Electrochemical Methods for Corrosion Behavior

Electrochemical Methods for Corrosion Behavior Characterization

Dr. Patrik Schmutz Head (a.i.) of “Laboratory for Corrosion and Materials Integrity” EMPA ,Swiss Federal Laboratories for Materials Science and Technology Dübendorf, Switzerland contact: [email protected]

BioTiNet Workshop Ljubljana, 25 October 2011

Outline Introduction - Corrosion and implant failure - Electrochemistry and implant surfaces

Electrochemical potentiodynamic polarisation - Macroscale characterization of Ti alloys - Local electrochemistry by Microcapillary cell techniques

Electrochemical Impedance Spectroscopy - Measurement principle - Characterization of biodegradable Metallic Mg implants

Crevice and galvanic corrosion investigation - Static and dynamic electrochemical setups - Example of Stainless Steel and Co-Cr-Mo alloys

Conclusions

Acknowledgments

Swiss Federal Laboratories for Materials Science and Technology

Laboratory for Corrosion and Materials Integrity

Prof. Peter Uggowitzer

P. Schmutz

•

Physico-chemistry of reactive metal surface

Micro- and nanocapillary electrochemistry

Dr. Alessandra Beni

Dr. Thomas Suter

• Dr. Giancarlo Pigozzi • Dr. Magdalena Pawelkiewicz • • • •

Dr. Jörn Lübben Dr. Emanuele Cardilli Dr. Ngoc Quach-Vu Noemie Ott

• Marianne Berg

• Dr. James DeRose • Dr. Olga Guseva • Mathias Breimesser • Aurelien Tournier

Corrosion management Dr. Markus faller • Dr. Martin Tuschchmid • Ronny Lay • Nikola Gojkovic • René Werner • Urs Gfeller

Michael Schinhammer

Ti alloys - Corrosion resistant

- Other problems related to fatigue or fretting

Choice of testing solution chemistry

Stainless Steel Co – Cr based alloys

Critical

- Pitting corrosion - Crevice corrosion - Galvanic corrosion

Mg alloys In - Vitro testing of corrosion processes

- Biodegradable

Decreasing dependence on testing media P. Schmutz et al., Interface, 17(2), 35-40 (2008)

Increasing corrosion resistance

Less relevant

Example of corrosion related implant failure Ti6Al4V pin implanted in bone (failure after 6 months due to corrosion - fatigue) Hip joints: DLC coating/PE (delamination in vivo, Täger Group) Cook S.D., et al., The in vivo performances of 250 internal fixation devices: a follow-up study. Biomaterial, 1987,8; p. 177 Crevice corrosion:

Cl

Metal

- 90 % of the plates and screws (26 months average)

O2

Me++

Cl -

Cl Me++

-

Metal

Me++

Me++ + H2O → Me(OH)+ + H+

-

O2 Me++

Cl -

Accelerated tests and corrosion ?

In-vivo evidence of corrosion

Materials development and lifetime prediction

Requires faster Feedback Years !!! Ideally weeks/ month °Accelerate the corrosion process by using more agg ressive media is an alternative but not always possible °Electrochemical methods are a good alternative - Very small currents can be measured - It allows earlier detection of on-going degradation processes - Corrosion rates are directly linked to electrical charge flow - There is a very broad range of different information can be gained

Surface processes and electrochemistry on implants SBF without buffer SBF

4

80

3 40 2

20

phase angle

-2

Oxidation and Corrosion

log Z [Ω .cm ]

60

0 1 -2

-1

0

1

2

3

4

5

6

-20

log ω

Macroscale methods: - Open Circuit Potential

Electrochemical Impedance Spectroscopy (EIS)

- Potentiodynamic polarization

Micro- and Nanocapillaries:

Dedicated artificial crevice setups:

- Local measurements - Solution analytics

- Galvanic coupling - Mechanical sollication

Electrochemical surface modifications: - Anodizing - Electropolishing

Thick anodic oxide on Mg

electrolyte bridge (SCE)

platinum wire

Principle of microcapillary cell

holder

Full local electrochemical control for heterogeneous materials characterization

Silicone sealing rubber sample d = 300 nm - 1000 µm

Setup designed by Dr. Thomas Suter at the Institute for Material Chemistry and Corrosion, ETH Zurich.

Localized corrosion characterization Electrochemical polarization measurements 10

3

Current density [µA/cm

2

]

1 M NaCl

SEM before

MnS interface bulk

12 µm

10 2

10

MnS

interface

10

-2

10

-3

10

-4

10

-5

1

bulk

10 0

Pitting 10

10

Current [nA]

Stainless Steel : 18Cr/10Ni

-1

d area = 2.5 µm

-2

-500

0

500

10 -6

1000

Potential [mV] (SCE)

Stainless Steel implants • Plastically deformed and scratched areas are very susceptible to localized corrosion

Ti alloys and electrochemical Polarization (b)

International standard ISO 10271:2001 (Dental Implants)

1.E-05 Log(i) (A /cm ^2)

Lactic acid solution (pH 2.2) 5.85 g/l NaCl + 10 g/l C3H6O3

1.E-04

1.E-06 1.E-07 1.E-08 Ti Grade4 SLA Ti Grade4 SL

1.E-09 1.E-10 -0.5

0

0.5

1

1.5

Potential vs. SCE (V)

Ti grade 4 + transfer piece: Ti6Al7Nb

(b) 1.E-04

Ti and Ti alloys

detected by ICP-MS

L o g (i) (A /cm ^2)

• No corrosive attack under static conditions • Some ionic release

1.E-05 1.E-06 1.E-07 1.E-08 Ti6Al4V SLA

1.E-09

Ti6Al4V SL 1.E-10 -0.5

0

0.5 Potential vs. SCE (V)

1

1.5

EIS: Electrochemical Impedance Spectroscopy Simple model

Measurement at corrosion potential Voltage perturbation (10 mV) is applied

- for electrochemical Interface

Rp

Amplitude

- The current response in function of frequency is measured

Rs

E

C

I Rs : Rp :

Ohm’s law gives a simple relation

C:

solution resistance polarization resistance of the surface capacitance of the surface

U=I*R When AC signal are applied, the relation is

For Mg: Rp= 1000 Ohm/cm2

Eac = Iac * Z

Corrosion rate ~ 220 µm/year

Z: impedance

EIS: data representation Nyquist plot

-Z ’’

Imaginary vs. Real component

Z0 Φ Φ

Z’

10 5 10 4

Rp -60

10 3

Time -40

Rs

10 2 10 1 10 -1

Phase (deg)

Impedance (Ohm)

-80

Bode plot

-20

10 0

10 1 10 2 10 3 Frequency (Hz)

10 4

0 10 5

12

- Frequency dependent representation

Mg alloys as degradable implants •

Magnesium is not only biocompatible... It is an important element in hundreds of metabolic processes. Suggested daily ratio: 350 mg/day

•

Mg-Y-Re alloys are preferred to of AZ91/AZ71.

•

A defined degradation sequence during the first 3-6 months is aimed at

Osteosynthesis

Cardiovascular application

pH of blood

Stents: weight:4mg

Pins

Experimental strategy : alloys and solutions •

•

3 alloys with systematic variation of Y, Zn for screening experiments Alloy

Mg

Y

RE

Zr

WE43

Bal.

4.0

3.5

0.5

Alloy

Mg

Zn

Y

Ca

Mn

WZ21

Bal.

0.9

1.7

0.25

0.15

ZW21

Bal.

2.0

0.8

0.25

0.15

Detailed description of WE43 dissolution

In vivo study: very complex media

In-vitro SBF

Solutions considered: •

SBF 27 as base (concentration in mmol/l) 100.0 NaCl, 4.0 KCl, 27.0 NaHCO3, 1.0 MgSO4 * 7H2O, 2.5 CaCl2 * 2H2O, 1.0 KH2PO4, TRIS Buffer (pH 7.4)

•

Matrix of solutions with combination of ionic species

model solution matrix for corrosion mechanisms

EIS: a kind of spectroscopic method Immediate immersion of WE43 in SBF 27 with and without buffer agent SBF without buffer SBF

4

Frequency resolved electrochemical impedance measurements allows to characterize reaction mechanisms

80

3 40 2

20

phase angle

-2

log Z [Ω.cm ]

60

increased pH

0 1 -2

-1

0

1

2

3

4

5

6

-20

pH 7.4

log ω

localized attack - fast process

• Distinction between uniform or localized corrosion • Double layer / surface oxide dielectric properties • Diffusion and adsorption processes can be monitored at low frequency

Uniform corrosion - slower

Reaction rates

Hydroxide products growth and redeposition Direct Charge transfer

WE43 in100 mM NaCl (buffered)

Porous corrosion products

-Z ’’

Mg Alloy

-Z ’’

Inductive effects (3) related to ionic adsorption from solution

(1)

1

(2)

2

Z’ 3

• Adsorption and Integration of ionic species (inductive effects) can be distinguished from purely growth of hydroxides as a function of time Degradation properties of Mg alloys

16

Nature of corrosion products: from ZW21 to WE43 NaCl, Tris

Transition from porous non protecting to more compact corrosion products

Full SBF WE43 3000

Important influence of Yttrium

WZ21 1000 ZW, WZ

WE

No significant changes in the nature of the corrosion products

ZW21 220

EIS and porous oxides characterization Osteosynthesis application: Thick porous Mg-hydroxides

Electrochemical Impedance Spectroscopy 8

Intact coating

7

Time dependant

log(Z)

6

0h 2h 10 h

5

4 3 through pores Solution contact to metal 2 -2

-1

0

1

2

3

4

5

6

Defective coating model (applicable to other coatings like DLC) • % of open pores can be determined • Initial stage of degradation can be followed as function of time

Corrosion rate

log(f)

Inert

Oxide

Alloy

Polymer monolayer

T1 T2 T3 Implantation time

Material combination in implant fixation Screw: SS, CCM or TiAlNb

Corrosion of metallic implant materials Stainless steel (SS) is very susceptible to crevice corrosion problems

Crevice Corrosion SS Plate

Cobalt Chromium Molybdenum (CCM) is more corrosion resistant but can release “toxic” ionic species when depassivated FDA concern issued February 2011 Titanium Aluminum Niobium alloys show very stable passivation but are than prone to fatigue-corrosion problems, inducing rapid breaking of the implant. Besides, the intrinsic corrosion problems, dissimilar materials will add the problem of galvanic coupling

Crevice corrosion and galvanic coupling Crevice conditions

Low migration of OH- ions increase of H+ in the crevice

Dissimilar materials

Mechanical damage active surface in the crevice

Differential aeration Damaged surface

in sta bil ity film Pa ss ive

ge ma da

pH decreases in crevice increases

Potential difference between crevice and external surface increases

c cli Cy

Cl-

Crevice corrosion

ity bil sta film

Galvanic corrosion

ive ss Pa

Potential difference between crevice and external surface

Repassivation

Investigation procedure is divided into: Passive layer instability, active surface in the crevice

- Static tests - Dynamic tests

Nanoscale crevices at coating interface

DLC-Si Si TiAlV 101 patients DLC/PE 101 patients Al2O3/PE 8.5 year follow-up 50% of DLC/PE failed

FIB cuts: It seems that the first 50 nm above the TiAlV are more or less totally corroded away (not a crack growth) Si interlayer is very susceptible to crevice corrosion in-vivo

Crevice corrosion and galvanic coupling Aeration cell:

All the potential and the currents flowing between electrodes can be measured

stabilize the anodic reaction in the crevice ( < 100 µm) ee-

RE

e-

O2

WE1

I1

I3

I2

Differential aeration

WE2 Cathode ½ O 2 + H2O + 2e - = 2OH

-

Ch1

Ch2

Ch3

Anode Me

Me2+ + 2e-

Me2+ + 2H2O

Me(OH)2 + 2H+

pH

Additional cathode

Additional cathode

Additional passive panels to increase differential aeration

Crevice

Passive or grinded sample in the crevice

Electrochemical potentials of CCM and SS Stainless Steel: Cr 17% - Ni 13% - Mo 2.5% - Mn 2% - Fe Bal CCM:

Co 66% - Cr 28% - Mo 6%

9 g/l NaCl, 0.4 g/l KCl, 0.5g/l CaCl2, 0.2g/l NaHCO3

• There is a risk of galvanic incompatibility between SS and CCM especially in case of damaged surfaces

Influence of pH on SS surfaces in crevice Lactic acid solution Ringer’s solution

• Crevice corrosion has been monitored in lactic acid condition and a significant current measured for the coupling SS-SS • It takes 8 days for localized corrosion to take place and then the current is progressively increasing • In Ringer’s solution, the environment is too mild to initiate an attack in a reasonable time

SS – CCM surfaces in crevices Galvanic current densities Lactic acid solution 8.00E-07

Current density (A/cm^2)

7.00E-07 6.00E-07 5.00E-07

SS(E) Panel

4.00E-07

Grinded SS Crevice

3.00E-07 Grinded CCM Crevice

2.00E-07 CCM(C) Panel

1.00E-07 0.00E+00 -1.00E-07 0

2

4

6

8

10

12

14

16

18

Time (day)

• CCM fully repassivates very fast at low pH (dominating influence of chromium) • SS is unable to repassivate in crevice conditions • The introduction of CCM in the combination SS-SS increase the risk of crevice corrosion for the steel

In vivo degradation of CoCrMo hip implants Study under dynamic conditions: According to ASTM-F75-92 Total Hip Replacement (THR) in 12 sheeps; Euthanasia after 8.5 months - S. Virtanen, A. Hogson (ETHZ) - B. Von Rechenberg, Tierspital Zürich - S. Mischler (EPFL)

CCM (66% / 28% / 6%) - Clinical Analysis - Corrosion - Wear

Dissolution processes studied by ICP-MS Characterization methods Static immersion or Online Microcapillary flow system coupled to ICP-MS Spectrometer

CCM (66% / 28% / 6%) Extremely high dissolved ions concentration is found in the tissues next to the implant when micro-motion is present !

Summary and conclusions Macro- and microelectrochemical polarization allow to characterize the intrinsic corrosion resistance of materials in aggressive media. The method is ideal in relation with materials development (structure, defects) Electrochemical Impedance Spectroscopy is the preferred method for a detailed investigation of complex corrosion processes at the OCP. The frequency dependent “spectroscopic information allow to track different corrosion processes (localized, uniform) occurring in parallel on surfaces and coatings Electrochemical crevice and galvanic coupling setups are necessary to simulate the aggressive local chemistry that is responsible for most of the implant failures Dynamic characterization in crevice and galvanic conditions will be the most relevant electrochemical tests in the case of Ti alloys that are highly corrosion resistant in static conditions (not shown in the webversion) Leaching of metallic ions that can be investigated by ICP methods is a corrosion related aspect that should not be neglected