Chapter 20: The Atmosphere, Climate and Global Warming - MSALVES

Fundamental Global Warming Questions. ▫ Weather and Climate. ▫ The Origin of the Global Warming Issue. ▫ The Atmosphere. ▫ How We ...

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Chapter 20: The Atmosphere, Climate and Global Warming

Overview n  n  n  n  n  n  n  n  n  n  n  n  n  n 

Fundamental Global Warming Questions Weather and Climate The Origin of the Global Warming Issue The Atmosphere How We Study Climate The Greenhouse Effect The Major Greenhouse Gases Climate Change and Feedback Loops Causes of Climate Change The Oceans and Climate Change Forecasting Climate Change Potential Rates of Global Climate Change Potential Environmental, Ecological and Human Effects of Global Warming Adjusting to Potential Global Warming

Fundamental Questions About Global Warming n 

Concern arises from two pieces of evidence: n 

Increase in average surface temperature of the Earth from 1860 to the present n  0.2˚C

n 

per decade since 1960

Increase in carbon dioxide concentrations in the atmosphere n  Measured

Keeling

on Mauna Loa in Hawaii by Charles

Fundamental Questions About Global Warming n 

n 

n  n  n  n 

n 

What is the origin of rapid warming in the geologic record? Is the present rapid warming unprecedented or at least so rare that many living things will not be able to respond successfully to it? To what extent, have people caused it? What are likely to be the effects on people? What are likely to be the effects on all life on Earth? How can we make forecasts about it and other kinds of climate change? What can we do to minimize potential negative effects?

Weather and Climate n 

Weather n 

what’s happening now in the atmosphere near the earth’s surface n  Temperature,

pressure, cloudiness, precipitation, winds

n 

Climate is the average weather Usually refers to long periods of time n  Classified mainly by latitude and wet/dry n 

The Climate is Always Changing n 

Climate has warmed and cooled may times in Earth’s history Times of high temp involve relatively ice free periods n  Times of low temp involve glacial events n 

The Origins of the Global Warming Issue n 

Relationship between chemistry of planet’s atmosphere and planet’s surface temperature Certain gases trap heat energy and warm the planet n  Since this idea was first introduce has stirred controversy n 

The Atmosphere n 

Thin layer of gases that envelops Earth n 

n 

Comprised of n  n  n  n  n  n 

n 

Held near the surface by gravitation and pushed upward by thermal energy. Nitrogen (78%) Oxygen (21%) Argon (0.9%) Carbon dioxide (0.03%) Water vapor Trace amounts of other gases/pollutants

Dynamic system

Structure of the Atmosphere n 

Made up of several vertical layers n 

Troposphere - bottom layer n  Where

weather occurs n  Temperature decrease with elevation n  At the top is tropopause - acts as a lid n 

Stratosphere - above the troposphere n  Stratospheric

ozone layer just above the

tropopause n  Protects again UV radiation

Atmospheric Processes n 

Processes generally defined by pressure, temperature, and water vapor content n 

Pressure is force per unit area n  Caused

by the weight of overlying atmospheric gases on those below n  Decreases with altitude n  Low pressure systems usually bring clouds n  High pressure systems usually bring clear skies

Atmospheric Processes n 

Temperature is the relative hotness or coldness of materials n  Measure

n 

of thermal energy

Water vapor content is how much water is in the gaseous form n  Varies

from 1% to 4%

Atmospheric Processes n 

Atmosphere moves due to Earth’s rotation n  Differential heating n 

n 

Produces global patterns of prevailing winds and latitudinal belts of high and low pressure

What Makes the Earth Warm n 

n 

Almost all the energy from the sun Sunlight comes in a wide range of electromagnetic radiation n 

n 

Long to short wavelengths Most of the radiation that reaches the Earth is in the infrared and visible wavelengths

What Makes the Earth Warm n 

Under typical conditions Earth’s atmosphere: Reflects ~30% of the electromagnetic energy that comes in from the sun n  absorbs ~25% n  The remaining ~45% gets to the surface n 

n  Radiates

space

back to the atmosphere or into outer

How We Study Climate n 

Instrumental Records Climate measurements began in 1860s n  Data from pre 19th century is n 

n  Estimates n  Extrapolated n  Interpolated

n 

We have very accurate data since 1960 n  Improved

instrumentation

How We Study Climate n 

Historical Records n 

Go back a few centuries

n 

Mostly qualitative n 

n 

Books, newspapers, journal articles, personal journals, ships’ logs, travelers’ diaries, and farmers’ logs

Paleoproxy records n 

Proxy data- not strictly climatic, but provides insight into climate n 

Tree rings, sediments, ice cores, fossil pollen, corals, and carbon-14 (14C)

Proxy Climate Records n 

Ice Cores n 

Polar ice and mountain glaciers have ice records that go back 100s or 1000s of years n  Oldest

n 

is 800,000 years

Ice cores have small bubbles of air n  Can

measure carbon dioxide and methane levels from the time the ice was created

Proxy Climate Records n 

Tree Rings n 

Many trees create one growth ring per year n  Width,

density and ionic composition of the ring are indicative of climate

Proxy Climate Records n 

Sediment Biological material (ex: pollen) is deposited on the land and stored for extended periods in lake, bog, and pond sediments n  Pollen is useful n 

n  Quantity

of pollen is an indicator of relative abundance of each plant species n  Pollen can be dated n  Can be used to construct a climate history

Proxy Climate Record n 

Coral n 

Coral exoskeleton made of calcium carbonate n  Carbonate

contains isotopes of oxygen n  Used to determine temp of water in which the coral grew

Proxy Climate Record n 

Carbon-14 and sun sunspots

The Green House Effect n 

Each gas in the atmosphere has its own absorption spectrum Certain gases are especially strong absorbers in the infrared n  They absorb radiation emitted by the warmed surfaces of the Earth n  They then re-emit this radiation n  This increases the temperature of the earth’s surface n 

The Green House Effect Natural phenomenon n  Major greenhouse gases include n 

Water vapor n  Carbon dioxide n  Methane n  Some oxides of nitrogen n  CFCs n 

Greenhouse Effect n 

n 

n 

n 

No one doubts that the greenhouse effect exists and affects planets The puzzle arises on the Earth about relative importance of greenhouse gases in affecting climate Evidence indicates that carbon dioxide, methane, and temperature rise and fall together Most scientists conclude that greenhouse gases are causing climate change

Positive and Negative Feedbacks The atmosphere and its interactions w/ the ocean and land surfaces experience positive and negative feedbacks n  Negative feedback n 

Warms temps warm air and lead to increased evaporation n  Evaporation leads to more cloud formation which reflects more sunlight which could cool the surface. n 

Positive and Negative Feedbacks n 

Positive feedback Warms temps warm air and lead to increased evaporation but instead of clouds forming remain as water vapor n  Water vapor is a greenhouse gas. The warmer it gets the more water vapor, and the process continues n 

Causes of Climate Change n 

19th century Scientists began to understand that climate changed greatly over long periods n  There were times of continental glaciations n  Evidence - debris at the edges of existing glaciers which looked the same as those deposited at lower elevations n 

n 

Cycles were apparent n 

100,000 year cycles divided into 20,000– 40,000 year periods

Causes of Climate Change n 

Milankovitch Cycles n  n 

n 

Explain why climate changes Earth is like a wobbling top following an elliptical orbit around the sun

Three Cycles 1. 

26,000 year n 

n 

Earth Does not keep its poles at a constant angle in relation to the sun Wobble around the pole makes a complete cycle in 26,000 years

Causes of Climate Change 2. 

41,000 years n 

3. 

The tilt of wobble also varies over a period of 41,000 years

100,000 years n  n 

Elliptical orbit around the sun also changes Sometimes it is a more extreme ellipse; other times it is closer to a circle and this occurs over 100,000 years.

Causes of Climate Change n 

The combination of these lead to periodic changes in the amount of sunlight reaching the Earth n 

n 

Milankovitch showed that these variations correlated with major glacial and interglacial periods

Don’t account for all climate variations

Solar Cycles n 

The Sun Goes Through Cycles Sometimes hotter, sometimes cooler n  Documented by differing amounts of isotopes trapped in glacial ice n 

n 

Variability of solar input of energy explains some of the climatic variability too

Atmospheric Transparency Affects Climate and Weather n 

Transparency of atmosphere to radiation affects the temp of the Earth From the sun coming in n  From the Earth’s surface going out n 

n 

Dust and aerosols absorb light Volcanoes, forest fires and farming put dust into the atmosphere n  Chemical and physical comp of atmosphere can make it warmer or cooler n 

The Ocean’s Effect on Climate Change n 

Water has the highest heat capacity of any compound n 

n 

Large amount of heat energy is stored in oceans

Ocean absorbs dissolved CO2 n 

As CO2 increases in atmosphere it also increases in the oceans

The Ocean’s Effect on Climate Change n 

Climate system driven (in part) by ocean conveyor belt n  n 

A global circulation of ocean waters If the conveyor was shut down, major changes in climate would occur

El Niño and Climate El Niño refers to a specific periodic variation of Pacific Ocean currents n  Under non-El Niño conditions n 

Trade-winds blow west across the tropical Pacific n  Warm surface water pile up in Western Pacific n 

El Niño and Climate n 

During El Niño years Trade winds weaken n  Western moving current weakens or reverses n 

n  As

a result eastern equatorial ocean unusually warm n  High rates of precipitation and flooding in Peru n 

Changes global atmospheric circulation n 

Causes changes in weather in regions that are far removed from tropical Pacific

El Niño and Climate n 

Surface water temperature rise off the South American coast inhibits the upwelling of nutrient-rich cold water from deeper levels Upwelling releases carbon dioxide n  El Niño events reduce the amount of oceanic carbon outgassing n 

Forecasting Climate Change n 

Two ways to forecast the future: n 

n 

Empirical and theoretical

Empirical approach is to go back to the geological idea of uniformitarianism The past is the key to the future n  Has led to the extensive research on climates and atmospheric conditions of the past n 

Predicting the Future of the Climate n 

Problem with Empirical approach n 

Temperature records are recent and not widespread n  Difficult

n 

to extrapolate, interpolate and estimate

Hadley Meteorological Center in Great Britain n  Reconstructing

temp records

Predicting the Future of the Climate Computer simulation n  General Circulation Models (GCM) n 

n 

Based around the atmosphere being divided into rectangular solids n  Each

a few km high and several km N or S n  For each the flux of energy and matter is calculated to each adjacent cell n 

Steady state model - cannot account for randomness

Potential Rates of Global Climate Change n 

Global surface temp has increased 0.2°C/ decade in the past 30 years. Eight warmest years have occurred since 1997 n  Continued warming of 0.2°C /decade is projected. n 

Potential Rates of Global Climate Change n 

By 2030 CO2 concentration in the atmosphere will have doubled from pre-Industrial Revolution concentrations n  Average global temperature will have risen approximately 1° to 2°C n 

n  Even

greater temperature increases at poles n  Polar amplification

Potential Effects of Global Warming n 

Changes in River Flow n 

Melting of glacial ice & reductions in snow cover n  Rainfall

will likely increase, but runoff will be more rapid than if snow slowly melts n  Reservoirs will overflow - more water will flow to the ocean

Potential Effects of Global Warming n 

Rise in Sea Level n 

Since last ice age, sea level has risen 1 ft/ century n 

n 

A major warming could increase sea levels 1.  2. 

n 

Global warming could double this Expansion of liquid water as water warms Melting of ice sheets on land whose waters then flow into the ocean

About half the people on Earth live on or near the coast - vulnerable to flooding

Potential Effects of Global Warming n 

Rise in sea level could: Threatens island nations n  Increase coastal erosion on open beaches and cause property loss. n  Cause landward progression of estuaries and salt marshes n  Lead to lost of coastal wetlands n  Threaten ground water supply in coastal communities n 

Tuvalu, the world’s smallest nation, may succumb to sea level rise

Potential Effects of Global Warming n 

Glaciers and Antarctic Ice Cap n 

n 

Far more glaciers are retreating than advancing worldwide Northern Hemisphere sea ice coverage has declined an average of 10.7% per decade since 1970s

Potential Effects of Global Warming

Potential Effects of Global Warming n 

The central ice cap on Antarctica is growing This is consistent w/ prediction of global climate change models n  As Earth warms, more snow falls on Antarctica n 

n 

The rate of melting of the Greenland ice sheet has doubled since 1998

Potential Effects of Global Warming n 

Changes in Biological Diversity n 

The Intergovernmental Panel on Climate Change (IPCC) report states that 2–20% of species assessed so far are likely to be at increased risk of extinction as global mean temperatures exceed a warming of 2 to 3°C above preindustrial levels.”

n  “approximately

Potential Effects of Global Warming n 

Black guillemots n 

n 

Birds that nest on Cooper Island, Alaska,

The abundance of this species has decreased n 

n 

Recession of sea ice occurred before chicks were mature enough to survive on their own Parent birds feed on Arctic cod found under the sea ice n  n 

n 

Distance from feeding grounds to nest must be <30 km In recent years - 250km to feeding grounds

Lost an important source of food for locals

Potential Effects of Global Warming n 

Agricultural Productivity-globally Likely to increase in some regions and decline in others n  Locations most likely negatively effected n 

n  Mid-latitude

food production n  Lands in the southern part of the N. Hemisphere n 

n 

May become more arid & soil moisture relationships will change

Human Health Effects n 

Difficult to forecast

Adjusting to Potential Global Warming n 

Two types n 

Adapt n  Learn

n 

to live with future global climatic change

Mitigate n  Work

to reduce emissions of greenhouse gases

Adjusting to Potential Global Warming n 

How can carbon dioxide emissions be reduced? Energy planning that relies heavily on energy conservation and efficiency n  Use of alternative energy sources or natural gas n  Use of mass transit n  Greater economic incentives to energyefficient technology n  Higher fuel-economy n 

Adjusting to Potential Global Warming n 

Burning forests to convert land to agriculture n 

n 

n 

Accounts for ~20% of anthropogenic emissions of carbon dioxide Reduce this by minimizing burning and protecting the world’s forests

Reforestation n  n 

Planting more trees Increase biospheric sinks for carbon dioxide

Adjusting to Potential Global Warming n 

Geologic sequestration of carbon is another possible mitigation measure n 

Capture carbon dioxide from power plants and industrial smokestacks n  Compress

the gas and change it to a mixture of both liquid and gas n  Inject it deep underground n 

Have the potential to sequester as much as 1,000 gigatons of carbon

International Agreements to Mitigate Global Warming n 

Two major approaches 1. 

2. 

International agreements in which each nation agrees to some specific limit on emissions Carbon trading

Carbon Trading n 

A nation or nation agrees to a cap of carbon emissions Then corporations and other entities are issued emission permits, allowing a certain quantity of emissions n  These can be traded n  Overall nation does not exceed the cap n 

International Agreements to Mitigate Global Warming n 

1988 n 

n 

First international meeting to discuss limiting greenhouse gases held (Toronto, Canada)

1992 Earth Summit in Rio de Janeiro, Brazil. n  General blueprint for reduction of global emissions suggested n  US thought it would be to costly and no legally binding limits set n 

International Agreements to Mitigate Global Warming n 

1997 n 

n 

n 

Legally binding limits discussed in Kyoto, Japan. US eventually agreed to cut emissions to 7% below 1990 levels (leading scientists recommend cuts 60-80% below) Became a formal treaty in 2006