Calculations In Chemistry

The speed of a wave is equal to its frequency times its wavelength. ... problem that can be solved using both methods, but to practice with the equati...

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Calculations In Chemistry * * * * * Modules 23 and 24 Light, Spectra, and Electron Configuration

* * * * * Module 23 –– Light and Spectra ....................................................................................631 Lesson 23A: Lesson 23B: Lesson 23C: Lesson 23D: Lesson 23E: Lesson 23F: Lesson 23G:

Waves ................................................................................................................. 631 Waves and Consistent Units ............................................................................ 636 Planck's Law ...................................................................................................... 641 DeBroglie’’s Wavelength .................................................................................. 645 The Hydrogen Atom Spectrum ....................................................................... 650 The Wave Equation Model .............................................................................. 656 Quantum Numbers .......................................................................................... 658

Module 24 –– Electron Configuration...........................................................................662 Lesson 24A: Lesson 24B: Lesson 24C: Lesson 24D: Lesson 24E:

The Multi-Electron Atom.................................................................................. 662 Shorthand Electron Configurations ................................................................ 666 Abbreviated Electron Configurations............................................................. 669 The Periodic Table and Electron Configuration ........................................... 673 Electron Configurations: Exceptions and Ions ............................................ 678 For additional modules, visit www.ChemReview.Net

Module 23 —— Light and Spectra

Module 23 —— Light and Spectra Timing: Begin this module when wavelength and frequency calculations are assigned. Pretests: If you believe that you know the material in a lesson, try two problems at the end of the lesson. If you can do those calculations, you may skip this lesson. * * * * *

Lesson 23A: Waves Waves and Chemistry Electromagnetic energy includes gamma rays, x-rays, ultraviolet, visible, and infrared light, microwaves, and radio waves. Each of these types of energy occupies a different region of the electromagnetic spectrum. Chemical particles can both absorb and release electromagnetic energy. This absorption and release of energy can be a powerful tool in identifying chemical particles. Exposure to certain types of electromagnetic energy can also cause chemical particles to change and react. In some cases, the behavior of electromagnetic energy is best predicted by assuming that the energy is a particle, but in other cases, energy is best understood as a wave. Let us begin by investigating the properties of waves.

Wave Terminology Crest

1Wavelength(ʄ)

0

90

180

270

360

450

540

630

720

810

900

990

Trough The following are some of the components of a wave that are important in chemistry. 1. Wavelength is the distance between the crests of a wave, which is equal to the distance between the troughs of a wave. a. The symbol for wavelength is nj (the lower-case Greek letter lambda). b. Since a wave length is a distance, the units of wavelength are distance units, such as meters, centimeters, or nanometers.

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2. Frequency is a number of events per unit of time. The unit for frequency is 1/time. For waves, frequency is the number of wave crests that pass a point per unit of time. a. In wave equations, the symbol for frequency is ǖ (the lower-case Greek letter nu). b. The SI unit for time, a fundamental quantity, is seconds. Because frequency is a derived quantity that is 1/time, the SI unit must be 1/seconds (sɆ1). The unit secondɆ1 is also called a hertz (Hz). During calculations, it is best to write hertz as sɆ1 . Hertz and sɆ1 are equivalent and can cancel. c. When wave frequency is expressed as ““cycles per second,”” wave cycles are the entity being measured, and 1/seconds is the unit. When writing wave units, the term ““wave cycle”” or ““cycle”” is often included as a helpful label in conversion calculations, but is usually omitted as understood in equation calculations. 3. The speed of a wave is equal to its frequency times its wavelength. wave speed = nj ǖ

= (lambda)(nu).

Memorize the equation for wave speed in words, symbols, and names for the symbols.

Wave Calculations Because wave relationships are often defined by multi-term equations, wave calculations are generally solved using equations rather than conversions. We will start with a simple problem that can be solved using both methods, but to practice with the equations that will be required for more complex calculations, solve the problem below using the equation method (for method review, see Lessons 17D or 21B). Q.

If ocean waves are traveling at 200. meters/minute and the crests pass a fixed point at a rate of 15.0 waves per minute, what is the wavelength, in meters?

* * * * * (When you see * * * * , cover below, solve, and then check below.) Write the one equation learned so far for waves. Wave speed = nj ǖ List those three terms in a data table. After each term, write the data in the problem that corresponds to the term. Add a ? and the desired unit after the WANTED symbol. * * * * * Wave speed = 200 m/min.

nj = ? meters ǖ = 15.0 wave cycles/min. = 15.0 min.Ɇ1

(speed units are distance over time) (the length of a wave is a distance) (frequency units are 1/time)

When solving wave frequency calculations using equations, ““wave cycles”” is usually omitted as understood to be the object being measured. Solve the equation in symbols for the WANTED symbol, then substitute the DATA. Include the consistent units and check the unit cancellation. * * * * *

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SOLVE:

Since

Wave speed = nj ǖ

nj in meters = speed = speed •• 1 = 200. m •• ǖ

ǖ

min.

1

= 13.3 meters

15.0 min.Ɇ1

Note in the unit cancellation in the denominator: min.•• min.Ɇ1 = min.1•• min.Ɇ1 = min.0 = 1 . Anything to the zero power equals one.

Practice A:

Check your answers at the end of this lesson.

1. Write the SI units for a. Wavelength

b. Frequency

c. Energy

d. Speed

2. Street lights containing sodium vapor lamps emit an intense yellow light at two close wavelengths. The more intense wave has a frequency of 5.09 x 1014 Hz. If light travels at the speed of 3.00 x 108 m •• sɆ1 , what is the wavelength of this intense yellow wave in meters? (Use the equation method to solve.)

Electromagnetic Waves The movement of electric charge creates electromagnetic waves. The waves propagate: they travel outward from the moved charge. The energy that was added to move the charge is carried outward by the waves. In a vacuum, all electromagnetic waves travel at the speed of light: 3.00 x 108 meters/second. The speed of light is the ““speed limit of the universe:”” the fastest speed possible for energy or matter. In wave calculations, the speed of light is given the symbol c. Electromagnetic waves slow when they travel through a medium that is denser than a vacuum, but when passing through air or other gases at normal atmospheric pressures, the speed of light does not slow sufficiently to affect most calculations in chemistry. For electromagnetic waves, this relationship will be true (and must be memorized): Speed of Light =

c = nj ǖ = 3.00 x 108 m/s

in vacuum or air

Since c is a constant, ǖ and nj are inversely proportional. As wavelength goes up, frequency must go down. If ǖ goes up, nj must go down. Further, as long as we work in consistent units and in air or vacuum, since c is constant, a specific value for the frequency of an electromagnetic wave will always correlate to a specific value for its wavelength.

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The Regions of the Electromagnetic Spectrum The electromagnetic spectrum goes from waves with very high frequencies (and very low wavelengths) to waves with very low frequencies (and very high wavelengths. The regions of the spectrum are assigned different names to help in predicting the types of interactions that the energy will display. However, all of these forms of energy are electromagnetic waves. The difference among the divisions of the spectrum is the length (or corresponding frequency) of the waves. The following table (no need to memorize) summarizes some of the general divisions of the electromagnetic spectrum. Frequency (sɆ1)

Wavelength (m)

Type of Electromagnetic Wave

1024

3 x 10ɔ16

Gamma Rays

1021

3 x 10ɔ13

1018

3 x 10ɔ10

X-rays

1015

3 x 10ɔ7

Ultraviolet, Visible, Infrared Light

1012

3 x 10ɔ4

Microwaves

109

3 x 10ɔ1

UHF Television Waves

106

300

Radio Waves

Units For Frequency and Wavelength Measurements of wavelengths and frequencies often involve very large and very small numbers. Values are often expressed using SI prefixes such as gigahertz (GHz) or nanometers (nm). Prefixes needed most often are those for powers of three.

Engineering Notation Scientific notation expresses a value as a significand between 1 and 10 times a power of 10. Engineering notation expresses values as a significand between 1 and 1,000 times a power of 10 that is divisible by 3. In wave calculations, answers are often preferred in engineering rather than scientific notation to ease conversion to the metric prefixes based on powers of three.

Prefix

Symbol

Means

tera

T

x 1012

giga-

G

x 109

mega-

M

x 106

kilo-

k

x 103

milli-

m

x 10Ɇ3

micro-

Ǎ

x 10Ɇ6

nano-

n

x 10Ɇ9

pico-

p

x 10Ɇ12

femto-

f

x 10Ɇ15

Examples: Converting scientific to engineering notation, 5.35 x 10Ɇ4 m = 535 x 10Ɇ6 m in engineering notation ( = 535 micrometers = 535 ȝm) 9.23 x 1010 Hz = 92.3 x 109 Hz in engineering notation ( = 92.3 GHz )

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To convert any exponential notation to engineering notation, adjust the exponent and decimal position until the exponent is divisible by 3 and the significand is between 1 and 1,000. (To review moving the decimal, see Lesson 1A). Try this example. Q. Convert 5.27 x 10Ɇ11 m to engineering notation, then convert the exponential to a metric-prefix. * * * * * A. 5.27 x 10Ɇ11 m = 52.7 x 10Ɇ12 m in engineering notation = 52.7 picometers or 52.7 pm 52.7 x 10Ɇ12 is the only way to write the given quantity that results in both an exponent divisible by 3 and a significand between 1 and 1,000. Engineering notation, like scientific notation, results in one unique expression for each numeric value, and this makes answers easy to compare and check. During electromagnetic wave calculations, you should work in general exponential notation, then, at the end, convert your answers to either scientific or engineering notation, depending on the system preferred for wave calculations in your course.

Practice B:

Do every other question. Complete the rest during your next study session.

1. By inspection, convert these to units in engineering notation, without prefixes. a. 5.4 GHz

b. 720 nm

c. 96.3 MHz

2. Convert these first to engineering notation, then to measurements with metric prefixes in place of the exponential terms. a. 47 x 10Ɇ7 m

b. 347 x 104 Hz

c. 1.92 x 10Ɇ8 m

d. 14,920 x 10Ɇ1 Hz

e. 0.25 x 1011 Hz

f. 7,320 m

ANSWERS Practice A 1. a. Wavelength is a distance, and the SI unit for distance is the meter (m). b. Frequency is defined as 1/time, and the SI unit for time is the second, so the SI unit of ǖ is 1/s or sʋ1, which is called a Hertz. c. Energy The SI unit for energy is the joule (J) or kg •• m2 •• sʊ1 . d. Speed is defined as distance over time, so the SI units are meters/second (m · sʊ1) 2.

Wave speed = ȝ ǖ Speed = 3.00 x 108 m •• sʊ1

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Ȝ in meters = ? ǖ = 5.09 x 1014 Hz sʋ1

( During calculations, write Hz as sʋ1 )

? = ȝ = speed = 3.00 x 108 m •• sʊ1 = 0.589 x 10ʊ6 m = 5.89 x 10ʋ7 m ǖ 5.09 x 1014 sʊ1 Practice B 1a. 5.4 GHz = 5.4 x 109 Hz or sʋ1 1b. 720 nm = 720 x 10ʋ9 m 1c. 96.3 MHz = 96.3 x 106 sʋ1 2a. 47 x 10Ɇ7 m = 4.7 x 10ʋ6 m = 4.7 Ȟm

(if exponent is made larger, make significand smaller)

2b. 347 x 104 Hz = 3.47 x 106 Hz = 3.47 MHz

2c. 1.92 x 10Ɇ8 m = 19.2 x 10ʋ9 m = 19.2 nm

2d . 14,920 x 10Ɇ1 Hz = 1.492 x 103 Hz = 1.492 kHz 2e. 0.25 x 1011 Hz = 25 x 109 Hz = 25 GHz

(significand must be between 1 and 1,000) 2f. 7,320 m = 7.32 x 103 m = 7.32 km

* * * * *

Lesson 23B: Wave Calculations and Consistent Units When using equations to solve science calculations, the units of measurements must be consistent: for each quantity in the equation, all measurements of that quantity must be converted to the same unit. How do you decide which units to choose as the consistent units in a problem? When choosing consistent units in equations we have studied previously, we have used two rules. x

When using a specified value and units for the gas constant R, our rule was: convert the DATA to the units used in the constant.

x

When using specific heat capacities (c), our rule was: convert to the unit of the most complex term in the DATA.

In wave calculations, we will follow both of these rules. Specific constants will be required, but those constants will generally contain the most complex units in the problem. The following rules will help in choosing and converting to consistent units. 1. Write the equation needed for the problem. 2. If the equation has constants, in the DATA table, first write each constant’’s symbol, value and units, then below write the symbols for the variables. 3. In the DATA table, after each variable symbol, write its chosen consistent unit. Example:

DATA:

nj in m =

(a wavelength is a distance)

To choose the consistent units to write after each variable symbol, apply these steps. a. If the equation has constants, after each variable write a unit that is appropriate for the symbol and is consistent with the units in the constants.

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Example: If

c= njǖ

is the equation that is needed, list

DATA:

c = 3.00 x 108 m · sɆ1

nj ǖ

in m = in sɆ1 =

(list constants in the equation first)

(wavelength is a distance; the distance unit in c is meters) (ǖ = 1/time, the time unit used in the constant c is seconds)

b. If there are no constants in the equation, label each variable with an appropriate unit matching the units used in the WANTED unit. 4. If the unit that is WANTED is not specified, a. pick a WANTED unit to match the units in the constants of the equation. b. If no constants are used, write after the WANTED unit the SI unit for the quantity. 5. In the DATA, write the data supplied for each symbol, then convert that DATA to the consistent units if needed. 6. First solve for the WANTED symbol in the consistent unit, then convert to a different WANTED unit if specified. The problem below will help you to understand and remember the rules above. Q.

When neon gas at low pressure is subjected to high voltage electricity, it emits waves of light. One of the more intense waves in the visible spectrum has a wavelength of 640. nm, perceived by the eye as red light. What is the frequency of this light in terahertz (THz)?

Solve using the steps above. * * * * * Answer This problem involves a frequency (ǖ) and a wavelength (nj) for light. We know that light travels at the speed of light (c), a constant. So far, we know only one equation that relates those three symbols. So, to start, your paper should look like this: c= njǖ DATA:

c = 3.00 x 108 m · sɆ1 nj = ǖ =

For the speed of light (c), in conversion calculations the unit m/s must be used as a ratio and written in the top/bottom format, but in equations, it will simplify unit cancellation if the units are written in the ““on one line”” format: 3.00 x 108 m · sɆ1 . Now assign a consistent unit to each variable. Since this equation has a constant (c), after each variable symbol write a unit that both measures the variable and matches one of the units used in the constant. Do that step, then check below.

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* * * * * Your DATA should look like the Rule 2a Example above, minus the (comments). Next, after the = sign for each variable, write the data for that variable that is supplied in the problem. Then, in the DATA table, x

convert the supplied units to the consistent units if needed.

x

For the WANTED variable, after the assigned consistent unit, write the unit WANTED in the problem if it is not the consistent unit.

Do those steps, and then check your answer below. * * * * * Your paper should look like this. c= njǖ DATA:

c = 3.00 x 108 m •• sɆ1 nj in m = 640. nm = 640. x 10Ɇ9 m ǖ in sɆ1 ; find sɆ1 then THz WANTED

For nj , meters is the chosen consistent unit, so you must convert nm to m. The easy way is to substitute what the prefix means. To SOLVE, x

First solve the equation for the WANTED symbol in symbols.

x

Substitute the DATA into the solved equation using the consistent units, and solve including the units.

x

If needed, convert to the unit WANTED in the problem.

Modify your work if needed and finish. * * * * * SOLVE:

? = ǖ in sɆ1 then THz =

c

nj

=

3.00 x 108 m •• sɆ1 = 4.69 x 1014 sɆ1 640. x 10Ɇ9 m

That solves in the consistent unit. To finish, convert to the WANTED unit. * * * * * 4.69 x 1014 sɆ1 Hz ••

1 THz = 469 THz 1012 Hz

Done! This method of choosing to solve in the units of the constants, is arbitrary. You can use any consistent units to solve. In physics, it is usually preferred (and simplifying) to solve all problems in SI units. In many chemistry calculations, constants will be stated in SI units, matching the physics practice. However, ““solving in the units of the constants”” will save a few steps if data is provided in mL, grams, or other non-SI base units, as will be the case in some science calculations.

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Try

Q2. How many wavelengths of the 640. nm red neon light above would fit into one centimeter? (one wave cycle = 1 wave = 1 wavelength)

* * * * * If you are not sure how to proceed, list the data, try to assign symbols, and see if the symbols fit a known equation. * * * * * The wanted unit is waves/cm, which is the inverse of wavelength, not wavelength. Plus, none of the data has a frequency, so the data does not match the one equation we know so far. Note that the data includes an equality, and that all of the data can be listed as equalities or ratios. That’’s a hint: try conversions to solve. * * * * * WANT: DATA:

? waves cm

(you want the waves per one cm, a ratio unit)

one wave = 1 wavelength

(2 measures of the same object)

one wavelength = 640. nanometers Though ““waves”” or ““wave cycles”” is usually left out of wave equation calculations as understood, including ““waves”” may help when using conversions. If needed, adjust your work and then finish the problem. * * * * * One way of several to SOLVE is ? waves = 1 wave •• cm 1 wavelength

1 wavelength •• 1 nm •• 10Ɇ2 m = 15,600 waves 1 cm cm 640. nm 10Ɇ9 m

How many waves of red light fit into a centimeter? Quite a few.

Summary: Frequency and Wavelength 1. Wavelength: the distance between the crests of a wave. The symbol is nj (lambda). T The units are distance units: the base unit meters, or nanometers, etc. 2. Frequency: the number of times a wave crest passes a point per unit of time. The symbol is ǖ (nu). The units are 1/time . SI frequency units = wave cycles per second = 1/seconds = sɆ1 = hertz (Hz). In calculations, write hertz as sɆ1 so that units will cancel properly. 3. The speed of a wave is equal to its frequency times its wavelength. Wave speed = nj ǖ

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= (lambda)(nu).

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4. Electromagnetic waves travel at the speed of light (symbol c). For all electromagnetic waves,

c = nj ǖ = 3.00 x 108 m · sɆ1 in vacuum or air.

5. To simplify solving equations that include a constant that has units, a. In the DATA table, x

list the constants first.

x

After each symbol for a variable, write a unit to convert DATA to. Choose if available a unit that matches the constants of the equation. If there are no constants, convert to the WANTED unit or to an SI unit.

b. First solve in the consistent unit, then convert to the WANTED unit if needed.

Practice

(Additional practice with nj and ǖ will be provided in lessons that follow.)

1. If an AM radio station broadcasts a signal with a wavelength of 0.390 km, what is the frequency of the signal on a radio tuner, in kHz? 2. If there are 225 waves per centimeter, what is the wavelength of the waves in meters?

ANSWERS 1. (The data is a nj and wanted is a ǖ. The equation that relates those two variables is:) c= njǖ DATA:

c = 3.00 x 108 m •• sʊ1

nj in m = 0.390 km = 0.390 x103 ǖ in sʋ1 = ? , then convert to kHz

(list constants used in the equation first) m = 390 m

1 kHz = 103 Hz = 103 sʋ1

( convert to units used in the constants) (listing metric conversions is optional)

? = ǖ in sʋ1, then kHz = c = 3.00 x 108 m •• sʋ1 = 0.77 x 106 sʋ1 •• 1 kHz = 770 kHz nj 390 m 103 sʋ1 (Hertz and sʊ1 are equivalent and can cancel.) 2. (If you are not sure how to proceed, list the data, assign symbols, then see if the symbols fit a known equation.) WANTED:

nj

DATA:

225 waves = 1 cm

in m = ?

(or meters/wave)

(If no equation seems to fit the DATA, try conversions to solve. If needed, use that hint and finish. * * * * *

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If the WANTED unit is re-written as meters/wave, a ratio is wanted, and a ratio is in the data to start from. Arrange the given so that one unit is where is WANTED (Lesson 11B), but any order for these two conversions works.) SOLVE:

? meters = 1 cm •• wave 225 waves

10ʋ2 m 1 cm

= 4.44 x 10ʋ5 m wave

The wavelength is 4.44 x 10ʋ5 m. * * * * *

Lesson 23C: Planck’’s Law Energy and Frequency In 1900, the German physicist Max Planck, studying the black-body radiation emitted by objects at high temperature, discovered that energy is absorbed by or emitted from atoms in bundles of a small but constant size, or in multiples of that constant size. Building on Planck’’s work, in 1905 Albert Einstein proposed an explanation for the photoelectric effect: the observation that when UV light shines on a metal, the metal emits electrons. Einstein postulated that light can be considered to be made of small particles called photons. In Einstein’’s formulation, electromagnetic energy has characteristics of both a wave and a particle, with photons acting as particles of energy that travel at the speed of light. These particles he called quanta. A single particle is a quantum. The energy of each photon is correlated to its frequency as a wave. For photons, the equation that relates frequency and energy is called Planck’’s law. Ephoton = h ǖ In this equation, h is a number with units called Planck’’s constant. Planck’’s constant = h = 6.63 x 10ʋ34 joule · seconds Because frequency must be positive, and Planck’’s constant is small but positive, the equation E = hǖ means that as the energy of a wave increases, its frequency must increase, and that higher frequency waves have higher energy. Since calculations using Planck’’s constant involve electromagnetic waves, we can x

use our previous equation for the speed of those waves,

x

solve that equation for ǖ: ǖ = c / nj , then

x

write the photon energy equation as E = h ǖ

c=njǖ ,

or, substituting for ǖ ,

E= h· c nj

These two general forms of Planck’’s law are equivalent. The first solves for energy in terms of frequency, the second in terms of wavelength. The first should be memorized, and the second either memorized (““for wavelength, the two constants are on top””) or derived as needed.

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Together, these equations mean that in the case of electromagnetic waves, for the three variables energy, frequency, and wavelength, if you know any one, you can calculate both of the other two. Further, it will always be true that as photon energies go up, the corresponding frequencies go up and wavelengths go down. Waves with higher energy have higher frequency and shorter wavelength.

Calculations Using Planck’’s Law In solving the problems in these lessons, it is expected that you will be able to write from memory the equations for waves and the value of the speed of light (which is used quite often in science), but you will be supplied the value for Planck’’s Constant (h) when it is needed in a problem. When using Planck’’s law, to simplify problem-solving we will use the same rules as other equations. x

Identify and write the needed equation.

x

In the DATA table, list the constants in the equation and their values first.

x

After each symbol for a variable, write a consistent unit. Choose the units of the constants if the equation has constants. If not, choose the WANTED unit if it is specified, or choose the SI unit for each quantity.

x

In the DATA table, convert all DATA to the consistent units.

x

Solve for the WANTED symbol in the consistent unit, then convert to other WANTED units if needed.

Try those steps on this problem. Q.

Cosmic rays are high-energy radiation that enters the earth’’s atmosphere from space. The energy of a single cosmic ray photon can be as high as 50. joules. What would be the frequency of this radiation in Hz? ( h = 6.63 x 10ʊ34 J · s )

* * * * * To decide which equation is needed to solve a problem, try this method: as you read the problem, write the symbol that fits the unit for each item of WANTED and DATA you encounter. Simply listing the symbols as you read will often quickly identify the equation that you need to solve. * * * * * 50 J = E, ? = ǖ . The fundamental equation that relates E and ǖ is ? * * * * *

E = hǖ

Write a data table and solve.

* * * * * DATA:

h = 6.63 x 10ʊ34 J · s

(list constants first, use their units)

E in J = 50 J

ǖ in sɆ1 = ?

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then convert to Hz WANTED

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? = ǖ ( in Hz ) = E =

h

50. J 6.63 x 10Ɇ34 J · s

= 7.5 x 1034 sɆ1 Hz

Photons with this is extremely high energy and frequency are produced by nuclear processes in stars. Let’’s try a problem with a more commonly encountered energy. Q2. A microwave oven warms food by producing radiation with a typical wavelength of about 12 cm. What is the energy of this wave? ( h = 6.63 x 10ʊ34 J · s ) * * * * * Answer As you read, you encounter a nj and a E. The equation that uses nj and E is ? * * * * *

E= h · c nj DATA:

c = 3.00 x 108 m · sɆ1 h = 6.63 x 10ʊ34 J · s

(list the two constants first, use their units)

E in J = ?

nj in m = 12 cm = 12 x 10Ɇ2 m = 0.12 m

( h uses joules ) ( c uses m, c- = x 10Ɇ2)

(In the DATA table, convert DATA to the consistent unit.) * * * * *

E= h · c nj

= ( 6.63 x 10ʊ34 J · s ) ( 3.00 x 108 m · sɆ1 ) = 1.7 x 10Ɇ24 J 0.12 m

Practice 1. Based on E = h ǖ and the rules for unit cancellation, what must the SI unit for Planck’’s constant be? Why? 2. The human eye can generally see energy waves in the range of 400 to 700 nm. When hydrogen gas at low pressure is subjected to high voltage, it emits four waves of light in the visible region of the spectrum: one red, one blue-green, one blue-violet, and one violet. ( h = 6.63 x 10Ɇ34 J •• s ) a. A photon of red light from the hydrogen spectrum has an energy of 3.03 x 10Ɇ19 J. What is the wavelength of this light in nanometers? b. The blue-green line consists of waves with a frequency of 615 THz. What is the energy of these waves? c. The blue-violet line has a wavelength of 434 nm. What is the frequency of these waves in Hz?

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ANSWERS 1. Since the SI unit for E is joules and for ǖ is sʊ1 ., the units of E = h ǖ must be J = (? Units) •• sʋ1. For unit cancellation to work, the units of h must equal J •• s (see Lesson 21D). (In SI base units, since Energy = work = mad = (mass)(acceleration)(distance) = J units = kg · m2 · sʊ2 , the units of h = ? = J · s also = kg · m2 · sʊ1 ), but base units are not needed for most calculations). 2a.

(Part (a) involves E and ȝ . The equation that relates those variables is)

E= h · c nj h = 6.63 x 10ʊ34 J · s

DATA:

c = 3.00 x 108 m · sʊ1

(list the two constants, convert DATA to those units)

E in J = 3.03 x 10ʊ19 J

ȝ in m = ? then convert to nm 1 nm = 10ʋ9 m

( c uses meters )

(listing fundamental metric conversions is optional in DATA )

* * * * *

ȝ (in m) = h · c = ( 6.63 x 10ʊ34 J · s ) ( 3.00 x 108 m · sʊ1 ) = 6.56 x 10ʋ7 m E 3.03 x 10ʊ19 J ȝ (in nm) = 6.56 x 10ʊ7 m = 656 x 10ʋ9 m (engineering notation) = 656 nm or ȝ (in nm) = 6.56 x 10ʊ7 m •• 2b.

1 nm = 6.56 x 102 nm = 656 nm 10ʋ9 m

(Part (b) involves E and ǖ . The equation that relates those symbols is)

E=hǖ DATA:

h = 6.63 x 10ʊ34 J •• s

(list constants first. Use their units for WANTED and DATA)

E in J = WANTED

ǖ SOLVE:

in sʊ1 = 615 THz = 615 x 1012 Hz = 615 x 1012 sʋ1

( h uses seconds )

E (in J) = h ǖ = ( 6.63 x 10ʊ34 J •• s ) ( 615 x 1012 sʊ1 ) = 4.08 x 10ʋ19 J

2c. (The problem has nj and ǖ. The equation that relates nj and ǖ for electromagnetic waves is) c= njǖ DATA:

c = 3.0 x 108 m · sʊ1

(list constants used in the equation first)

ȝ in m = 434 nm = 434 x 10ʊ9 m ǖ in sʋ1 = ? , then convert to Hz

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SOLVE: ? = ǖ in sʋ1 , then Hz = c = 3.00 x 108 m · sʋ1 = 0.00691 x 1017 sʊ1 = 6.91 x 1014 Hz ȝ 434 x 10ʊ9 m * * * * *

Lesson 23D: De Broglie’’s Wavelength Timing: Do this section if you are asked to solve calculations using the De Broglie equation, and/or if you plan to take physics.) * * * * *

De Broglie’’s Wavelength Equation In 1923, the French physicist Louis De Broglie proposed that, just as energy has particle-like properties, particles can have wavelike properties. In the equation De Broglie derived to predict the characteristics of these ““matter waves,”” the length of the wave associated with a particle depends on the mass of the particle and its speed (or velocity). The equation is nj=

h mass · speed

Though De Broglie’’s equation can be applied to any moving particles, it is most often applied to small particles such as electrons. Apply De Broglie’’s wavelength equation to the following problem. If you need a hint, read a part of the answer below, then try again. Q. Calculate the wavelength of an electron (mass of electron = 9.11 x 10Ɇ28 grams) that is traveling at one-tenth the speed of light. * * * * * The problem involves wavelength (nj), mass, and speed. The equation that relates those three variables is the De Broglie wavelength equation. nj=

h mass · speed

DATA:

h = 6.63 x 10ʊ34 J · s mass = 9.11 x 10Ɇ28 g

(list the two constants first)

speed = 0.100 x 3.00 x 108 m · sɆ1 = 3.00 x 107 m · sɆ1 nj= ? SOLVE: ? = nj =

h = 6.63 x 10ʊ34 J · s mass · speed (9.11 x 10Ɇ28 g)( 3.00 x 107 m · sɆ1)

=???

We have a problem. The units do not cancel. You could ignore that, but if you do, you will do a lot of work to arrive at an answer that is not correct.

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When units do not cancel properly, something is likely wrong. Let us see if we can fix this problem. Joules is an abbreviation for a combination of SI base units used to measure distance, mass, and time. In many calculations in chemistry, joules can be left ““as is”” in an answer unit, as a measure of energy. The De Broglie wavelength equation, however, a case where, for the units to cancel, joules must be converted to the base units that joules is an abbreviation for. To convert joules to its base units, you have two choices. You can memorize the base units that are equivalent to joules, or you can derive the base units from simple relationships if you know a bit of physics. Let’’s review the process for converting unit abbreviations such as newtons, pascals, watts, and volts to the fundamental SI base units that those named units are abbreviating. This conversion process will be helpful to know, especially if you take future courses in chemistry, physics, or engineering.

Converting Joules to Base Units What is a joule of energy? Energy is the capacity to do work. There are many forms of energy: including potential, kinetic, thermal, and electrical. There are many units that can be used to measure energy, including calories, ergs, BTUs, and kilowatt-hours. The SI unit used to measure energy is the joule. Energy is a derived quantity. It can be defined in terms of the fundamental quantities of distance, mass, and time. The easiest way to do so is to define energy in terms of what in physics is termed ““mechanical work.”” Work is defined as the product of a force acting over a distance. In equation form: Energy = work = force times distance = F •• d Since force is equal to mass times acceleration (F = ma), we can write Energy = work = F •• d = (mass times acceleration) times distance = m·a·d , or Energy = work = m·a·d

(This relationship can be remembered as ““work is mad!””)

The joule, the derived SI unit measuring energy, is defined in terms of the SI base units that measure the fundamental quantities. The SI base-units are derived from what was historically known as the mks system. x

Distance is measured in the SI-base unit of meters (m).

x

The SI base unit used to measure mass is the kilogram (kg), not the gram. (In the SI system, base units for all other fundamental quantities do not include a metric prefix. The kilogram used for mass is the exception.)

x

The base unit for time is seconds (s), and acceleration is defined as distance/time2, so acceleration is measured in base units of meters/second2 ( = m · sɆ2 ).

Based on Energy = work = m·a·d , the SI unit measuring energy (one joule) is defined as the energy needed to accelerate one mass base unit (one kg) by one acceleration base unit (1 m · sɆ2) for one distance base unit (1 m). By substituting into the definition of energy Energy = m · a · d

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the base units used to measure each of those four terms:

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1 Joule = 1 kg · (1 m · sɆ2 ) · 1 m , this produces a definition of Joule = kg · m2 · sɆ2

This key equality relates joules to its SI base units.

In the unit for h, if we substitute those base units in place of joules, and measure the other variables in the data in those base units, the units will cancel properly in De Broglie wavelength and other calculations. To summarize: To solve the De Broglie equation, for the units of h, substitute for joules the base units that joules are equivalent to. Either memorize the base units for joules, or remember that ““work is mad!”” and substitute the SI base units (mks) that measure m, a, and d. In general, SI derived units that are abbreviations for combinations of base units (such as joules, newtons, watts, and pascals) can be converted to SI base units using these steps: To convert an SI combined unit to its base units 1. Write the equation that defines the derived quantity that the unit measures using quantities for which the SI base units are known; then 2. Substitute into the equation the base units used to measure those quantities. (For more on converting unit abbreviations such as Joules to SI base units, see Lesson 19C). * * * * * Now let’’s return to our De Broglie wavelength calculation. In your DATA table, substitute for joules the base units of joules, adjust your DATA units to match these new units for the constant, solve, and then check your answer below. * * * * * To arrange for the units to cancel, begin by substituting the base units for joules into h: DATA:

h = 6.63 x 10ʊ34 J ( kg · m2 · sɆ2 ) · (s)

(list constants first)

Write after the mass variable in the DATA table the units for mass used in the constant h, then convert the mass DATA to those units. mass in kg = 9.11 x 10Ɇ28 g ••

1 kg 103 g

= 9.11 x 10Ɇ31 kg

Mass, to have consistent units that will cancel in the equation, must be kg and not g. Speed (distance over time) is supplied in the problem in the base units used in h. speed (in m/s) = 0.100 x 3.00 x 108 m · sɆ1 = 3.00 x 107 m · sɆ1 Since the unit for the WANTED wavelength is not specified, pick a unit to attach to the symbol that either uses the units in the constant or is an SI unit. In this and in most problems, both choices will result in the same unit. Since wavelength is a distance, solve for nj in the distance SI base unit: meters. SOLVE: ? = nj (in m) =

= 6.63 x 10ʊ34 ( kg · m2 · sɆ2 ) · s = 2.43 x 10Ɇ11 m h mass · speed (9.11 x 10Ɇ31 kg) (3.00 x 107 m · sɆ1)

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Mark the unit cancellation on your paper carefully. If the units cancel to give the WANTED unit, then it is likely that the numbers were put in the right place to get the right answer. When should you substitute base units for units such as joules, pascals, volts, and newtons? Do so only when it is necessary in order for units to cancel to obtain a WANTED unit. If the WANTED unit and/or other DATA units include one of those complex derived units, you will probably not need to convert to base units to solve.

Summary: Equations and Constants For Electromagnetic Waves Be sure that these 7 relationships can be recalled from memory before doing the following practice. Treat practice as a practice test. 1.

Wave speed = nj ǖ

2. For electromagnetic waves, speed of light = 3. Planck’’s law: E = h ǖ

and

c = nj ǖ = 3.00 x 108 m · sɆ1

E=h·c nj

4. Planck’’s constant = h = 6.63 x 10ʋ34 J · s 5. The De Broglie wavelength equation: 6.

Joule = kg · m2 · sɆ2

nj =

h mass · speed

(memorize or derive as needed)

7. When working in problems that mix derived and fundamental SI units, convert all DATA to mks: distance in meters, mass in kg, time in seconds.

Practice 1. If F = m · a , and the SI unit for force (the newton) is defined using the SI base units for mass and acceleration, what base units are equivalent to the newton? 2. If the wavelength of a moving electron is measured to be 36.3 picometers, what is the speed of the electron? (mass of electron = 9.11 x 10Ɇ28 grams)

The Heisenberg Uncertainty Principle In 1927, the German physicist Werner Heisenberg postulated the uncertainty principle: that for very light particles such as electrons, it is not possible to be certain of both position and velocity at the same time. Mathematically, his equationtion is (uncertainty in position) x (uncertainty in velocity) • h/(4S · mass) Since the mass of a particle is constant, all of the terms on the right side of this equation are constant, and the two terms on the left are variables. The equation is therefore in the form xy = c and is an inverse proportion. As the uncertainty of one variable on the left goes down, the uncertainty of the other goes up.

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This result is that if we know where an electron is, we cannot say precisely its velocity (its speed and direction, which tells us where it will be next). If we know the velocity of the electron, we cannot say precisely where it is. This means that the location of electrons must be stated in probabilities rather than certainties. If you need to solve calculations using the uncertainty equation, simply memorize the equation and apply the rules for solving equations discussed above. * * * * *

ANSWERS 1. Since F = m · a , one unit of force (one Newton) equals one base unit of mass (1 kg) times one base unit of acceleration (one meter per second2 = 1 m · sʋ2). newton = kg · m · sʋ2 2. (The problem involves ȝ, speed, and mass. Use the De Broglie equation.) nj=

h mass · speed

(So that units cancel in the De Broglie equation, substitute the base units for joules into h:) DATA:

h = 6.63 x 10ʊ34 J · s

( kg · m2 · sʋ2 ) · s

(list constants first)

For consistent units that will cancel, mass must be in kg and not g. mass in kg = 9.11 x 10ʊ28 g ••

1 kg = 9.11 x 10ʊ31 kg 103 g

For the WANTED speed, the units are not specified, so pick units for speed (distance per unit of time) that are used in the constant (h): meters and seconds. speed (in m/s) = ?

ȝ (in m) = 36.3 picometers •• To SOLVE: =

? = speed (in m/s) =

10ʋ12 m 1 pm

= 36.3 x 10ʋ12 m

= 6.63 x 10ʊ34 ( kg · m2 · sʊ2 ) · s h mass · Ȝ (9.11 x 10ʋ31 kg) (36.3 x 10ʊ12 m)

=

6.63 x 10ʊ34+31+12 ( kg · m2 · sʋ2 ) · s = 0.0200 x 109 m · sʋ1 (9.11 x 36.3) kg · m

= 2.00 x 107 m/s * * * * *

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Lesson 23E: The Hydrogen Atom Spectrum Bohr and Atomic Spectra When atoms are heated to high temperatures, or vaporized and electrified, they glow: they emit light. Viewed through a prism or a diffraction grating, this light separates into thin lines of color in the order of the colors of the rainbow: energy waves at sharply defined wavelengths. Additional waves may be emitted in regions of the spectrum not visible to the eye. Together, these energy waves are called the emission spectrum or line spectrum of the atom. Each atom has a characteristic line spectrum. Astronomers can analyze the light from distant stars to identify the atoms that are present in the stars. In 1913, the Danish physicist Neils Bohr proposed that the light of an atom’’s emission spectrum results from electrons falling from higher to lower fixed energy levels inside an atom, like marbles falling down a staircase (but one in which each step has a different rise). Based on a simple mathematical equation,

En = Ɇ 2.18 x 10Ɇ18 J/atom n2

Bohr’’s model predicted exactly the observed wavelengths of the hydrogen atom spectrum. Bohr’’s model did not correctly explain other properties of the hydrogen electron, nor did it correctly predict electron behavior in other atoms. However, his proposal that electrons must occupy energy levels in the atom, and his equation to calculate the energy levels in hydrogen, remain a key part of our current model for atomic structure.

Bohr’’s Model For Hydrogen Energy Levels A neutral hydrogen atom consists of one proton at the center of the atom and one electron outside the nucleus. (A hydrogen nucleus may also include one or two neutrons, but these neutral particles do not affect the key electrical interaction between the positive proton and the negative electron.) Nearly all of the volume of the atom is due to the space occupied by the electron’’s movement around the nucleus. The hydrogen electron can be described as existing at certain fixed levels of energy that are similar to a staircase. The H-atom electron must be found on one of the energy levels of the staircase: it cannot rest between steps. The steps of the H-atom staircase are uneven, but they follow a consistent pattern. The first step up from the bottom step is large, but the rise for each subsequent step is smaller. The staircase has an infinite number of steps, numbered from n = 1 to n = ’ . Step n = 1 is the bottom step and n= ’ is at the top of the staircase. In nature, systems tend to go to their lowest potential energy. The H-atom electron is therefore normally found at the bottom step n = 1, where it is said to be in its ground state. However, if energy is added to the H-atom, such as from heat, energy waves, or high voltage, the electron can be promoted up the staircase. If the H-atom electron is above the bottom step, it is unstable and said to be in an ““excited state.””

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An H-atom electron promoted to an upper step is unstable because it is not at its lowest possible potential energy. The electron will therefore tend to fall back down the staircase. It falls like a marble, either hitting every step or skipping some steps, until it reaches the bottom step n = 1. The electron may ““pause”” on any step, but the electron cannot pause between steps. The electron falling down the staircase must lose energy. To do so, it emits energy waves (photons). The energy waves it emits are seen as the lines of the H-atom spectrum. To calculate the energy of the lines in the spectrum, let’’s add energy values to this H-atom model.

The H Energy Levels Using this equation:

En = Ɇ 21.8 x 10Ɇ19 J n2

(per each atom)

calculate and fill-in each missing En value for the steps of the H-atom listed below. To add and subtract numbers in exponential notation by hand, the numbers must have the same exponential term (see Lesson 1B). To simplify upcoming calculations, we will write all of the En values as ““ x 10Ɇ19 J ““ as in the above equation. If you need help, check the sample calculation below. n = ’ ________________ E’ = 0 Joules …… n = 6 ________________ E6 = Ɇ 0.606 x 10Ɇ19 J n = 5 ________________ E5 =

Ņ Calculate the remaining En values

n = 4 ________________ E4 = n = 3 ________________ E3 = n = 2 ________________ E2 =

n = 1 ________________ E1 = * * * * * For the energy level n = 6, :

E6 = Ɇ 21.8 x 10Ɇ19 J = Ɇ0.606 x 10Ɇ19 J

62 Finish calculating the remaining energies if needed. * * * * *

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Your answers should match those at the right. (The numbers are accurate, but the spacing between the steps is not drawn to scale.) The movement of electric charge creates electromagnetic waves. When the H-atom electron falls from one energy level to a lower level, it must lose energy. To do so, it releases an energy wave with an energy equal to the difference in energy between those two levels.

The H-atom Energy Levels n = ’ _____________ E’ = 0 J ……

n = 6 _____________ E6 = Ɇ 0.606 x 10Ɇ19 J n = 5 _____________ E5 = Ɇ 0.872 x 10Ɇ19 J n = 4 _____________ E4 = Ɇ 1.36

x 10Ɇ19 J

n = 3 _____________ E3 = Ɇ 2.42 x 10Ɇ19 J

n = 2 _____________ E2 = Ɇ 5.45

x 10Ɇ19 J

n = 1 _____________ E1 = Ɇ 21.8

x 10Ɇ19 J

In your notebook, calculate the difference in energy between energy levels E3 and E2. * * * * * E3 minus E2 = Ɇ 2.42 x 10Ɇ19 J Ɇ (Ɇ 5.45 x 10Ɇ19 J) = + 3.03 x 10Ɇ19 J From the electron’’s perspective, this difference is assigned a negative sign because it represents the amount of energy that the electron must lose in falling from E3 to the lower energy level E2: the electron will be minus this much energy. However, from the perspective of the light wave emitted, this energy is positive: the wave must contain the amount of energy that the electron loses. In Lesson 23C, Problem 2a, you calculated the wavelength of a wave with this energy. What was the value of that wavelength? According to Problem 1a, what color would your eye perceive this wave to be? * * * * * 656 nm. When the H-atom electron falls from level n= 3 to n = 2, it produces an energy wave at a wavelength of 656 nm that your eye sees as red. When the electron falls between other energy levels, it emits light with other colors (plus waves in other regions of the electromagnetic spectrum that the eye cannot see).

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Practice: The H-Atom Spectrum Do Problems 1 and 3 below. Do more if you need more practice. In Lesson 23C, Practice 2, and in the lesson above, we calculated these values for the

H-Atom Visible Spectrum Color

Wavelength (nm)

Frequency (Hz)

red

656

blue-green

486

6.15 x 1014

blue-violet

434

6.91 x 1014

violet

410

Energy (J/atom)

Transition

3.03 x 10Ɇ19

Step 3 Æ 2

4.08 x 10Ɇ19

In this table, the last column represents the movement of an electron to lower levels in the H atom. The color, wavelength, frequency and energy in this table are properties of the energy wave emitted as the electron falls. Use the table as data for the problems below. Add your answers to the table as you complete the following calculations. ( h = 6.63 x 10Ɇ34 J •• s ) 1. As the H-atom electron falls from level n = 5 to n = 2, based on the values for the energy levels (En) that you calculated in this lesson, a. what would be the energy of the wave emitted? b. What would be the wavelength of the wave in nm? c. What would be the color of the wave? d. What information do these answers allow you to add to the table above? 2

Calculate the energy of the violet line of the H-atom visible spectrum a. using Planck’’s law. b. Use the energy-level diagram for the H-atom to determine which transition produces a photon with the energy of the violet line.

3. If sufficient energy is added to the H-atom in its ground state (with the electron at n = 1), the electron can be ionized: it can be taken an essentially infinite distance away from the proton that is attracting the electron. The energy needed to remove the electron is the energy needed to promote the electron from level n = 1 to n = ’. This value is termed the ionization energy of the atom. a. Based on the energy level diagram for H, what is the minimum amount of energy that is needed to take away (ionize) an H-atom electron? b. If an ionized electron falls from level n = ’ down to level n = 1 in one transition, what will be the energy of the wave emitted by the electron? c. How does this energy value compare to the energy values of the lines in the visible spectrum listed in the chart above? d. What will be the wavelength of this energy wave in nm?

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e. If the human eye can generally see energy waves in the range of 400 to 700 nm, will you be able to see this wave when looking at an H-atom spectrum? 4. One of the lines in the ultraviolet region of the spectrum of hydrogen has a frequency of 2.46 x 1015 Hz. Which transition does this represent? 5. Using alternate units, the ionization energy of hydrogen is 13.6 electron volts (eV) per atom. Convert this ionization energy to kilojoules per mole (kJ/mol). (Use 1 eV = 1.60 x 10Ɇ19 J) 6. If the ionization energy of a hydrogen atom is Ɇ 21.8 x 10Ɇ19 J, what is the energy of level n = 3 ?

ANSWERS 1. a. E5 ʋ E2 = ʋ 0.872 x 10ʊ19 J ʋ (ʋ 5.45 x 10ʊ19 J) = + 4.58 x 10ʊ19 J b. This problem involves E (from part a) and ȝ . The equation that relates those variables is E= h ·c ȝ DATA:

h = 6.63 x 10ʊ34 J · s

c = 3.00 x 108 m · sʊ1

(list the two constants, convert DATA to their units)

E in J = 4.58 x 10ʊ19 J

ȝ in m

then convert to nm WANTED

( c uses meters )

nano means x 10ʊ9

SOLVE ȝ (in m) = h · c = ( 6.63 x 10ʊ34 J · s ) ( 3.00 x 108 m · sʊ1 ) = 4.34 x 10ʊ7 m E 4.58 x 10ʊ19 J = 434 x 10ʋ9 m = 434 nm c. Blue-violet. See values in the table above. d. For the blue-violet wave, E = 4.58 x 10ʊ19 J , and the electron is falling from step 5 Æ 2. 2. a. Only ȝ is known in the table; E is WANTED. The form of Planck’’s law that relates ȝ and E is

E= h ·c ȝ DATA:

c = 3.00 x 108 m · sʊ1 h = 6.63 x 10ʊ34 J · s

(list constants first, use their units to solve)

E in J = WANTED

ȝ in m = 410 nm = 410 x 10ʋ9 m

( h uses joules ) (convert to the meters used in c )

E = h · c = ( 6.63 x 10ʊ34 J · s ) ( 3.00 x 108 m · sʊ1 ) = 4.85 x 10ʋ19 J ȝ 410 x 10ʋ9 m

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b. Based on the pattern in the spectrum data table, the violet line should represent the 6 Æ 2 transition. Check it: E6 ʋ E2 = ʋ 0.606 x 10ʊ19 J ʋ (ʋ 5.45 x 10ʊ19 J) = + 4.84 x 10ʊ19 J Allowing for rounding, this agrees with the 2a answer. 3. a. Enough energy must be added to promote the electron from n = 1 to n = ’, E’ ʋ E1 = 0 J ʋ (ʋ 21.8 x 10ʊ19 J) = + 21.8 x 10ʊ19 J b. From n = ’ down to n = 1, the energy difference is the same: E’ ʋ E1 = + 21.8 x 10ʊ19 J The energy put in to pull away (ionize) the electron, starting from n = 1, must equal the total energy the electron loses by emitting an energy wave when the electron returns to n = 1. c. + 21.8 x 10ʊ19 J is a larger energy than those for the visible waves listed in the table. d. Part (d) involves E (from part c) and ȝ . The equation that relates those variables is E= h·c nj DATA:

h = 6.63 x 10ʊ34 J · s

c = 3.00 x 108 m · sʊ1

(list the two constants, convert DATA to those units)

E in J = 21.8 x 10ʊ19 J

ȝ in m = ? then convert to nm nano means x 10ʊ9

(for units consistent with c, solve in m first )

SOLVE: ȝ (in m) = h · c = ( 6.63 x 10ʊ34 J · s ) ( 3.00 x 108 m · sʊ1 ) = 0.912 x 10ʊ7 m E 21.8 x 10ʊ19 J = 91.2 x 10ʋ9 m = 91.2 nm e. No. This wave has a shorter wavelength (and a higher frequency and energy) than the eye can see. 91.2 nm is in the ultraviolet (UV) region of the spectrum. The high-energy ultraviolet lines of the H-atom spectrum can be imaged by special films. Prolonged exposure to UV radiation is dangerous to the eyes and skin. The sun produces high amounts of UV radiation, but most is absorbed by the ozone layer in the earth’’s upper atmosphere before it can reach the earth’’s surface. If the ozone layer decays, the incidence of skin cancer on earth would likely increase, among other harmful effects. 4. To find the transition using the energy-level diagram, the energy of the line is needed. The equation that relates E and ǖ is DATA:

h = 6.63 x 10ʊ34 J · s

E=hǖ (list constants first, use their units for WANTED and DATA)

E in J = ?

ǖ in sʊ1 = 2.46 x 1015 Hz sʋ1 SOLVE:

( h uses seconds )

E (in J) = h ǖ = ( 6.63 x 10ʊ34 J · s ) (2.46 x 1015 sʊ1 ) = 1.63 x 10ʋ18 J

Which transition has this energy? * * * * *

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Convert this E to 16.3 x 10ʋ19 J for easier comparison to the numbers in the energy-level diagram. * * * * * E2 ʋ E1 = ʋ5.45 x 10ʊ19 J ʋ (ʋ 21.8 x 10ʊ19 J) = + 16.4 x 10ʊ19 J The energy lost by an electron in falling from E2 to E1 matches the energy value of the wave emitted, as calculated from the frequency above , allowing for rounding. For all of the transitions where the electron falls to n = 1, the H-atom will emit UV radiation. 5. WANTED: DATA:

?

kJ mol

13.6 eV = 1 atom 1 eV = 1.60 x 10ʊ19 J 6.02 x 1023 atoms = 1 mole atoms

(mixes atoms with moles of atoms)

A ratio is WANTED. The data is two ratios/equalities/conversions. Try conversions (Lesson 11B). * * * * * ? kJ = 1.60 x 10ʊ19 J •• 1 kJ •• mol 1 eV 103 J

13.6 eV •• 6.02 x 1023 atoms = 1.31 x 103 kJ 1 atom 1 mole mol

6. The ionization energy is the energy need to promote the electron from n = 1 to n = ’. That energy is also the value in the energy-level equation En = ʊ 21.8 x 10ʊ19 J n2 E3 = ʊ 21.8 x 10ʊ19 J = ʋ 2.42 x 10ʋ19 J For energy level n = 3,

(per atom)

32

* * * * *

Lesson 23F: The Wave Equation Model SchrĞdinger’’s Wave Equation Though the Bohr model explained the spectrum of hydrogen, other aspects of the model were less successful at explaining the behavior of the hydrogen electron and the behavior of electrons in other atoms. In 1926, the German physicist Erwin SchrĞdinger developed equations which described the electron as if it were a wave, similar to the ““standing waves”” created by stringed instruments. Solutions to these equations are termed the quantum mechanical (wave) model for the atom. This model remains today our best explanation for the behavior of the hydrogen electron, and it is the basis for predicting the behavior of electrons in all other atoms as well. Solutions to the wave equation generally involve complex mathematics, and one question may have multiple solutions. In many respects, however, the wave equation produces a model for the hydrogen atom based on mathematical patterns that are elegant in their simplicity. The following points are part of the description of the hydrogen atom based on quantum mechanics.

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Module 23 —— Light and Spectra

Predictions of the Wave Equation For Hydrogen 1. Inside the hydrogen atom are levels described as n = 1, 2, 3, ……., ’ called principal quantum numbers. Higher quantum numbers represent higher energy levels. In the hydrogen atom, these energy levels have the En values calculated by the En equation in the Bohr model. 2. Around the H-atom nucleus are orbitals that describe the space where an electron is likely to be found. Each orbital has a shape that is described in terms of probability. The shape describes where an electron in the orbital will be 90% of the time. An electron in an orbital has an energy equal to one of the values of Bohr’’s En equation. 3. At each principal quantum number n, there are n2 total orbitals, and n different types of orbitals. a. At level n = 1, there is one orbital, the 1s orbital. An s orbital has a spherical symmetry around the nucleus: in an s orbital, at a given distance from the nucleus in all directions, there is an equal chance of finding an electron. b. At level n = 2, there are two types of orbitals and four total orbitals: one 2s orbital with spherical symmetry, and three 2p orbitals. The three p orbitals are perpendicular to each other; they can be described as falling on x, y, and z axes around the nucleus. c. At level n = 3, there are three types of orbitals and nine total orbitals: one spherical 3s orbital, three perpendicular 3p orbitals, and five 3d orbitals. Most (but not all) of the d orbitals are diagonal to the p orbitals. d. At level n = 4, there are four types of orbitals and 16 total orbitals: one 4s, three 4p , five 4d, and seven 4f orbitals. (It may help to remember the spdf order of the orbitals as ““stupid pirates die fighting.””) 4. The H-atom electron in its ground state is in the 1s orbital. If sufficient energy is added to an H-atom, its electron can be promoted into one of the higher energy orbitals. The above points can be summarized by a diagram. Below is the model for the H-atom predicted by the wave equation for the first four principal quantum numbers. Each line ( ___ ) represents an orbital. The Hydrogen Atom: Orbitals For the First Four Energy Levels 4s __

4p __ __ __

4d __ __ __ __ __

4f __ __ __ __ __ __ __ ( = 16 orbitals)

3s __

3p __ __ __

3d __ __ __ __ __

( = 9 orbitals)

2s __

2p __ __ __

1s __

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( = 4 orbitals ) ( = 1 orbital )

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Though the above diagram applies only to hydrogen, it is the basis for the orbitals found in all of the other atoms. Every atom has the same number and type of orbitals that are found in hydrogen. The difference will be that in other atoms, the orbitals will have different (but generally predictable) relative energies.

Practice Commit the diagram above to memory, then do the problems below. 1. At level n = 4 of the hydrogen atom are a. how many types of orbitals? b. How many total orbitals? c. Write the number and letter used to identify the types of orbitals, and list the number of orbitals there will be of each type, at n = 4. 2. At level n = 5, the H atom has orbitals designated 5s, 5p, 5d, 5f, and 5g. How many orbitals are there of each type?

ANSWERS 1. a. 4 types of orbitals

b. 16 total orbitals

c. c. One 4s, three 4p, five 4d, and seven 4f orbitals.

2. At n = 4, there are n2 = 16 total orbitals: 1 s, 3 p, 5 d, and 7 f . At level n = 5, there must be n2 = 25 total orbitals. 25 –– 16 = 9 additional orbitals at n = 5. At level n = 5, there must be one 5s, three 5p, five 5d, seven 5f, and nine 5g orbitals. * * * * *

Lesson 23G: Quantum Numbers Quantum Numbers For Hydrogen In the wave equation for the H-atom, each electron in an orbital can be identified by a series of quantum numbers that predict the characteristics of the orbital and of an electron in that orbital. 1. Principal quantum numbers are the n values: the integers 1, 2, 3, …… The value of n will predict the size and energy of the orbital. For higher n values, the orbitals occupy more volume and are at higher potential energy. An electron in orbitals with a higher n will on average be further from the nucleus than electrons in orbitals with a lower n in the same atom.

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2. Angular momentum quantum numbers (symbol l –– a lower-case script L ) at each n are numbered from 0 to nɔ1. Each l value correlates with one of the types (s, p, d, or f) of orbitals. The s orbital is l = 0, p orbitals are l = 1, d orbitals are l = 2, and f ‘‘s are l = 3. 3. Magnetic quantum numbers (symbol ml ) have values from ɔ l to 0 to +l . These numbers identify the multiple p, d, and f orbitals at each n. 4. Electron spin quantum numbers (symbol ms ) identify the spin of an electron in an orbital. An electron must have a spin of either +½ or ɔ½ . In these lessons, we will represent an electron that has a positive spin as Ń and one with a negative spin as Ņ . A way to remember these rules for quantum numbers is to memorize the H-atom orbital diagram above plus the quantum number diagram below for n = 4. Note the patterns of the numbers going from the bottom up. Relating Quantum Numbers and Orbitals 4s

4p

ml =

0

l =

0

n =

4

4d -1

0 1

1

4f -2 -1

0

1

2

-3

2

-2

Ń -1

0

1

2

3

3

The electron shown above in the 4f level would be described as having the quantum numbers n = 4, l = 3, ml = ɔ1, and ms = +½ . The diagram for level n = 3 is similar to n = 4 above, except that it will lack the f orbitals. The diagram for level n = 2 will have only s and p orbitals. The diagram for level n = 1 will have only the single s orbital.

Practice Commit the diagram in this lesson to memory, then do the problems below. 1. In a manner similar to the ““Relating Quantum Numbers and Orbitals”” diagram above, add numbers below the orbitals to complete the following chart. 3s

3p

3d

ml =

l = n = 2. At level n = 5, what quantum numbers are permitted for

a. l ?

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b. ml ?

c. ms ?

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3. Write the diagram for the first four (the lowest four) energy levels of the hydrogen atom, then add to the diagram one electron that has quantum numbers a. n = 3, l = 1, ml = 1, and ms = Ɇ½ . b. n = 4, l = 2, ml = Ɇ2, and ms = +½ . 4. Write symbols and values for the four quantum numbers that characterize the hydrogen atom electron when it is in the following orbitals. a.

2s Ņ

2p

b.

3s

3p

3d

c.

4s

4p

4d

Ņ 4f Ń

ANSWERS 1.

3s

3p

ml =

0

l =

0 3

n =

3d -1

1

-2 -1

1

2. a. l : 0 1 2 3 4 3.

0

b. ml :

a. 4s

4p

3s

3p

2s __

2p __ __ __

1

2

2 -4 - 3 -2 -1 0 1 2 3 4

4d ļ

0

4f

3d

c. ms : Always +½ and ʊ½ . ( = 16 total ) ( = 9 total ) ( = 4 total )

1s __

( = 1 total )

b. 4s

4p

4d Ń

3s

3p

3d

2s __

2p __ __ __

1s __

4f

( = 16 total ) ( = 9 total ) ( = 4 total ) ( = 1 total )

4. a. n = 2, l = 0, ml = 0, and ms = ʋ 1/2 . b. n = 3, l = 2, ml = ʋ1, and ms = ʋ 1/2 . c. n = 4, l = 3, ml = ʋ3, and ms = + 1/2 . * * * * *

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Summary: Light and Spectra 1. Wavelength: the distance between the crests of a wave. The symbol is nj (lambda). The units are distance units: either the base unit meters, or nanometers, etc. 2.

Frequency is a number of events per unit of time. The units are 1/time. For waves, frequency is the number of wave crests that pass a point per unit of time. In wave equations, the symbol for frequency is ǖ (nu). SI frequency units:

In equations, use

1/seconds = sɆ1 = hertz (Hz).

In conversions, use

wave cycles or wave lengths/second

In equation calculations, write hertz as sɆ1 so that units will cancel properly. 3. The speed of a wave is equal to its frequency times its wavelength. Wave speed = nj ǖ

= (lambda)(nu).

4. Electromagnetic waves travel at the speed of light (symbol c). For all electromagnetic waves,

c = nj ǖ = 3.00 x 108 m · sɆ1 in vacuum or air.

5. To simplify solving wave calculations using equations, a. In the DATA table, x

list the constants first.

x

Convert the DATA to consistent units: those of the constant of the equation if there is one, or those used in the WANTED unit, or an SI unit, in that order.

b. SOLVE for the consistent unit, then convert to a different WANTED unit if needed. 6. Planck’’s law that relates frequency and electromagnetic energy is

E=hǖ

or

E= h· c nj

where

h = Planck’’s constant = 6.63 x 10ʋ34 J · s

Higher frequency waves have higher energy and lower wavelength. 7. The energy levels inside a hydrogen atom can be calculated by En = Ɇ 21.8 x 10Ɇ19 J (per each atom) n2 The spectrum of the hydrogen atom can be explained by assuming the hydrogen atom electron moves between these energy levels. 8. The Hydrogen Atom: Orbitals For the First Four Energy Levels 4s __

4p __ __ __

4d __ __ __ __ __

4f __ __ __ __ __ __ __ ( = 16 orbitals)

3s __

3p __ __ __

3d __ __ __ __ __

( = 9 orbitals)

2s __

2p __ __ __

( = 4 orbitals )

1s __

( = 1 orbital ) # # # # #

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Module 24 —— Electron Configuration Pretests: In this module, if you believe that you know the material in a lesson, try two problems at the end of the lesson. If you can do those calculations, you may skip the lesson. * * * * *

Lesson 24A: The Multi-Electron Atom Orbitals For the Other Atoms SchrĞdinger’’s wave equation predicts mathematically the observed behaviors of the hydrogen atom. However, for atoms with more than one electron, the wave equation provides less exact predictions of how an atom will behave. Why? In the case of hydrogen, one proton and one electron attract. Mathematics is able to precisely model the forces in this ““two body”” problem, but if a second electron is added to the atom, the situation is more complex. Because the protons are tightly packed into the nucleus, nuclei with more than one proton behave as a single point of positive charge. Multiple electrons will be attracted to those protons, but unlike the case of hydrogen with one electron, two or more electrons also repel each other. How much will they repel? It depends in part on the types of orbitals that the electrons occupy. At n = 2, an electron in the 2s orbital will on average be closer to the nucleus than an electron in a 2p orbital. This closer 2s electron, by repelling the 2p electron, will act to shield the 2p electron slightly from the attraction of the protons in the nucleus. This means that the 2p orbital will be slightly higher in energy than the 2s orbital. The result of these and other factors is x

the wave equation predicts qualitatively, but not exactly, how electrons in atoms other than hydrogen will behave, and

x

the orbital diagram for multi-electron atoms will be different from that of hydrogen.

In neutral atoms other than hydrogen, the orbitals have different energy values in each atom, but the orbitals are generally arranged in the same order. This means that for the atoms in the periodic table, there will be only two types of energy level diagrams to learn: one for hydrogen, and one that works in most cases for all of the other atoms.

The Orbital Diagram for Multi-Electron Atoms For neutral atoms other than hydrogen, these rules apply. 1. All atoms have the number and kind of orbitals predicted by the wave equation for the hydrogen atom, but the orbitals are arranged in a different order based on their relative energies. 2. The energy level diagram has clusters of orbitals. Large energy gaps separate these clusters, but within a cluster, energy levels are close.

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3. The lowest energy level in a cluster is always an s orbital. The energy of this s orbital is relatively high compared to the energy of the orbitals below it, but the s orbital is relatively close in energy to the orbitals above it in the cluster. 4. The d orbitals are shielded by both the s and p orbitals, so much so that in neutral atoms, the d orbitals rise to between the energy of the s and p orbitals with one higher principal quantum number. For the five lowest energy clusters, the sublevels in order of increasing energy are 1s

2s 2p

3s 3p

4s 3d 4p

5s 4d 5p

5. The f orbitals are more shielded than the d orbitals, so much so that the 4f orbitals for most neutral atoms have energy slightly above the 6s orbital, but below the 5d orbital. For most neutral atoms, the 6th and 7th clusters have sublevels in this order: 6s 4f 5d 6p

7s 5f 6d 7p .

These rules result in the Energy-Level Diagram for a Multi-Electron Atom 7p

6d

6p

5d

7s

6s

5s

4s

3s

2s

5p

4p

5f

32

4f

32

4d

18

3d

18

3p

8

2p

8

2

1s

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The numbers at the right side of the diagram show the number of electrons that the cluster will hold. When a series of orbitals is at the same energy, such as in the three p orbitals or five d orbitals, the orbitals are said to be in a sublevel, and the orbitals are termed degenerate. At this point, to understand why we write the sublevels in the order that we do, you need to be able to draw the bottom four clusters of the above diagram from memory. At a later point, you will need to draw the complete diagram, but as we will see, patterns that relate the orbital diagram to the periodic table will make this task much easier.

The Orbital Electron Configuration A key step in understanding the chemical behavior of atoms is to write the electron configuration of the atom: showing which orbitals are filled, half-filled, and empty. This electron configuration can be determined by filling the orbital-energy-level diagram with the atom’’s electrons. Rules for Filling the Orbital Energy Level Diagram To write the orbital electron configuration for a neutral atom, use these steps. 1. Find the number of electrons in the atom. The atomic number is the number of protons in an atom. In a neutral atom, this is also the number of electrons. 2. Put the electrons into the orbitals one at a time. Each electron will fall to the unfilled orbital with the lowest energy. This rule, that the orbitals fill from the lowest energy up, is called the aufbau principle. 3. An orbital becomes filled when it has two electrons; it cannot have more than two. The electrons must have opposite spins. This rule is termed the Pauli exclusion principle, which says that no two electrons in an atom can have the same four quantum numbers. An electron must have one of two possible spins, described as spin up and spin down.. In these lessons, we will represent an electron with a spin up as Ń and a down spin as Ņ . If an orbital has two electrons, the electrons are said to be paired and the orbital is filled. If an orbital has only one electron, it is termed is half-filled and has an unpaired electron. 4. Each electron has a spin with a value of + 1/2 or ——1/2 . In these lessons, we will represent an electron with a positive spin as Ń and a negative spin as Ņ . If a series of orbitals is at the same energy, fill each orbital with one electron, and give all the electrons in this sublevel the same spin. By convention, positive spins ( Ń ) are assigned first), before you start to pair electrons. (This is Hund’’s rule.) Example: The neutral atom carbon has 6 electrons. Fill the orbital diagram with the six electrons from the bottom up. Each s orbital is filled with two electrons that have opposite spins. For the 2p orbitals, since the three p orbitals are at the same energy, put one electron with an up spin in each orbital before you start to pair electrons.

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Module 24 —— Electron Configuration

The resulting carbon electron configuration is 2s ŃŅ

2p Ń Ń

1s ŃŅ Carbon has two filled orbitals, two half-filled orbitals, and two unpaired electrons. For some neutral atoms, the actual experimentally determined electron configurations differ slightly from those predicted by the rules above. However, these rules predict the actual configurations for over 90% of the neutral atoms in the periodic table.

Practice Practice writing the bottom 4 clusters (from the 1s to the 4p orbitals) of the orbital energylevel diagram until you can do so from memory, then do the problems below. Use a periodic table. 1. The following are electron configurations for neutral atoms. Name the atoms. a.

2s ŃŅ

2p Ń

b.

2s ŃŅ

1s ŃŅ

2p ŃŅ ŃŅ

Ń

1s ŃŅ

2. Draw the orbital electron configuration for a. Nitrogen

b. Neon

c. Phosphorous

d. Nickel

3. How many unpaired electrons are found in neutral atoms of a. Nitrogen (2a above)

b. Nickel (2d above)

ANSWERS 1. a. Contains 5 electrons = Boron (B) 2. a.

2s ĹĻ

2p Ĺ Ĺ

Ĺ

b. 9 electrons = Fluorine (F) b.

1s ĹĻ c.

3s ĹĻ 2s ĹĻ

2s ĹĻ

2p ĹĻ ĹĻ ĹĻ

1s ĹĻ 3p Ĺ Ĺ

Ĺ

2p ĹĻ ĹĻ ĹĻ

1s ĹĻ

d.

4s ĹĻ 3s ĹĻ 2s ĹĻ

4p

3d ĹĻ ĹĻ ĹĻ Ĺ

3p ĹĻ ĹĻ ĹĻ 2p ĹĻ ĹĻ ĹĻ

1s ĹĻ

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Module 24 —— Electron Configuration

3. a. Nitrogen: 3 unpaired electrons

b. Nickel: Two unpaired electrons

* * * * *

Lesson 24B: Listing the Sublevels The Order of the Sublevels A method that will show the electron configuration of an atom without drawing the orbital diagram is to list the sublevels in order of increasing energy, and to include the number of electrons in each sublevel. Example: The configuration for silicon (Si) can be written as: 1s2

2s2 2p6

3s2 3p2

This method does not show as much information as writing the orbital diagram, but this method is quicker, and from it we can determine which orbitals are totally filled, partially filled, and unfilled. That is the information we will need most often to answer questions about electron configuration. To write the electron configuration for a neutral atom by listing the sublevels, follow these steps. 1. Before you begin to write the configuration for specific atoms, it is helpful to write the sublevels for the multi-electron atom in order of increasing energy (from the bottom up). This list is 1s

2s 2p

3s 3p

4s 3d 4p

5s 4d 5p

6s 4f 5d 6p

7s 5f 6d 7p ……

As you write the sublevel numbers and letters, leave a gap in front of each of the s orbitals in the series. This gap indicates the large gap in energy between the clusters in the orbital diagram, a factor that is important in t in determining how much energy must be added to remove electrons from an atom or ion. In listing the sublevels and clusters in order, it may help to note that each of the clusters begins with the number of the cluster followed by an s, and ends (except for the first cluster) with the number of the cluster followed by a p. Another way to remember the order of

7s 7p

the sublevels in the list above is to draw

6s 6p 6d 6f

the memory device at the right.

5s 5p 5d 5f 5g

To create this diagram, first

4s 4p 4d 4f

draw the order for the orbitals of the

3s 3p 3d

hydrogen atom (as shown), and then add

2s 2p

the diagonal arrows pointed left and up.

1s

2. To write the electron configuration for a specific atom by listing the sublevels, first find the number of electrons in the atom (which is equal to its atomic number).

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Module 24 —— Electron Configuration

3. Then write the sublevels in order of increasing energy, as listed above. As you go, fill each sublevel full of electrons. Add superscripts to indicate the number of electrons that fill each sublevel. x

An s orbital is filled when it has 2 electrons.

x

A p orbital sublevel is full when it has 6 electrons.

x

A d orbital sublevel can hold 10 electrons.

x

An f orbital sublevel can hold 14 electrons.

A full 1s orbital is written as 1s2 (read as ““one s two””). A full 3d sublevel is written: 3d10 (read as ““three d ten””). 4. When not enough electrons remain to fill a sublevel, write the number of remaining electrons as a superscript, then stop. Examples: a. Sodium is atomic number 11; the neutral Na atom has 11 electrons. To write the Na electron configuration, write the list of sublevels, filling them with electrons as you go, until you run out of electrons. The Na shorthand configuration is written Na: 1s2

2s2 2p6 3s1

The sum of the superscripts must equal the number of electrons: 2 + 2 + 6 +1 = 11 Note that when the sublevels are written in order of increasing energy, all of the sublevels before the last sublevel must be filled. b. Iridium (Ir) has 77 electrons. Its shorthand configuration is: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p6

5s2 4d10 5p6

6s2 4f14 5d7

To check your answer, add up the superscripts. The total must be the number of electrons in the atom.

Practice A Use a periodic table. Check your answers after each part. 1. Write the memory device that lists the orbitals in order of increasing energy, then write the orbitals on one line, in order of increasing energy, from 1s to 7p. 2. Write the electron configuration by listing the sublevels for a. Oxygen

b. Sulfur

3. How many unpaired electrons are in a. Oxygen

b. Sulfur

5. A shortcut: note that for each atom, its highest cluster starts with the number of the row in which the atom is found in the periodic table, followed by an s.

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When listing the sublevels, find the number of the row that the atom is in, then write full sublevels until you reach the s orbital with that number. That s orbital will start the highest cluster. Examples: a. Sodium is in the third row of the periodic table (rows go across). Its electron configuration is:

1s2

2s2 2p6

3s1

The highest cluster in which sodium has electrons begins with 3s . b. Iridium is in the sixth row of the table. Its configuration is: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p6

5s2 4d10 5p6

6s2 4f14 5d7

6. To find the number of unpaired electrons in a neutral atom, draw the orbital diagram, but do so only for the sublevel that is unfilled in the highest cluster. Examples: In sodium above, all of the levels below 3s1 are filled. They will contain no unpaired electrons. The final term is 3s1, which is shorthand for the orbital configuration 3s Ń . Sodium therefore has one unpaired electron. In iridium above, all of the orbitals below 5d7 are filled. In the highest occupied cluster, the one sublevel with unfilled orbitals has the electron configuration 5d7 which i represents the orbital configuration 5d ŃŅ ŃŅ Ń Ń Ń . Neutral Iridium has 3 unpaired electrons.

Practice B Use a periodic table. Check your answers after each part. 1. Listing the sublevels, write the electron configuration for a. Fe

b. Br

c. Kr

2. How many unpaired electrons are in a. Fe

b. Br

c. Kr

3. a. Strontium is in which row of the periodic table? b. Listing the sublevels, write the electron configuration for strontium. c. Into which orbital did strontium’’s last (highest energy) electron go?

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ANSWERS Practice A 1. 1s 2s 2p

3s 3p

4s 3d 4p

5s 4d 5p

2. a. Oxygen: 1s2 2s2 2p4

6s 4f 5d 6p

7s 5f 6d 7p.

b. Sulfur: 1s2

2s2 2p6

3s2 3p4

3. To find the number of unpaired electrons, look only at the highest sublevel with electrons. a. Oxygen: 2p4 = 2p ĺļ ĺ ĺ

= 2 unpaired eņ

b. Sulfur: 3p4 = 3p ĺļ ĺ ĺ

= 2 unpaired eņ

Practice B 1. a. Fe: 1s2

2s2 2p6

3s2 3p6

4s2 3d6

Kr: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p6

c.

b. Br: 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p5

3. To find the number of unpaired electrons, look only at the highest sublevel with electrons. a. Fe: 3d6 = 3d ĺļ ĺ ĺ ĺ ĺ b. Br:

4p5 = 4p ŃŅ ŃŅ Ń

c. Kr:

4p6 = 4p ŃŅ ŃŅ ŃŅ b. Sr: 1s2

3. a. Row 5

= 4 unpaired eņ

= 1 unpaired eņ = 0 unpaired eņ 2s2 2p6

3s2 3p6

4s2 3d10 4p6

5s2

c. 5s

* * * * *

Lesson 20C: Abbreviated Electron Configurations The electron configurations written by listing the sublevels can be abbreviated by using the symbol for the appropriate noble gas to represent totally filled lower-energy clusters. Example: Lead, atomic number 82, has an electron configuration Pb: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p6

5s2 4d10 5p6

6s2 4f14 5d10 6p2

but this configuration can be abbreviated as Pb: [Xe] 6s2 4f14 5d10 6p2 The symbol [Xe] represents the five filled lower clusters. This form for the electron configuration is known by a variety of names. In these lessons we will call this the abbreviated electron configuration, but you may also see this referred to as the shorthand or core electron or noble gas shortcut electron configuration. Because this form for electron configurations is the fastest of the three types of configurations to write, it is the one written most often.

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Configurations written using noble gas symbols are also helpful because they separate the core electrons (in the filled lower clusters) from the non-core electrons. The core electrons around an atom do not change when the atom bonds or participates in chemical reactions. The non-core electrons are those that are in the highest cluster that contains electrons: the electrons written to the right of the noble gas symbol in the abbreviated electron configuration. In chemistry, the focus of our attention will be the electrons written to the right of the noble gas symbol. Those non-core electrons are the electrons that are gained or lost in chemical reactions and are shared in covalent bonds.

Writing Abbreviated Electron Configurations For Neutral Atoms 1. Use the symbol for the appropriate noble gas to represent totally filled lower-energy clusters. The electrons in these filled lower clusters are termed the core electrons. [He] = 1s2 = 2 electrons [Ne] = 1s2 2s2 2p6 = 10 eɔ [Ar] = 1s2 2s2 2p6 3s2 3p6 = 18 eɔ [Kr] = 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 = 36 eɔ [Xe] = 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6 = 54 eɔ [Rn] = 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6

6s2 4f14 5d10 6p6 = 86 eɔ

Note that except for helium, all of the noble gas electron configurations end in p6, and the number in front of the p6 is the row of the periodic table that the noble gas completes. Example: Aluminum is atomic number 13. The shorthand electron configuration for a neutral Al atom is Al: 1s2 2s2 2p6 3s2 3p1 To write the abbreviated configuration, note that Al has 13 electrons. The noble gas in the chart above that can be used to represent the filled lower clusters is neon, which has 10 electrons. The abbreviated electron configuration for Al is Al: [Ne] 3s2 3p1

(10 + 2 + 1 = 13)

The symbol [Ne] represents two filled lower clusters containing 10 electrons. 2. For a simplified way to write abbreviated configurations for neutral atoms, use these steps. a. Find the atom in the periodic table. Note its number of electrons. b. Write in brackets [ ] the symbol of the noble gas at the end of the row above the atom. c. After the [noble gas], write the number of the row in the periodic table that the atom is in, followed by an s. This will get you started on writing the orbitals in the highest unfilled cluster.

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Example: Find vanadium (V) in the 4th row of the table. Ar is at the end of the row above V. Start vanadium’’s abbreviated configuration by writing V: [Ar] 4s d. Starting from the number of electrons in the noble gas, add electrons to fill the sublevels until you run out. e. To check your configuration, add the number of electrons in the noble gas (equal to its atomic number) plus the superscripts to the right of the noble gas symbol. This total must equal the number of electrons in the neutral atom (its atomic number). Try the steps in Rule 2 on this question. Q.

Write the abbreviated electron configuration for tungsten (W), atomic number 74.

* * * * * Tungsten is in the 6th row of the periodic table. The noble gas at the end of the 5th row is xenon (Xe). Start the electron configuration by writing W: [Xe] 6s Xe has 54 electrons and W has 74. Fill the unfilled cluster until you run out of electrons. W: [Xe] 6s2 4f14 5d4 is the abbreviated configuration. Check: 54 + 2 + 14 + 4 = 74 * * * * * 3. The valence electrons establish many of the properties of a neutral atom. For the main group atoms (in the tall columns of the periodic table), the valence electrons are defined as all of the s and p electrons in the highest unfilled cluster (the s’’s and p’’s to the right of the noble gas symbol). Examples: Al: [Ne] 3s2 3p1 has two s and one p electron to the right of the noble gas symbol. Aluminum therefore has the 10 core electrons represented by [Ne], plus 3 valence electrons. I: [Kr] 5s2 4d10 5p5 has two s and five p electron to the right of the noble gas symbol, so iodine has 7 valence electrons. For main group atoms, the d and f electrons are not considered to be valence electrons. The valence electrons are the electrons most likely to be involved in chemical reactions and covalent bonding. Compared to the electrons in other orbitals, the valence electrons are ““loosely bound.”” For transition metals and the two rows below the main table, the electrons considered valence electrons in some cases may also include the d or f electrons. In reactions of atoms whose highest energy electron is in a d or f orbital, the d and f electrons are not as loosely bound as the s electrons, but the d and f electrons are more loosely bound than the core electrons, and they may be involved in chemical reactions and processes. Apply those rules to this Q. How many valence electrons are in lead (Pb)?

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* * * * * Pb: [Xe] 6s2 4f14 5d10 6p2 has two s and two p electron to the right of the noble gas symbol, so lead has 4 valence electrons. For main group atoms, the valence electrons are limited to the s and p electrons in the highest cluster that contains electrons.

Practice B:

Use a periodic table. Check your answers after each part.

1. List in order the sublevels in the 4th cluster of the orbital energy-level diagram. 2. What noble gas symbol would be used to represent five full orbital clusters? 3. When writing an abbreviated electron configuration, what would be the first sublevel that would be written after these noble gas symbols? a. [He]

b. [Kr]

c. [Rn]

4. Write the abbreviated electron configuration for these neutral atoms. a. Li (3)

b. Cl (17)

c. Iodine (53)

d. Yttrium (39)

e. Polonium (84)

5. Write the number of valence electrons for these Problem 4 atoms. a. Li (3)

b. Cl (17)

c. Iodine (53)

6. Write the number of core electrons in

e. Polonium (84)

4a. Li

4b. Cl

7. What is the highest number of valence electrons that a main group neutral atom can have? 8. For the 2nd neutral atom in the 4th row of the periodic table, a. what is its abbreviated electron configuration? b. What ion does this atom tend to form? c. What would be the electron configuration for the ion that this atom tends to form?

ANSWERS Practice A 1. 1s 2s 2p 3s 3p 4s 3d 4p 5s 4d 5p 6s 4f 5d 6p 7s 5f 6d 7p. 2. a. Oxygen: 1s2 2s2 2p4

b. Sulfur: 1s2

Fe: 1s2

2s2 2p6

3s2 3p6

4s2 3d6

e. Kr: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p6

c.

2s2 2p6

3s2 3p4

d. Br: 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p5

3. To find the number of unpaired electrons, look only at the highest sublevel with electrons. a. Oxygen: 2p4 = 2p ĺļ ĺ ĺ

= 2 unpaired eņ

b. Sulfur: 3p4 = 3p ĺļ ĺ ĺ

= 2 unpaired eņ

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c. Fe: 3d6 = 3d ĺļ ĺ ĺ ĺ ĺ d. Br:

4p5 = 4p ŃŅ ŃŅ Ń

e. Kr:

4p6 = 4p ŃŅ ŃŅ ŃŅ

4. a. Sr: 1s2

2s2 2p6

= 4 unpaired eņ

= 1 unpaired eņ = 0 unpaired eņ

3s2 3p6

4s2 3d10 4p6

5s2

b. Row 5

c. 5s

Practice B 1. 4s 3d 4p

2. [Xe] at the end of the 5th row.

3. a. [He] 2s The number of the s orbital is the row number that the atom is in. b. [Kr] 5s 4. a. Li (3): [He] 2s1

b. Cl (17): [Ne] 3s2 3p5

d. Yttrium (39): [Kr] 5s2 4d1

c. [Rn] 7s

c. Iodine (53): [Kr] 5s2 4d10 5p5

e. Polonium (84): [Xe] 6s2 4f14 5d10 6p4

5. Valence electrons: a. Li (3) one

b. Cl (17) seven

c. Iodine (53) seven

e. Polonium (84) six 6. a. Lithium has 2 core electrons represented by [He]

b. Cl has 10 core electrons represented by [Ne]

7. Eight. The highest number of s and p electrons possible in the highest cluster is 2 in the s and 6 in the p. 8. a. Ca: [Ar] 4s2

b. Ca2+

c. [Ar] . To form the 2+ ion, calcium loses its two valence electrons.

* * * * *

Lesson 24D: The Periodic Table and Electron Configuration The Shape of the Table Atoms that are in the same column of the periodic table have similar behavior because those atoms have similar configurations for their highest energy electrons. The correlations between a standard periodic table and electron configuration includes: 1. The periodic table starts with hydrogen, which has one proton and one electron. One proton and one electron are then added for each atom moving to the right across the rows of the periodic table. When a cluster in the orbital energy level diagram is filled, the result is the electron configuration of a noble gas. After each noble gas, a new row of the table is started. This convention places all of the noble gases in the last column. All noble gases have totally filled clusters. 2. Comparing the orbital energy level diagram and the periodic table: x

The orbital energy level diagram has 7 clusters of energy levels and the periodic table has 7 rows.

x

If the highest energy electron for an atom is added into the 4th cluster, that atom is in the 4th row of the periodic table.

x

If an atom is in the 5th row of the table, its highest energy electron is found in the 5th cluster: the one that start with the 5s orbital.

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3. The number of electrons a cluster can hold equals the number of atoms in each row of the periodic table. x

The lowest cluster of the orbital diagram can hold two electrons. The first row of the periodic table has two atoms: H and He.

x

The second and third clusters in the orbital energy diagram each hold 8 electrons. The second and third rows of the periodic table each have 8 atoms. Across these rows, 8 electrons are added to the atoms, one electron at a time. x

The fourth cluster has the orbitals 4s 3d 4p . These three sublevels can hold 18 electrons. The fourth row of the table has how many atoms?

* * * * * 18. Count them to be sure. x

The sixth cluster has the orbitals 6s 4f 5d 6p . These four sublevels can hold 32 electrons. The sixth row of the periodic table has 32 atoms (because it includes the first row of atoms in the two rows listed below the chart).

Practice A:

Use a periodic table. If needed, check your answers after each part.

1. What is the abbreviated electron configuration (using the noble gas symbol) for the first neutral atom in the 7th row of the periodic table? 2. Which p orbitals are filling in the 5th row of the periodic table? 3. Which d orbitals are filling in the 4th row of the table? 4. Which f orbitals are filling in the 7th row of the table? x 4. The shape of the periodic table is determined by the order in which the orbitals fill in the orbital energy-level diagram.

s block

p block d block

f block

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x

All neutral atoms that are in the first two columns of the periodic table are in the s block (see diagram above). For the atoms in this block, the s orbitals are filling: these atoms always have their highest energy electron going into an s orbital. For neutral atoms in the first column, all electron configurations end in s1. In the second column, all end in s2.

x

All of the neutral atoms in the six tall columns at the right in the table are in the p block: they have their highest energy electron going into a p orbital (except for helium). In Group 3A (the boron family), all electron configurations end in p1. In the noble gas column, all end in p6 (except for helium, which ends in s2 to fill the first cluster).

x

All transition metals are in the d block: they have their highest energy electron going into a d orbital. The transition metals are placed after the s tall columns but before the p tall columns because the d orbitals fill the orbital diagram after the s, but before the p orbitals. In the each row of the periodic table, as in each cluster of the orbital energy level diagram, the d orbitals that are filling have a principal quantum number that is one less than the quantum number of the s orbital that fills immediately before them. o

After the 4s orbitals fill, the 3d orbitals fill. After the 5s fill, the 4d fill.

Examples: The first transition metal, scandium (Sc), has an electron configuration that ends in 3d1. The second, titanium (Ti), ends in 3d2. The last transition metal in that row, zinc (Zn) has an electron configuration that ends in 3d10. Mercury (Hg), two rows below zinc in the table, has an electron configuration that ends in 5d10. As you might expect, cadmium (Cd), in the row between zinc and mercury, has an electron configuration that ends in …….? * * * * * 4d10 x

The atoms in the two rows below the table are in the f block: they have their highest energy electrons going into f orbitals. Since there is room for 14 electrons in the seven f orbitals, there are 14 atoms in each of the two rows placed below the table. In the first row below, called the lanthanides because the row begins with lanthanum, the 4f orbitals are filling. In the second row, the actinides, the 5f orbitals are filling. In the each row of the periodic table, as in each cluster of the orbital energy level diagram, the f orbitals that are filling have a principal quantum number that is two less than the s orbital that fills immediately before them: o

After the 6s orbitals fill, the 4f orbitals fill. After the 7s fill, the 5f fill.

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Practice B:

Use a periodic table. If needed, check your answers after each part.

1. Which orbitals are being filled in the 6th row of the periodic table, in order? 2. Where in the periodic table are the neutral atoms that have electron configuration ending in a. s2

b. p6

c. p2

3. Name the four neutral atoms whose electron configuration ends in d2 .

The Columns of the Table 4. Atoms in the same column of the table have similar electron configurations. Examples: x

All of the atoms in column one have an electron configuration ending in s1. H ends in 1s1, Li in the 2nd row ends in 2s1, Fr in the 7th row ends in 7s1.

x

All halogens (Group 7A) have electron configurations ending in p5. All halogens have seven valence electrons: two s and five p electrons in their highest cluster.

x

All neutral atoms in the carbon family (Group 4A) have an electron configuration ending in p2. All have four valence electrons: two s and two p electrons.

x

The number of valence electrons for an atom is the number of the main (A) group (using the A-B group notation) for its column of the periodic table. Example: All atoms in Group 7A (the halogens) have seven valence electrons.

The patterns in the periodic table will help you to write all of the various types of electron configurations. For example, the table below shows the highest energy sublevel for atoms in the last column of each block of the table. Note the patterns

1s2 2s2

2p6

3s2

3p6

s 4s2 block 5s2 6s2

3d10

d block

7s2

4p6

4d10

5p6

5d10

6p6

6d10

f block

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p block

4f14 5f14

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On this table, from the top down, reading across each row, write the filled sublevel configurations shown for the first 4 rows of the table. Leave a little extra room before you start a new row. * * * * * 1s2

2s2 2p6

3s2 3p6 4s2 3d10 4p6…….

Note that this is the order used when listing the sublevels to write an electron configuration.. This diagram will also help in quickly identifying the configuration of the highest energy sublevel of an atom. Example: Tellurium (Te) has 52 electrons. Find Te in the periodic table. Then mark where it will be in the above table. Decide from the position in the above table the configuration of the highest energy sublevel. Based on its position, Te’’s highest energy orbital will have the configuration: _______ * * * * * 5p4 . For the shorthand configuration, simply write all of the bold orbitals above, in order from the top and across the rows, until you get to Te’’s 5p4 , then stop. Try it. * * * * * Te: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p6

5s2 4d10 5p4

To write the abbreviated configuration, write the [noble gas] at the end of the row above Te, then write the filled orbitals shown in the row that Te is in, with the last sublevel being the highest energy sublevel for Te. Try it. * * * * * Te: [Kr] 5s2 4d10 5p4 As a check for both types of configurations, count the electrons represented by each. * * * * * You should get 52, the number of electrons in a neutral Te atom. * * * * *

Mendeleev’’s Periodic Table In 1872, the Russian chemist Dmitri Mendeleev proposed a periodic table as a way to predict chemical behavior. The existence of protons and electrons would not be discovered for decades. In fact, at the time, many of the atoms currently in the periodic table had not yet been discovered. Mendeleev bravely predicted that atoms would be discovered to fill the holes he left in his table. Based on the patterns in his table, he described what the characteristics of these undiscovered atoms would be. His predictions soon proved correct, and his periodic table became the central framework for organizing chemical behavior . Mendeleev’’s 1872 table is remarkably similar to the modern periodic table. We know today what Mendeleev did not: why the atoms are organized the way they are in his table. The shape of the table is determined by the order of the electron orbitals that are predicted to exist by SchrĞdinger’’s wave equation. The atoms in columns have similar behavior because they have similar electron configurations in their highest occupied cluster.

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Practice C: Use a periodic table. On problems with parts, 9 and complete every other part. Save the rest for your next practice session. 1. What do the rare earth atoms have in common with regard to their electron configuration? 2. Why do the rare earth atoms fit into the periodic table before the transition metals begin, rather than after? 3. Write the orbital configuration of just the highest unfilled sublevel for these neutral atoms. a. Iodine (53)

b. Cobalt (27)

c. Rubidium (37)

4. Write the shorthand electron notation (1s2 2s2……) for these atoms. a. Gallium (31)

b. Zirconium (40)

5. Write the predicted abbreviated electron configuration (using noble gas symbols) for a. Magnesium (12) d. Potassium (19) g. Mercury (80) j. Fluorine (9)

b. Osmium (76)

c. Aluminum (13)

e. Phosphorous (15)

f. Polonium (84)

h. Plutonium (94) k. Iron (26)

i. Rutherfordium (104) l. Beryllium (4)

6. Where are the atoms located that have a. One valence electron?

b. 7 valence electrons?

ANSWERS 1. [Rn] 7s1 2. 5p . The principal quantum number of the filling p orbitals is the row number in the table. 3. 3d . The principal quantum number of the filling d orbitals is one less than the row number. 4. 5f . The principal quantum number of the filling f orbitals is two less than the row number. Practice B 1. 6s 4f 5d 6p

2a. In Group 2A (the 2nd tall column). 2b . Noble gases below He.

2c. In the 2nd tall column to the right of the transition metals (the carbon family). 3. Titanium (Ti), Zirconium (Zr) Hafnium (Hf), and Rutherfordium (Rf). Practice C 1. Using our rules for predicting electron configuration, the highest energy electron is going into an f orbital. 2. Using our rules, the f orbitals are at lower energy than the d orbital with one higher principal quantum number; the f orbitals fill before the d’’s. 3.

a. Iodine 5p ŃŅ ŃŅ Ń

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b. Cobalt 3d ĹĻ ĹĻ Ĺ

Ĺ

Ĺ

c. Rubidium 5s Ĺ

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4. a. Ga:

1s2

b. Zr: 1s2

2s2 2p6

3s2 3p6

4s2 3d10 4p1

2s2 2p6

3s2 3p6

4s2 3d10 4p6

5. a. Mg: [Ne] 3s2

5s2 4d2

b. Os: [Xe] 6s2 4f14 5d6

c. Al: [Ne] 3s2 3p1

d. K: [Ar] 4s1

e. P: [Ne] 3s2 3p3

f. Po: [Xe] 6s2 4f14 5d10 6p4

g. Hg: [Xe] 6s2 4f14 5d10

h. Pu: [Rn] 7s2 5f6

i. Rf: [Rn] 7s2 5f14 6d2

j. F: [He] 2s2 2p5

k. Fe: [Ar] 4s2 3d6

l. Be: [He] 2s2

6. a. In the first column of the periodic table.

b. In the halogen family: tall column 7.

* * * * *

Lesson 24E: Electron Configurations: Exceptions and Ions Exceptions to the Standard Predictions Not all of the actual electron configurations follow the rules above, but many of the exceptions can be predicted. In predicting exceptions, the rules are 1. A series of orbitals at a sublevel (orbitals with the same energy) often have lower potential energy if they are empty, half-filled or totally filled. The expected electron configurations predicted by the standard rules often rearrange to form these energy configurations that gain them special stability. Example: Write the standard predicted electron configuration for chromium (24): [

]

How many unpaired electrons would chromium have? * * * * * By the standard rules, Cr = [Ar] 4s2 3d4 4p Ĺ 3d Ĺ Ĺ Ĺ 4s ĹĻ In this orbital diagram, chromium has four unpaired electrons, but chromium has an exceptional configuration. Based on the rule above, predict what it might be. The highest unfilled cluster would be

* * * * * If one of the chromium 4s electrons is promoted slightly, up to the 3d orbitals, both the 4s and the 3d orbitals become half-filled. This configuration is

4s Ĺ

4p

3d Ĺ

Ĺ

Ĺ

Ĺ

Ĺ

= [Ar] 4s1 3d5

If a system can go to lower potential energy, it strongly tends to do so. Measurements of the behavior of neutral chromium atoms find that they have the six unpaired electrons predicted by this exception rule. Other atoms below chromium in the same column may have similar behavior, but the exceptions do not always occur. Experimental measurement of the number of unpaired

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electrons is often required to determine the actual electron configuration of a neutral atom or ion when exceptions are possible. 2. The electron configurations of the rare-earth atoms contain many exceptions, especially in the early columns. The reason is that the d and the f orbitals are very close in energy. Many of the exceptions have a non-standard-prediction d1 electron, such as Ce (58): [Rn] 6s2 4f1 5d1

and

U (92): [Rn] 7s2 5f3 6d1

But, by a slim majority, most rare earth atoms have the s2 f* d0 configuration predicted by the standard rules for filling the orbital energy-level diagram. Some periodic tables list La and Ac in the 14 columns below the table. Others place La and Ac in the transition metals, and instead list Lu and Lr at the end of the 14 lower columns. Arguments can be made for both conventions.

Practice A:

Use a periodic table. If needed, check your answers after each part.

1. Write the abbreviated electron configuration (using noble gas symbols) that would be predicted, using the standard rules, for a. Nickel (28)

b. Palladium (46)

After each configuration above, write the predicted number of unpaired electrons. 2. By experiment, palladium is found to have no unpaired electrons. Write what this exceptional electron configuration is likely to be, and explain why it would be stable. 3. Find the three coinage metals (copper, silver, and gold) in the periodic table. These atoms have been treated as a special group since ancient times. All are metals that retain their shine and resist corrosion when compared to most metals. Their exceptional stability arises in part from their exceptional electron configurations. a. Write the standard prediction of the abbreviated configuration for gold (79). b. What would be the exceptional configuration for gold, and why would it be stable? c. In its exceptional electron configuration, how many unpaired electrons does gold have? How many valence electrons?

Electron Configurations For Ions Atoms tend to form ions that have the same number of valence electrons as the nearest noble gas. The noble gases have eight valence electrons (except for helium that has 2). To write electron configurations for monatomic ions, follow these steps. 1. First write the neutral electron configuration. 2. To form negative ions, add electrons in the standard order. 3. To form positive ions, take away electrons from the highest cluster. Take the electrons out in this order: take first the p’’s then the s’’s, then the d’’s, then the f’’s.

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Note that in making positive ions, the electrons are taken out of a neutral atom in a different order than they go in. Electrons are lost first from the orbitals with the highest principal quantum number. This means that for main group atoms, the valence p then s electrons are taken away first. Why? When an electron is taken away, the repulsion of all the electrons is reduced, and the shielding of the d and f orbitals is reduced. In postitive ions, this drops the d and f orbitals to a lower relative energy than they have in neutral atoms. For example, the 3d orbitals, which in a neutral atom are higher in energy than the 4s orbitals, in 4th row positive ions drop to an energy lower than the 4s orbitals. Apply the three rules above to these two examples, then check your answers below. Q1. Write the abbreviated electron configuration for the chloride ion, Clɔ. Q2. Write the abbreviated electron configuration for the tin (IV) ion, Sn4+. * * * * * A1.

Neutral chlorine is [Ne] 3s2 3p5, chloride ion has one more electron: [Ne] 3s2 3p6 This gives chloride the same electron configuration as argon, the nearest noble gas. When two atoms have the same electron configuration, they are said to be isoelectronic. Iso- is a prefix from ancient Greek meaning equal.

A2.

Neutral tin has a configuration of [Kr] 5s2 4d10 5p2, and Sn4+ is [Kr] 4d10 . The 4+ ion has lost four electrons: the two 5p electrons, then the two 5s electrons. This gives the tin ion zero valence electrons. Ions tend to have either zero or 8 valence electrons, giving them the same valence configuration as the nearest noble gas.

It is difficult to add an electron to, or to remove an electron from, a noble gas electron configuration. Atoms with electron configurations close to that of a noble gas are very reactive, usually undergoing reactions that result in their attaining a noble gas electron configuration. This tendency is a driving factor in a wide range of chemical reactions.

Practice B:

Use a periodic table. If needed, check your answers after each part.

1. Add a charge to these symbol to show the monatomic ion that the following atoms tend to form (review Lesson 7B if needed). a. Cs

b. S

c. At

d. Al

e. Mg

f. F

2. Write the electron configurations for each ion in Problem 1. 3. Which ion in Problem 1 is isoelectronic with the noble gas xenon? 4.

Silver (atomic number 47) forms a 1+ ion. a. Write the abbreviated electron configuration for Ag+. b. How many unpaired electrons are in Ag+?

5.

Iron (26) forms two cations: Fe2+ and Fe3+. a. Write the abbreviated electron configuration for both ions. b. What is the number of unpaired electrons in each ion?

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c. Which ion lost more than its valence electrons? d. Why might that ion lose more than its valence electrons? 6. Write the electron configuration for the two ions formed by copper. Which ion has a configuration that is not predicted by the standard rules for filling the energy level diagram and forming ions, and why might this ion form?

ANSWERS Practice A 1a. Ni: [Ar] 4s2 3d8 ; 2 unpaired electrons: b. Pd: [Kr] 5s2 4d8

2 unpaired electrons:

4s ĹĻ 5s ĹĻ

4p 5p

3d ĹĻ ĹĻ ĹĻ Ĺ Ĺ 4d ĹĻ ĹĻ ĹĻ Ĺ Ĺ

2. Pd: has an actual configuration of [Kr] 5s0 4d10 This configuration has empty s and full d orbitals. Orbitals at the same energy that are empty, half-filled, or totally filled have lowered potential energy. 3. a. Au: [Xe] 6s2 4f14 5d9 b. Au: [Xe] 6s1 4f14 5d10 This gives half-filled s , filled f , and filled d orbitals. Orbitals at the same energy that are empty, half-filled, or totally filled have special stability. c. The single 6s electron is the one unpaired and the one valence electron.

Practice B 1. a. Cs+

b. S2Ň

2. a. [Xe]

b. [Ne] 3s2 3p6 or [Ar]

d. [Ne]

c. AtŇ

e. [Ne]

d. Al3+

e. Mg2+

f. FŇ

c. [Xe] 6s2 4f14 5d10 6p6 or [Rn]

f. [Ne]

3. Only 1a: Cs+ . The abbreviated configuration for AtŇ can be written using [Xe] to start, but AtŇ is isoelectronic with radon (Rn) (see 2c answer). 4. a. Neutral Ag would have a standard predicted configuration of [Kr] 5s2 4d9 , but if a coinage metal has a neutral configuration of s1 d10 , this results in half-filled s and totally filled d orbitals. The actual configuration for neutral silver is Ag: [Kr] 5s1 4d10 a configuration that has only once valence electron. Since silver’’s most common ion is one plus, this fits the prediction that it only has one valence electron as a neutral atom. To make Ag+, take away the one valence electron. Ag+ = [Kr] 4d10 b. Ag+ = [Kr] 4d10 has no unpaired electrons. All of the orbital sublevels are filled. 5. a. Write the neutral atom configuration first. Fe: [Ar] 4s2 3d6 Fe2+ has lost two its two valence electrons. Fe2+: [Ar] 3d6 Fe3+ has lost one more electron than Fe2+: Fe3+: [Ar] 3d5

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b. Fe2+ has four unpaired electrons. Fe2+: [Ar] 3d6 = 3d ĹĻ Ĺ Fe3+ has five unpaired electrons. Fe3+: [Ar] 3d5 c.

= 3d Ĺ

Ĺ Ĺ

Ĺ

Ĺ Ĺ Ĺ

Ĺ

Fe3+ has lost its valence electrons, plus one more.

d. By losing one extra electron, Fe3+ has gained a 3d5 configuration, which has degenerate d orbitals that are half-filled and therefore have special stability. 6. Copper’’s two ions are copper (I) and copper (II). The neutral copper electron configuration predicted by the standard rules is [Ar] 4s2 3d9 . However, the actual, measured copper electron configuration is [Ar] 4s1 3d10 . In this exceptional configuration, by promoting one s electron to the d orbitals, Cu gains a half-filled s and a totally filled series of d orbitals which have extra stability. In some cases, copper behaves as if it has one valence electron, and in other cases as if it has two. The Cu2+ configuration is [Ar] 3d9 . In this configuration, the neutral copper atom has formed an ion by losing two electrons, and it has no valence electrons. The Cu+ configuration is [Ar] 3d10 . In this exceptional configuration, Cu+ has zero valence electrons plus a totally filled series of d orbitals. Both factors support extra stability. # # # # #

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