Dr. John Busbee, CEO

j.busbee@xerionbattery.com

1.217.377.6888

2

BATTERY NEEDS AND CHALLENGES IN THE AUTOMOTIVE

SPACE

EV Need:

Encreased Range

Faster “Fill-up”

Regenerative Charging

Improved Fire Safety

Longer Automotive Life

Lower Costs

Battery Need:

Higher Energy Density

Fast Charge

Regenerative Charging

Improved Fire Safety

Longer Automotive Life

Lower Costs

Battery Challenge:

Lower Power, Cycle Life

Lithium Plating, Heating

Charge Acceptance

Thermal, Shorting

Cycle Life

Processing, Materials

3

TECHNOLOGY OVERVIEW

Al

Foil

Plastic

Separator

Fast Charging due to Metal Foam

Architecture:1. Li+ moves fast through in liquid through

pores to Silicon surface

2. Silicon is thin, so Li+ moves more quickly to

reaction site in middle of silicon

3. Electron moves fast through metal

scaffold to silicon surface

4. Electron moves quickly through thin silicon

to reaction site

XERION UNIQUE TECHNOLOGIES

RE-ENGINEERING BATTERY ARCHITECTURES

4

5

BATTERY COST REDUCTIONDIRECTPLATETM

Electroplating bath:

made of lower purity raw materials

Electroplating process:

Minutes, not hours

Electroderinsing (in water) &

drying

Electrode fabrication process

• Electroplating

Mass Production

Materials Refinement

• >99.4% Pure Materials

Starting Raw Materials: 80% ~ 95% pure

• Simplified Manufacturing Process

Combines material synthesis and fabrication

• Variety of Substrates Metal Foils

Metal Foams

Carbon Foams and Fibers

Opportunities for New Applications

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Enables High Packing Density

DirectPlateTM

• Direct deposition of active battery

materials on foil

• Up to 250 micron thick

• No binders

• No conductive additives

• Up to ~ 90% volume fraction of active

materials

• Strong adhesion between active

materials and current collectors

LCO electroplated on Al foil

22 um thick, 80% LCO

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- L i th ium Cobalt Oxide

DirectPlateTM

1 um

8

- Real ized v ia DirectP late TM

High Power LCO Cathode

Coin cell-half cell (vs. Li/Li+)

10C charge current

0 2 4 6 8 10 120

20

40

60

80

100

Sta

te o

f C

ha

rge (

%)

Charge Time (min)

LCO, 2.2 mAh/cm2 (Xerion)

LCO, 3.0 mAh/cm2 (Xerion)

LCO, 3.5 mAh/cm2 (Xerion)

9

- LCO cathode Scotch Tape Adhesion Test

DirectPlateTM: Robust Battery Structures

No Delaminated

Material

Delaminated

Material

10

Enables High F lex ibi l i ty

DirectPlateTM

Conventional LCO DirectPlateTM LCO

After rolling 1000 times

Discharge profile after rolling

0.0 0.2 0.4 0.6 0.8 1.0

2.6

2.8

3.0

3.2

3.4

3.6

3.8

4.0

4.2

4.4

Voltage (

V)

Capacity Retention

0 rolls

1000 rolls

0.0 0.2 0.4 0.6 0.8 1.0

2.6

2.8

3.0

3.2

3.4

3.6

3.8

4.0

4.2

4.4

Voltage (

V)

Capacity Retention

0 rolls

100 rolls

500 rolls

DirectPlateTM LCO electrodeConventional LCO electrode

Electrodes rolled at ~ 2.5 mm radius

11

072016_NiCr_wire_rolled_450_2h_1v_100mson_30soff_140cycle.mpr

Ew e vs. Capacity, cycle 1

Capacity/mA.h

1.210.80.60.40.20

Ew

e/V

4.3

4.2

4.1

4

3.9

3.8

3.7

3.6

3.5

3.4

3.3

3.2

3.1

3

100 um

LG Chem’s Cable Batteries

- A new method to make cathode for cable batter ies

DirectPlateTM

1ST cycle of LCO coated wire

LCO coated wire

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- Enhance batter y per formance

StructurePoreTM

DirectPlateTM StructurePoreTM :• High power cathode

• High energy anode

- silicon

- tin

- lithium

• Scale-up

XABC SILICON STRUCTURE PORE CONCEPT

Structure pore Ni foam Fast silicon electrodeposition

Charge cycle and

associated expansion

Pore space accommodates silicon expansion

Discharge cycle and

associated contraction

Returns nearly to original state

XABC SILICON STRUCTURE PORE CONCEPT

Structure pore Ni foam Fast silicon electrodeposition

Charge cycle and

associated expansion

Pore space accommodates silicon expansion

Discharge cycle and

associated contraction

Returns nearly to original state

XERION TECHNOLOGY PRODUCES HIGH ENERGY

BATTERIES USING POROUS SILICON

Si coating

Metallic

3D scaffold

~100 – 500 nm coating

- Fast charging

- Fast, Direct plating

- Conformal deposition of silicon on 3D

scaffold

- No need for copper foil

- No slurry processing needed

- Silicon much cheaper than graphite

- Good cycle life

XABC FAST CHARGE SILICON HALF CELL

SIGNIFICANTLY OUTPERFORMS ‘HIGH -POWER’

COMMERCIAL GRAPHITE ELECTRODE

0 10 20 30 40

0

20

40

60

80

100

Commercial Graphite

2.0 mAh/cm2

51 m

400 mAh/cm3

XABC Si

2.6 mAh/cm2

3m

600 mAh/cm3

SO

C (

%)

Time (min)

5C Fast charge

GOOD HALF CELL CYCLE LIFE IS ENABLED BY INTERNAL

POROSITY, NANOSTRUCTURED MORPHOLOGY AND

OPTIMIZED SURFACE AREASilicon electrode before cycling Silicon electrode after cycling

0 25 50 75 100 1250.0

0.5

1.0

1.5

2.0

2.5

3.0

Capacity (

mA

h/c

m2)

Cycle Number

• High silicon loading

• Minimal capacity degradation

0.05 - 1V vs. Li/Li+ 23°C, Coin

10 µm

Silicon on nickel scaffold Silicon on nickel scaffold

10 µmMinimal degradation

leads to good cycle life

PROPRIETARY © 2016 Xerion Advanced Battery Corp. All Rights Reserved

Minimal

Change

3-LAYER FAST CHARGE SILICON PROTOTYPE CELLS

Anode: Si010218-3_1 (~3.695 mAh/cm2/side, 144 µm thick)

Cathode: NMC622, 96%, BIC (~3.45 mAh/cm2)

Area: 5.75 x 5.6 cm2

Packaging: 71 µm laminate

Separator: 12 µm

Capacity: 173.3 mAh

Average Voltage at 1C charge: 3.334 V

CHARGE RATE ANALYSIS SHOWS THAT SI

BASED FULL CELLS CAN BE CHARGED AT

FAST RATE WITHOUT VISIBLE SIGNS OF LI

PLATING

High Power

Considerable Li plating on commercial graphite anode with fast charging

Si 5C

No Li

Si 2C

No Li

Gra. 5C

Li plating

Gra. 2C

Li plating

4.2 – 2.5 V 23°C, Coin

FULL CELL PROTOTYPES

EXPECTED ENERGY / POWER DENSITY

Present Optimized

Energy (Wh/l) @ 1C 700 800

Energy (Wh/kg) @ 1C 300 350

Power (Wh/l), RT, 50%

SOC, 5C, 10S3700 4000

Power (Wh/kg), RT,

50% SOC, 5C, 10S1600 1775

High Power Flexible

Micro-batteryVery High Energy

Tunable 3-D

Structure

Direct

Electrofabrication

Low Cost*

Highly Scalable

NOVEL MANUFACTURING PROCESSCAN BE QUICKLY CUSTOMIZED WITH MINIMAL CHANGE IN

TOOLING

Markets:

All-Electric Vehicles

Grid-Scale Storage

Cell Phones

Markets:

Wearables

Internet of Things

Medical

Markets:

Embedded Electronics

Bluetooth/RFID devices

Highly structured, fast charge 3000 flex cycles, no degradation

Fab-compatible, high energy

Markets:Hybrid Vehicles

Drones

Power ToolsNational Defense

Thick electrodes, no binder

*Because Electrodeposition (Electroplating) is also a refinement technique, it offers high potential to reduce costs and open new

sources for less pure lithium materials

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