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Solid State Thin Film Batteries: Market Shares, Strategies, and Forecasts, Worldwide, Nanotechnology, 2015 to 2021

Published: Apr-2015 | Format: PDF | Winter Green Research | Number of pages: 553 | Code: MRS - 13623

WinterGreen Research announces that it has published a new study Solid State Thin Film Batteries:  Market Shares, Strategy, and Forecasts, Worldwide, 2015 to 2021.  The 2015 study has 329 pages, 110 tables and figures.  Solid State Thin Film Batteries offer quality for powering energy harvesting with precisely the right component.

The quality of energy storage is better with solid state thin film batteries.   Solid State Thin Film Batteries A comparison of battery performance for various rechargeable batteries is a compelling illustration of the value of thin film batteries.  Data for thin film batteries using very thin substrates illustrate the longer cycle life that can be achieved.  Applications include power bridging, permanent power, and wireless sensor networks.

Thin film battery market driving forces include creating business inflection by delivering technology that supports entirely new capabilities.  Sensor networks are creating demand for thin film solid state devices.  Vendors doubled revenue and almost tripled production volume from first quarter.  Multiple customers are moving into production with innovative products after successful trials.  

A strong business pipeline has emerged with customer activity in all target markets.    The market focus is shifting from ramping capacity to driving manufacturing efficiencies and achieving margin improvement, indicating increasing market maturity.

Smarter computing is part of an IT opportunity, brought by the availability of many, many devices that measure what is going on in the world.  These devices are made possible by the availability of small, inexpensive, reliable batteries that provide battery backup on the printed circuit board.  Smarter computing is related to achieving a more instrumented, interconnected and intelligent infrastructure.

Software and onboard storage are significant aspects of making the networks more intelligent.  The need to capture and analyze increasing amounts of data, deliver results to more users, and respond faster across all devices, without a corresponding increase in budget is a function of better management and better systems.  Back up power is part of the picture.

Key application areas for solid stare batteries are:

  •  Power bridging
  • Permanent power
  •  Wireless sensors

    
As energy harvesting and wireless sensor networks evolve, the solid state batteries provide an uninterruptable, stable power source that lasts as long as the electronics with which it is packaged.  In some cases, changing batteries is not feasible, ant these applications are illustrative of those kinds of instances.  

According to Susan Eustis, the lead author of the team that created the study, “Solid state electronics brings the same advantages to batteries as it has brought to all other industry segments it touches.  Printed circuit board manufacturers are finding that they can achieve a rapid return on investment from substantially decreasing the energy costs associated with using storage by wave soldering the storage onto the boards during the manufacturing process.”

Solid state thin film battery markets at $9 million in 2014 are forecast to reach $1.3 billion by 2021.   Rapid growth toward the end of the forecast period is anticipated as technology improves the cost structure of the manufacturing.
 
WinterGreen Research is positioned to help customers face challenges that define the modern enterprises. The increasingly global nature of science, technology and engineering is a reflection of the implementation of the globally integrated enterprise.  Customers trust WinterGreen Research to work alongside them to ensure the success of the participation in a particular market segment.

WinterGreen Research supports various market segment programs; provides trusted technical services to the marketing departments.  It carries out accurate market share and forecast analysis services for a range of commercial and government customers globally.  These are all vital market research support solutions requiring trust and integrity.

WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software.  The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, Bloomberg, electronics.ca, and Thompson Financial.

Table of Cotents

Solid State Thin Film Battery Executive Summary
Advantages of Solid State Batteries
Solid State Thin Film Battery Market Driving Forces
Improvements In Wireless Sensor Technologies Have Opened
Up New Solid State Battery Markets
Nanotechnology and Solid State Batteries

1. Solid State Thin Film Battery Market Description and Market Dynamics
1.1 World Economy Undergoing A Transformation
1.1.1 Global Economic Conditions:
1.1.2 Global Economy Becomes Steadily More Sluggish
1.1.3 Global Economic Conditions Impact Markets
1.2 Smarter Computing Depends on Solid State Thin Film Batteries
1.2.1 Intelligent Systems: The Next Era of IT Leverages Solid State Thin Film Batteries
1.2.2 Cloud and Virtualization from IBM WebSphere
1.3 Solid State Thin Film Battery Target Markets
1.3.1 Permanent Power for Wireless Sensors
1.4 Principal Features Used To Compare Rechargeable Batteries
1.5 Integrated Energy Storage
1.5.1 Pervasive Power
1.6 Reducing Grid Energy Losses

2. Solid State Thin Film Battery Market Shares and Market Forecasts
2.1 Advantages of Solid State Batteries
2.1.1 Solid State Thin Film Battery Market Driving Forces
2.1.2 Improvements In Wireless Sensor Technologies Have Opened Up New Solid State Battery Markets
2.1.3 Nanotechnology and Solid State Batteries
2.2 Solid State Battery Market Shares
2.2.1 Cymbet
2.2.2 Cymbet EnerChip
2.2.3 Infinite Power Solutions (IPS) THINERGY
2.2.4 Solid State Thin Film Battery Market Leader Analysis
2.3 Solid State Thin-Film Battery (TFB) Market Forecasts
2.3.1 Solid State Battery Market Forecast Analysis
2.3.2 IBM Smarter Planet
2.4 Applications for Solid State Thin Film Battery Battery
2.4.1 Cymbet Millimeter Scale Applications
2.4.2 Cymbet Ultra Low Power Management Applications
2.4.3 Solid State Thin Film Battery Market Segment Analysis
2.4.4 Embedded Systems Need Solid State Batteries
2.4.5 Energy Harvesting
2.4.6 Near Field Communication (NFC) Transactions
2.5 Battery Market
2.6 Wireless Sensor Market
2.6.1 Benefits Of Energy Harvesting
2.6.2 Solid-State Battery Advantages
2.6.3 Comparison of Battery Performances
2.7 Solid State Thin Film Battery Price and Installed Base Analysis
2.8 Solid State Thin Film Battery Regional Analysis

3. Solid State Thin Film Battery Product Description
3.1 Cymbet Solid State Batteries (SSB)
3.1.1 Cymbet Solid State Batteries (SSB) Eco-Friendly Features
3.1.2 Cymbet EnerChip Bare Die Solid State Batteries are Verified Non-cytotoxic
3.1.3 Cymbet EnerChip Solid State Battery Fabrication
3.1.4 Cymbet Embedded Energy Concepts For Micro- Power Chip Design
3.1.5 Cymbet Embedded Energy Silicon Substrate Architecture
3.1.6 Cymbet Pervasive Power Architecture
3.1.7 Cymbet Cross Power Grid Similarities and Point of Load Power Management
3.1.8 Cymbet Solid State Rechargeable Energy Storage Devices
3.1.9 Cymbet Integrated Energy Storage for Point of Load Power Delivery
3.1.10 Cymbet Energy Processors and Solid State Batteries
3.1.11 Cymbet Millimeter Scale
3.1.12 Cymbet Millimeter Scale Energy Harvesting EH Powered Sensors
3.1.13 Cymbet Building Millimeter Scale EH-based Computers
3.1.14 Cymbet Designing and Deploying Millimeter Scale Sensors
3.1.15 Cymbet Permanent Power Using Solid State Rechargeable Batteries
3.1.16 Cymbet Ultra Low Power Management
3.1.17 Cymbet EH Wireless Sensor Components
3.2 Infinite Power Solutions
3.2.1 Infinite Power Solutions THINERGY MECs from IPS
3.2.2 Infinite Power Solutions (IPS) THINERGY MEC225 Device:
3.2.3 Infinite Power Solutions (IPS) THINERGY MEC220
3.2.4 Infinite Power Solutions (IPS) THINERGY MEC201
3.2.5 Infinite Power Solutions (IPS) Thinergy® MEC202
3.2.6 Infinite Power Solutions (IPS) Recharging THINERGY Micro-Energy Cells
3.2.7 Infinite Power Solutions (IPS) THINERGY Charging Methods
3.2.8 Infinite Power Solutions (IPS) Battery Technology For Smart Phones
3.2.9 Infinite Power Solutions (IPS) High-Capacity Cells for Smart Phones
3.2.10 Infinite Power Solutions (IPS) 4v Solid-State Battery Ceramic Technology With Energy Density >1,000wh/L
3.2.11 Infinite Power Solutions (IPS) All-Solid-State HEC Technology
3.3 Excelatron
3.3.1 Excelatron Current State of the Art For Thin Film Batteries
3.3.2 High Temperature Performance of Excellatron Thin Film Batteries
3.3.3 Excelatron Solid State Battery Long Cycle Life
3.3.4 Excelatron Discharge Capacities & Profiles
3.3.5 Excellatron Polymer Film Substrate for Thin Flexible Profile
3.3.6 Excelatron High Power & Energy Density, Specific Power & Energy
3.3.7 Excellatron High Rate Capability
3.3.8 Excellatron High Capacity Thin Film Batteries
3.4 NEC
3.4.1 Toyota

4. Solid State Thin Film Battery Technology
4.1 Technologies For Manufacture Of Solid State Thin Film Batteries
4.2 Cymbet EnerChip™ Solid State Battery Charges 10 Chips Connected In Parallel
4.2.1 Cymbet EnerChip Provides Drop-in Solar Energy Harvesting
4.2.2 Cymbet Wireless Building Automation
4.2.3 Cymbet Solutions: Industry transition to low power IC chips
4.2.4 Cymbet Manufacturing Sites
4.2.5 Cymbet Energy Harvesting Evaluation Kit
4.2.6 EnerChip Products are RoHS Compliant
4.2.7 Cymbet Safe to Transport Aboard Aircraft
4.3 Infinite Power Solutions (IPS) Ceramics
4.3.1 Infinite Power Solutions (IPS) Lithium Cobalt Oxide (LiCoO2) Cathode and a Li-Metal Anode Technology
4.3.2 Infinite Power Solutions Technology Uses Lithium
4.3.3 IPS Thin, Flexible Battery Smaller Than A Backstage Laminate
4.3.4 IPS Higher-Density Solid-State Battery Technology
4.4 NEC Technology For Lithium-Ion Batteries
4.4.1 NEC Using Nickel In Replacement Of A Material
4.4.2 NEC Changed The Solvent Of The Electrolyte Solution
4.5 Air Batteries: Lithium Ions Convert Oxygen Into Lithium Peroxide
4.6 Nanotechnology and Solid State Thin Film Batteries
4.6.1 MIT Solid State Thin Film Battery Research
4.6.2 ORNL Scientists Reveal Battery Behavior At The Nanoscale
4.6.3 Rice University and Lockheed Martin Scientists Discovered Way To Use Silicon To Increase Capacity Of Lithium-Ion Batteries
4.6.4 Rice University50 Microns Battery
4.6.5 Next Generation Of Specialized Nanotechnology
4.6.6 Nanotechnology
4.6.7 Components Of A Battery
4.6.8 Impact Of Nanotechnology
4.6.9 Nanotechnology Engineering Method
4.6.10 Why Gold Nanoparticles Are More Precious Than Pretty Gold
4.6.11 Silicon Nanoplate Strategy For Batteries
4.6.12 Graphene Electrodes Developed for Supercapacitors
4.6.13 Nanoscale Materials for High Performance Batteries
4.7 John Bates Patent: Thin Film Battery and Method for Making Same
4.7.1 J. B. Bates,a N. J. Dudney, B. Neudecker, A. Ueda, and C. D. Evans Thin-Film Lithium and Lithium-Ion Batteries
4.8 MEMS Applications
4.8.1 MEMS Pressure Sensors
4.9 c-Si Manufacturing Developments
4.9.1 Wafers
4.9.2 Texturization
4.9.3 Emitter Formation
4.9.4 Metallization
4.9.5 Automation, Statistical Process Control (SPC), Advanced Process Control (APC)
4.9.6 Achieving Well-controlled Processes
4.9.7 Incremental Improvements
4.10   Transition Metal Oxides, MnO
4.11   Battery Cell Construction
4.11.1 Lithium Ion Cells Optimized For Capacity
4.11.2 Flat Plate Electrodes
4.11.3 Spiral Wound Electrodes
4.11.4 Multiple Electrode Cells
4.11.5 Fuel Cell Bipolar Configuration
4.11.6 Electrode Interconnections
4.11.7 Sealed Cells and Recombinant Cells
4.11.8 Battery Cell Casing
4.11.9 Button Cells and Coin Cells
4.11.10 Pouch Cells
4.11.11 Prismatic Cells
4.12 Naming Standards For Cell Identification
4.12.1 High Power And Energy Density
4.12.2 High Rate Capability
4.13   Comparison Of Rechargeable Battery Performance
4.14   Micro Battery Solid Electrolyte
4.14.1 Challenges in Battery and Battery System Design
4.15   Types of Batteries
4.15.1 Lead-Acid Batteries
4.15.2 Nickel-Based Batteries
4.15.3 Conventional Lithium-ion Technologies
4.15.4 Advanced Lithium-ion Batteries
4.15.5 Thin Film Battery Solid State Energy Storage
4.15.6 Ultra Capacitors
4.15.7 Fuel Cells
4.16   Battery Safety / Potential Hazards
4.16.1 Thin Film Solid-State Battery Construction
4.16.2 Battery Is Electrochemical Device
4.16.3 Battery Depends On Chemical Energy
4.16.4 Characteristics Of Battery Cells

5 Solid State Thin Film Battery Company Profiles
5.1 Balsara Research Group, UC Berkley
5.2 Cymbet
5.2.1 Cymbet Customer/Partner TI
5.2.2 Cymbet EH Building Automation
5.2.3 Cymbet Semi Passive RF Tag Applications
5.2.4 Cymbet Enerchips Environmental Regulation Compliance
5.2.5 Cymbet Investors
5.2.6 Cymbet Investors
5.2.7 Cymbet Distribution
5.2.8 Cymbet Authorized Resellers
5.2.9 Cymbet Private Equity Financing
5.3 Johnson Research & Development / Excellatron
5.3.1 Characteristics of Excellatron Batteries:
5.3.2 Excellatron Thin Film Solid State Battery Applications
5.3.3 Excellatron Strategic Relationships
5.4 Infinite Power Solutions
5.4.1 IPS THINERGY MECs
5.4.2 Infinite Power Solutions Breakthrough Battery Technology
5.4.3 IPS Targets Smart Phone Batteries
5.5 MIT Solid State Battery Research
5.5.1 When Discharging, Special Lithium Air Batteries Draw In Some Lithium Ions To Convert Oxygen Into Lithium Peroxide
5.6 NEC
5.6.1 NEC IT Services Business
5.6.2 NEC Platform Business
5.6.3 NEC Carrier Network Business
5.6.4 NEC Social Infrastructure Business
5.6.5 NEC Personal Solutions Business
5.7 Planar Energy Devices
5.8 Seeo
5.8.1 Seeo Investors
5.9 Toyota
5.10   Watchdata Technologies
5.11 Guangzhou Markyn Battery Co. Polymer Lithium Ion Battery 209
5.11.1 Guangzhou Markyn Battery Co. 210
5.12 Imprint Energy 212
5.12.1 Imprint Energy Aims To Reshape The Battery Landscape 212
5.13 ITN Lithium Technology 213
5.13.1 ITN’s Lithium EC sub-Division Focused On Development And
Commercialization of EC 214
5.13.2 ITN’s SSLB Division Thin-Film Battery Technology 215
5.13.3 ITN Lithium Air Battery 216
5.13.4 ITN Fuel Cell 218
5.13.5 ITN Thin-film Deposition Systems 220
5.13.6 ITN Real Time Process Control 221
5.13.7 ITN Plasmonics 225
5.13.8 ITN's Lithium Technology 226
5.13.9 ITN Lithium Electrochromics 228
5.14 Johnson Research Product Development 232
5.15 Kunshan Printed Electronics Ltd. 233
5.16 KSW Microtec 233
5.16.1 KSW Microtec Efficient Flexible, Producer of RFID Components 233
5.17 Matsushita / Panasonic / Sanyo / Sanyo Solar 234
5.18 NEC Corporation 234
5.18.1 NEC Group Vision 2017 235
5.1.1 NEC Printed Battery 235
5.18.2 NEC Develops Ultra-Thin Organic Radical Battery Compatible with IC
Cards 236
5.18.3 NEC Radio tags 239
5.18.4 NEC RFID Tag 239
5.18.5 NEC Nanotechnology Thin And Flexible Organic Radical Battery (ORB)
242
5.18.6 NEC / Nissan / AESC (Automotive Energy Supply Corporation) 246
5.19 Oak Ridge National Laboratory 247
5.20 Oak Ridge Micro-Energy 250
5.20.1 Oak Ridge Micro-Energy, Inc. 251
5.20.2 Oak Ridge 105mm x 60mm 3.0 Ah Lithium Ion Ultra Safe Prismatic Cell
252
5.21 Paper Battery Company 256
5.21.1 Paper Battery PowerWrapper™ Supercapacitor 257
5.22 Leonhard Kurz / PolyIC 258
5.23 PolyPlus 259
5.23.1 Poly Plus Lithium Water 259
5.24 Prelonic Technologies 259
5.24.1 Prelonic Technologies Printed Batteries 260
5.25 Prelonic Technology 262
5.26 Prieto Battery 262
5.26.1 Prieto Battery 267
5.26.2 Prieto Battery Reducing The Thickness Of The Electrode Results In
Lower Energy
Capacity And Shorter Operating Time 268
5.26.3 Prieto Battery Nanowires Make Up The First Key Piece Of The Battery,
The Anode 269
5.26.4 Proposed Architecture of the Prieto battery 269
5.27 ProLogium 272
5.27.1 ProLogium Solid-State LCB (Lithium Ceramic Battery) 273
5.27.2 ProLogium PLCB (Pouch Type- LCB) 275
5.27.3 ProLogium ELCB (Logithium) 278
5.28 ProtoFlex Thin Film Batteries 279
5.29 PS 280
5.30 Saft 280
5.30.1 Saft, Building For Future Growth 281
5.30.2 Attractive market positioning in high-end niche markets 281
5.31 Samsung 281
5.32 Solicore 282
5.33 Sony Corporation 284
5.33.1 Sony Technology 284
5.34 STMicroelectronics (NYSE:STM) 285
5.34.1 STMicroelectronics Product Technologies 287
5.34.2 ST Custom and Semi-Custom Chips 290
5.1.17 STM Application-Specific Standard Products (ASSPs) 291
5.34.3 ST Secure ICs 292
5.34.4 ST Application Specific Discretes (ASD™) 293
5.34.5 ST In-Check “Lab-on-Chip” 293
5.34.6 ST Multi-Segment Products 293
5.34.7 ST Microcontrollers 294
5.34.8 ST Smart Power Devices 294
5.34.9 ST Standard Linear and Logic 295
5.34.10 ST Discretes 295
5.34.11 ST Protection Devices 296
5.34.12 ST Sensors 296
5.34.13 ST RF 297
5.34.14 ST Real-time Clocks 297
5.1.2 STMicroelectronic EnFilm: Thin-film Batteries 297
5.35 Tesla 298
5.36 Texas Instruments (TXN:NYSE) 299
5.37 Umicore Thin Film Products 300
5.37.1 Umicore Materials Technology Group 301
5.38 VTT 302
5.39 Zibo Dison 303
5.40 Battery manufacturers 304


List Of Figure

Table ES-1 26
Solid State Thin Film Battery Market Driving Forces 26
Table ES-2 29
Smarter Computing Market Driving Forces 29
Table ES-3 30
Thin Film Battery Benefits 30
Table ES-4 31
Comparison Of Battery Performance 31
Figure ES-5 32
Thin Film Battery Energy Density 32
Figure ES-6 34
Solid State Thin Film Battery Market Shares, Dollars, Worldwide, 2014 34
Figure ES-7 36
Solid State Thin Film Battery Market Forecasts Dollars, Worldwide, 2015-2021 36
Table 1-1 40
Thin Film Battery Target Markets 40
Table 1-2 42
Principal Features Used To Compare Rechargeable Batteries 42
Table 1-3 43
Challenges in Battery and Battery System Design 43
Figure 1-4 52
Discharge of a Lithium Battery 52
Table 1-6 58
Characteristics Of Battery Cells 58
Table 2-1 61
Solid State Thin Film Battery Market Driving Forces 61
Table 2-2 64
Smarter Computing Market Driving Forces 64
Table 2-3 65
Thin Film Battery Benefits 65
Table 2-4 66
Comparison Of Battery Performance 66
Figure 2-5 67
Thin Film Battery Energy Density 67
Figure 2-6 69
Solid State Thin Film Battery Market Shares, Dollars, Worldwide, 2014 69
Table 2-7 70
Solid State Thin Film Battery Market Shares, Dollars, Worldwide, 2014 70
Table 2-8 71
Solid State Thin Film Battery Market Shares, Units and Dollars, Worldwide, 2014
71
Figure 2-9 73
Solid State Thin Film Battery Market Forecasts Dollars, Worldwide, 2015-2021 73
Table 2-10 74
Solid State Thin Film Battery Market Forecasts Dollars, Worldwide, 2015-2021 74
Table 2-11 75
Solid State Thin Film Battery Market, Energy Harvesting, Power Bridging, and
Wireless Sensor Networks, Forecasts Dollars, Worldwide, 2015-2021 75
Table 2-12 76
Solid State Thin Film Battery Market, Energy Harvesting, Power Bridging, an
Wireless Sensor Networks, Forecasts, Percent, Worldwide, 2015-2021 76
Table 2-13 77
Solid State Battery Applications 77
Figure 2-14 80
Smarter Computing Depends on Instrumented Devices 80
Figure 2-15 81
Smarter Planet Impact on IT 81
Table 2-16 84
Thin Film Battery Unique Properties 84
Figure 2-17 87
Mouser Solid State Thin Film Battery Offerings 87
Table 2-18 93
Solid State Thin Film Battery Regional Market Segments, 2014 93
Table 2-19 94
SOlid State Thin Film Battery Regional Market Segments, 2014 94
Table 3-1 97
Cymbet Applications 97
Table 3-2 99
Cymbet EnerChip Industry Target Markets 99
Table 3-3 100
Cymbet Solid State Energy Storage Backup Target Markets 100
Figure 3-4 102
Cymbet EnerChip CBC3105-BDC: 102
Table 3-5 103
Cymbet EnerChip: Target Markets 103
Table 3-6 105
Cymbet Energy Harvesting Applications 105
Table 3-7 109
Cymbet EnerChips ROI 109
Table 3-8 110
Cymbet EnerChips Features 110
Table 3-9 111
Cymbet EnerChip Improve End-Product Sales 111
Table 3-10 112
Cymbet EnerChip Feature Sets 112
Table 3-11 113
Cymbet EnerChip CC Features 113
Table 3-12 114
Cymbet EnerChip Components 114
Figure 3-13 116
EnerChip RTC Uses an Embedded Energy Co-Package 116
Figure 3-14 117
EnerChip Bare Die Soldering 117
Table 3-15 120
Cymbet's EnerChip Benefits 120
Figure 3-16 126
Apple iWatch 126
Table 4-1 131
Solid-State Thin Film Battery Unique Properties 131
Figure 4-2 134
Department of Energy's Oak Ridge National Laboratory Battery Behavior At The
Nanoscale 134
Figure 4-3 137
Rice Researchers Advanced Lithium-Ion Technique has Microscopic pores that dot
a silicon wafer 137
Figure 4-4 140
Rice University50 Microns Battery 140
Figure 4-5 142
Silver Nanoplates Decorated With Silver Oxy Salt Nanoparticles 142
Table 4-6 146
Approaches to Selective Emitter (SE) Technologies 146
Table 2-7 157
Comparison Of Battery Performances 157
Table 4-8 158
Common Household-Battery Sizes, Shape, and Dimensions 158
Figure 4-9 159
Design Alternatives of Thin Film Rechargeable Batteries 159
Table 5-1 163
Blue Spark Printed, Carbon-Zinc Battery Target Markets 163
Table 5-2 165
Blue Spark Printed Battery Target Markets 165
Table 5-3 166
Blue Spark printed battery Properties 166
Table 5-4 167
Blue Spark Ultra-Thin UT Batteries Form Factor Applications 167
Figure 5-5 174
Cymbet Elk River Manufacturing Facility 174
Figure 5-6 175
Cymbet Lubbock Texas Manufacturing Site 175
Figure 5-7 177
Authorized Distributors 177
Table 5-8 187
Enfucell SoftBattery Applications 187
Table 5-9 188
FlexEl Battery Solutions Products 188
Table 5-10 189
FlexEl Battery 189
Figure 5-11 191
FlexEl Primary Disposable Solution 191
Figure 5-12 192
FlexEl Disposable Battery Specifications 192
Figure 5-13 193
FlexEl Rechargable Battery Specifications 193
Table 5-14 196
Front Edge Technology Description 196
Table 5-15 203
GS NANOTECH 203
Figure 5-16 204
GS Nanotech Thin Film Battery 204
Figure 5-17 204
GS NANOTECH Thin Film Battery 204
Figure 5-18 205
GS Nanotech Nanotechnology 205
Source: GS Nanotech. 205
Table 5-19 206
GS NANOTECH Thin Film Battery Advantages 206
Figure 5-20 209
Guangzhou Markyn Battery Co. Polymer Lithium Ion Battery 209
Table 5-21 211
Guangzhou Markyn Battery Offerings 211
Table 5-22 213
Imprint Energy Battery Features 213
Table 5-23 217
ITN Technologies 217
Figure 5-24 217
ITN Thin Film Battery Technology 217
Figure 5-25 219
ITN Battery 219
Figure 5-26 220
ITN Thin-Film Deposition Systems 220
Figure 5-27 221
ITN’s Thin-Film Deposition Systems 221
Table 5-28 223
ITN Thin-Film Deposition Systems Products and Services Offered 223
Table 5-29 224
ITN Thin-Film Deposition Systems 224
Figure 5-30 226
ITNIYN Fuel Cells 226
Table 5-31 229
ITN’s SSLB Solid-State Lithium Battery Target Markets 229
Table 5-32 230
ITN’s SSLB Technology Advantages 230
Table 5-33 231
ITN Technologies 231
Figure 5-34 235
NEC Printed Battery 235
Figure 5-35 238
NEC ORB Thin, Flexible Battery Technology 238
Figure 5-36 240
NEC ORB Battery 240
Figure 5-37 241
NEC ORB Flexible Battery 241
Table 5-38 243
NEC Nanotechnology Thin And Flexible Organic Radical Battery (ORB)
Characteristics Of The Technologies 243
Figure 5-39 244
NEC Organic Radical Battery 244
Table 5-40 248
Oak Ridge National Laboratory ORNL Advance Battery Materials And
Processing Technology Contracts 248
Table 5-41 249
Oak Ridge National Laboratory And Battery Manufacturers Energy Materials
Program Aspects 249
Figure 5-42 251
Oak Ridge Micro-Energy 251
Figure 5-43 253
Oak Ridge Micro-Energy Discharge of a Thin-Film Lithium Battery At Current
Densities o
f 0.02, 0.1, 0.2, 0.5, 1.0, 2.0, 5.0, and 10.0 mA/cm2 253
Figure 5-44 254
Discharge of a thin-film lithium-ion battery at current densities of
0.02, 0.1, 0.2, 0.5, 1.0, 2.0, 5.0, and 10.0 mA/cm2 254
Figure 5-45 255
Ragone Plots Graph Of Energy vs. Power Per Unit Area Of The Cathode From The
Discharge Data For The Lithium And Lithium-Ion Batteries 255
Figure 5-46 258
Poly IC Printed Electronics 258
Figure 5-47 260
Prelonic Technologies Chemical Systems 260
Figure 5-48 263
Prieto Battery 3D architecture 263
Figure 5-49 270
Prieto Battery Nanowires Li-ion Batteries Using A 3D Structure 270
Table 5-50 271
Prieto Battery Features 271
Figure 5-51 274
ProLogium Solid-State LCB (Lithium Ceramic Battery) Characteristics 274
Figure 5-52 283
Solicore Flexion Lithium Polymer Batteries 283
Table 5-53 300
Umicore Business Areas 300
Figure 5-54 301
Umicore Thin Film Products 301

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