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Rechargeable Batteries for Specknets

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Nickel Cadmium (Ni-Cd) 1.2V, 400 Cycles. Inexpensive Simple charging ... Ni-Cd. Pd-acid. Smaller. Lighter. Speckled Computing. Theoretical Energy Densities and ... – PowerPoint PPT presentation

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Title: Rechargeable Batteries for Specknets

1
Rechargeable Batteries for Specknets

Allan Paterson
St Andrews Centre for Advanced Materials (STACAM)
University of St Andrews
ajp6_at_st-andrews.ac.uk

2
Plan

Requirements and key power source issues
Types of rechargeable batteries
Li-ion batteries
Commercial options
Sanyo
Thin Film Batteries
New electrode materials
Nano materials
Lithium Manganese Nickel oxides
Future Work

3
Requirements
Autonomous speck with renewable power source

Require Specks to be small
limit to energy storage
Long periods between recharge high
energy density
Powerful supply for comms. sustain high
currents

Secondary batteries

Alternatives
Radioactive Primary Batteries
Efficiency too low. lots of energy stored, cant
get at it.
Capacitors and Thermoelectric Generators
Relatively large devices.
Solar Cells
Still require energy storage when dark / cloudy
Low power

4
Key Issues

Energy densities
Gravimetric (Wh/kg) ? lighter weight
Volumetric (Wh/l) ? smaller size
Power (W)
Potential (V)
Current (I)
Recharge conditions and limits
cell protection
Fabrication of micro-batteries

Optimised Speck battery
Effects available capacity
5
Secondary Batteries

Nickel Cadmium (Ni-Cd)
1.2V, 400 Cycles
Inexpensive - Simple charging
low energy density - Memory effect
high self discharge (20 month)
Toxic
Nickel Metal Hydride (Ni-MH)
1.2V, 600 Cycles
Simple to charge,
High self discharge (30 month)
reduced memory effect - Less-toxic
Silver Zinc (AgZn)
1.5 V, 300 Cycles
Low energy density - Very difficult to recharge
Lithium Ion (Li-ion) based
3.5V, 2000 Cycles
Higher energy density - No memory effect - Low
self discharge
Lower toxicity - More expensive - More complex
charging
Continuous current limited to 1.5C

Energy Densities
Smaller
Thin Film Li / Li-ion
Li-ion
Ni-Cd
Li-polymer
Ni-MH
Lighter
Pd-acid
6
Theoretical Energy Densities and Run Times
Estimated Energy Storage Available For Cubic
Specks

Theoretical based on highest thin film and li-ion
energy densities.
Practical energy available determined by rate at
which you discharge.
Does not include packaging
? 1 1 1 mm cube difficult!

Theoretical
Practical
Packaged
7
Rocking chair Li-ion Battery
e-
e-
-

Li
charge
e-
e-
discharge
Li
LixC6 Graphite
Li conducting electrolyte
LiCoO2

Electrode redox reactions on charge
Cathode oxidation LiCoO2 ? Li1-xCoO2
xLi xe-
Anode reduction xLi xe- C6 ?
LiC6

discharge is the opposite

8
Current Lithium Ion Systems

A - Coin / Button Cells (Li-ion)
LiMnO2 LiPF6 in EC/DEC organic electrolyte
Graphite
Rigid Aluminium packaging
For clock / memory backup PDA type devices
Available now, Sanyo, Varta, Seiko
B - Pouch Cells (Li-Polymer Gel)
LiCoO2 PEO or PVDF LiAsF6 or LiPF6 Graphite
Soft or hard bodied complex form factors
Large rectangular (20 ? 25mm) footprint but thin
(2.5mm)
Zero stack pressure no leaks, safer
Common in Mobile Phone / Notebook / MP3 Players.
C - All Solid State (Thin Film Li-ion)
LiCoO2 LiPON solid electrolyte Li / Sn(O) /
V2O5
Highly crystalline electrodes, no
binder/conductor
Very thin battery (30µm)
on rigid (0.4mm) or flexible (0.1mm) substrate
No solvents/gasses/liquids to degrade or leak -
Safer
Sustain high continuous currents
More tollerant of over charge/discharge ? No cell
protection required

A
B
C
9
Sanyo Coin Cells
Sanyo Micro batteries ?-MnO2 Liquid
electrolyte Li-Al Alloy Model No
ML414 ML421 Voltage 3V 3V Dimensions
4.8 1.4 mm 4.8 2.1mm 555mm Speck
3 cells 2 cells (in parallel) Total Rated
Nominal Capacity 4mAh Max rated
Discharge Current 0.5mA Standard Charge
/ Discahrge Current 0.05mA ? Discharge
time of approx 5 to 6 hours for 1mW drain ?

Electrochemical testing to establish
Sustainable high currents, able to draw 1mW?
Batteries actual capacity and resulting run time?
Rate capability?
Ease of recharge?
Cyclability?

10
Sanyo - Electrochemistry
Recharge Conditions
Cyclability and Rate Capability
Constant Voltage Charge
Constant Voltage Charge
1mW
1mW
2mW
2mW
3mW

At limits of size and max current for this
system

At manufacturers max rated recharge current
time to recharge at least 1week.

11
Sanyo - Summary

Extremely sensitive to recharge conditions
Large depth of discharge significantly reduces
cycle life
1 depth of discharge ? 20,000 cycles
10 depth of discharge ? 1,000 cycles
50 depth of discharge ? 100 cycles
100 depth of discharge ? 30 to 50 cycles
100 depth of discharge - non CC/CV fast
recharge ? 20 cycles
Higher power dramatically reduces run time
1mW ? 6 hrs
2mW ? 2 hrs
3mW ? ¼ hr
Push as hard as can/need destroys the battery
Alternative ? non Lithium Alloy at this size?

12
Thin Film

All-solid-state device
formed by sputtering
Key Li2.9PO3.3N3.6
ceramic electrolyte.
Initial work by John Bates Oak Ridge Micro
Energy Inc.
Main option for specks smaller than 5 5 5 mm
Prepared to make us some 5 5 mm footprint TF
batteries
Requires a design from us generation of mask
set for 4.52 substrate
Main issue is the location and dimensions of the
contact patches
Design rules recommendations from Christina for
wire bonding to produce suitable schematic for
cell fabrication shortly
Conduct electrochemical performance evaluation
and allow subsequent prototype device integration

13
Battery specification

Size 0.3855mm
Mostly packaging
55mm footprint
?4.54.5mm cathode
0.20cm2 ? 40µAh
Fit 13 in parallel
500µAh 0.5mAh total
Sustainable high charge/discharge rates
At a power drain of 1mW then13 cells
gives current density of 130µA/cm2
No significant capacity reduction from IR loss at
room temp.
? Total discharge time of battery stack 2
hours

Anode Current Collector
Cathode Current Collector
Anode Cathode
Electrolyte
14
What for the Future?
Carbon nanotube

Most improvement in energy storage and
performance to be gained from RD of new and
advanced electrodes.
? Materials chemistry challenge.

Advanced Speck electrodes require
Higher capacities ? Advanced Li-Mn-Ni-O
Improved rate capability ? Nanomaterials

Nanomaterials
1 Nanometre 1000millionth of a metre
Simply by making materials small can have a
profound influence on their properties.
Inorganic oxide - Nanotubes and Nanowires.

15
TiO2-B Nano-tubes / wires

Much interest in titanates, e.g. Li4Ti5O12
Safe, low toxicity
Voltage 1.5V, Capacity 160mAhg-1 (0.5 Li
per Ti)
? Hunt for NEW titanates?

TiO2-B Nano-tubes / wires
TiO2-B most open of polymorph of TiO2
High theoretical capacity
Tubes/wires have 1D morphology
Better particle contact ? Higher rate capability

Early reports of TiO2 tubes wrong ?
Na2-xHxTinO2n1xH2O
170?C hydrothermal H exchange, ?400?C
TiO2-B nanowires
High Yield
NaOH H2O TiO2-anatase
Armstrong, Armstrong, Canales, Bruce Angew.
Chem. 43, 2286 (2004)
16
TEM Images
TiO2-B Nanowires
TiO2-B Nanotubes
10nm
G. Armstrong, A. R. Armstrong, J. Canales and P.
G. Bruce Chem. Commun., 2005, 2454
17
TiO2-B Electrode Performance
The 1st Cycle
Rate Capability

Intercalate Li up to Li0.98TiO2. (330mAhg-1) at
low rates, 1.6V
2 that of anatase (150mAhg-1) or Li4Ti5O12
(160mAhg-1)
Excellent capacity retention and reversibility gt
99.9 (wires)
Able to sustain high charge / discharge rates
1st cycle irreversible capacity problem of
conductivity?

18
New composite electrodes

Encase active material in polymer gel
Create porous electrode with all active
material accessible by penetrating electrolyte ?
increased conductivity.

Standard Composite Electrode - Active 75 -
Carbon Super-S 18 - Kynar Binder 7
1 to 2.5V LP30 Electrolyte
Optimised PEO Composite Electrode - Active
60 - Carbon Super-S 25 - PEO 15 -
Electrolyte Plasticizer 20 w/w of dry

Highlights poor e- conductivity
optimised PEO electrode does not address fully
? carbon coating?

19
Lithium Manganese Oxides

Much interest in Mn based intercalation materials
- LiMnO2 and LiMn2O4
Cheap 1 cost of Co - Safe, low toxicity
Potentially much higher capacities
Almost ideal intercalation Electrode
LiMn0.5Ni0.5O2
Mn4 in octahedral sites stabilizes layered
structure
½ Ni for electrochemistry Ni2 ? Ni4 2e-
Manganese materials difficult to synthesise pure
phases
Very sensitive to synthesis conditions effects
electrochemistry
Difficult to make all Ni4 Susceptible to ionic
mixing anti site defects

Li0.44MnO2
20
The Problem with Manganese

Mn3 3d4 (High Spin) Jahn Teller Active

0 Mn3
50 Mn3
100 Mn3
?-MnO2
LiMn2O4
Li2Mn2O4
Undistorted cubic phase
Undistorted cubic phase
Co-operative Jahn-Teller distortion to tetragonal
symmetry

To obtain a high capacity for any Li-Mn-O
compound must be able to intercalate /
deintercalate a large of Li
?1st order Jahn-Teller distortion ? 2 Phase ?
Poor reversibility.

Disproportionation type reaction above 4V
2Mn3(solid) ?Mn4(Solid) Mn2(solution) -
active material dissolution

Li2MnO3 composite to stabilise layered
structure
Potentially large improvement in performance
from xLi2MnO31-xLiMn0.5Ni0.5O2 type
materials Layered notation
(LiLix/(2x)Mn(1x)/(2x)Ni(1-x)/(2x)O2)

21
Li-Mn-Ni-O System

Possibly greatest initial interest
0.3Li2MnO30.7LiMn0.5Ni0.5O2 - when discharged
average Mn OS maintained above 3.5
Large theoretical capacity as Li2MnO3 also
electochem active - Li2MnO3 ? ?MnO2 Li2O (H
exchange)

New composite
xLi2MnO3(1-x)LiMn0.5Ni0.5O2 composite or
LiLix/(2x)Mn(1x)/(2x)Ni(1-x)/(2x)O2
Layered LixMnyO2
LiMn2O4 Spinel
LiCoO2

Potentially much higher capacities with
optimised material 300mAhg-1

Li
(Mn / Ni)O6
22
Synthesis and Powder XRD results

Mixed Hydroxide Co-precipitation
Ni(NO3)2.6H2O Mn(NO3)2.4H2O Precursor

Dripped into LiOH soln. pH11 (3hrs)
Filter Wash
? 180oC 24hrs
? 900oC 10 hrs Then quench to room-temp.
? 80oC 24hrs
? 480oC 12 hrs Then re-grind
LiOH.H2O Grind in acetone
Ni1-xMnx(OH)2
LiLix/(2x)Mn(1x)/(2x)Ni(1-x)/(2x)O2 ?
xLi2MnO3?1-xLiMn0.5Ni0.5O2