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Song Xu, Ph.D.

Sr. Application Scientist

Keysight Technologies

In-situ Study of Lithium Battery with Electrochemistry/ AFM

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Page Why are we interested in battery research?

The Original Question of all: Why

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Lithium Battery

Page SEM Observation of Solid-Electrolyte Interphase

Elsevier , “Comparative study of the solid electrolyte interphase on graphite in full Li-ion battery cells using X-ray photoelectron

spectroscopy, secondary ion mass spectrometry, and electron microscopy”

Jung Tae Lee a, Naoki Nitta a, James Benson a, Alexandre Magasinski a,

Thomas F. Fuller b, Gleb Yushin a,*

Lithium Battery

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AFM / STM In Liquid Imaging is used to observe the formation of SEI

in-situ and in real time

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Changing potential while scanning

Fixed potential

Basics of Electrochemistry AFM/STM: the in-situ and the resolution

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EC Bulk Cu Crystal Deposition

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Reference electrode

Electrolyte

Combning AFM/STM with the potentialstate to form EC-AFM/STM

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Basics of Electrochemistry AFM/STM: the sample cell

reference electrode

(no connection with

other electrodes)

counter electrode

(no connection with

other electrodes)

working electrode (in contact with Au)

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Basics of Electrochemistry AFM/STM: Design of glove box

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Basics of Electrochemistry AFM/STM: Environmental control with professional glove box

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DALHOUSIE

University

luc@dahn.phys.dal.ca

www.physics.dal.ca/~dahn

The problems of AFM inside a professional glove box: noise and

vibration isolation

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Solution to the problem: miniature vibration isolation

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Solution to the problem: miniature vibration isolation

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Solution to the problem: miniature vibration isolation

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reference electrode

(no connection with

other electrodes)

counter electrode

(no connection with

other electrodes)

working electrode (in contact with Au)

The problems of AFM inside a professional glove box: Electrical

Chemistry Cell

Problems

•Small parts

•Leak

•evaporation

•Corrosion

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Electrodes

Reference electrode: Mostly Ag, Cu ok for Cu deposition

experiment

Counter electrode: Mostly Pt, Cu ok for Cu deposition experiment.

The long loop is for the large current in the big

AFM cell. STM counter electrode doesn’t need the

loop.

The problems of AFM inside a professional glove box: Small parts of

Electrical Chemistry Cell

Page DALHOUSIE

University

luc@dahn.phys.dal.ca

www.physics.dal.ca/~dahn

Electrode Lithium

Electrode

The problems of AFM inside a professional glove box: Small parts of

Electrical Chemistry Cell

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Customizable in

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The problems of AFM inside a professional glove box: and handling

and the corrosion

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Solution to the problems of AFM inside a professional glove box: EC

cell made for easy to handle

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Solution to the problems of AFM inside a professional glove box: EC

cell made for easy to handle

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell—the first circle

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell—the first circle

AFM images of HOPG

surface scanned at a

synchronous discharge

voltage range of

a) 3.0 e 2.95 V;

b) b) 1.7 e 1.65 V;

c) c) 1.0 e 0.95 V;

d) d) 0.5 e 0.45 V;

e) e) 0.1 e 0.05 V.

Scan area 25 mm2.

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In-situ observation of bottom SEI on HOPG electrode surface during

charging circle of a Li ion battery cell—the first circle

AFM images of bottom SEI layer:

a) pristine HOPG;

b) b) discharge to 1.7 V;

c) c) discharge to 0.5 V;

d) d) discharge to 0.02 V.

Scan area 25 mm2.

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell—the first circle

Schematic of SEI evolutions during the first discharge process.

a) The solvent decomposition product (purple dots) deposits at the surface of the graphite;

b) the solvated lithium ions (gray dots) pass through the particle layer and intercalated into the graphite layer (black lines);

c) solvent decomposition products accumulate at the surface when the

lithium intercalation takes places;

d) the displacement of the graphite layer caused by the lithium intercalation pushes the top particle layer off the HOPG surface;

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell—the delamination of the first SEI layer

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell- the bottom SEI

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell- the bottom SEI

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In-situ observation of SEI on HOPG electrode surface during charging

circle of a Li ion battery cell- the bottom SEI is a soft layer

Center framed area scanned at higher force (10nN)

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On going work

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On-going work: mechanical properties measurement of mechanical

properties of SEI of Li battery cell

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Future work: Better solution to the problems of AFM inside a

professional glove box: EC cell made for easy to handle and resist to

corrosion

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Future work: EC AFM cell for Litihium Cell with heating and cooling

option

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Future work: EC AFM cell for Litihium Cell with oxygen feed to a porous

sample electrode

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Some small inventions: Sample transfer holder from glove box to SEM /

XPS

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Conclusion:

We observed Litihum battery SEI formation in-situ in real time

future:

Mechanical property measurement of SEI on HOPG electrode surface

during charging circle of a Li ion battery cell

Temperature based study: heating and cooling