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Worldwide Nanotechnology Thin Film Lithium-Ion Battery Market Shares Strategies, and Forecasts, 2009-2015
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Abstract
WinterGreen Research announces that it has a new study on Worldwide
nanotechnology thin film lithium - ion battery markets. The 2009 study has 412
pages, 112 Tables and Figures. Worldwide Nanotechnology lithium - ion
batteries are poised to achieve significant growth as units become smaller and
less expensive broadening the types of energy applications in which they are
included.
Worldwide nanotechnology thin film lithium - ion batteries are poised to
achieve significant growth as units become more able to achieve deliver of
power to electric vehicles efficiently. Less expensive lithium - ion batteries
allow leveraging economies of scale and proliferation of devices into a wide
range of applications. According to Susan Eustis, lead author of the study,
"Economies of scale leverage the lithium - ion battery nanotechnology advances
needed to make lithium - ion batteries competitive. Nanotechnology provided by
lithium - ion research solves the issues poised by the need to store renewable
energy. Lithium - ion batteries switch price reductions are poised to drive
market adoption by making units affordable."
Nanotechnology results obtained in the laboratory are being translated into
commercial products. The processes of translating the nanotechnology science
into thin film lithium ion batteries are anticipated to be ongoing. The
breakthroughs of science in the laboratory have only begun to be translated
into life outside the lab, with a long way to go in improving the functioning
of the lithium - ion batteries. Unlike any other battery technology, thin film
solid - state batteries show very high cycle life. Using very thin cathodes
(0.05μm) batteries have been cycled in excess of 45,000 cycles with very
limited loss in capacity. After 45,000 cycles, 95% of the original capacity
remained.
Then there is the problem of translating the evolving technology into
manufacturing process. What this means is that the market will be very
dynamic, with the market leaders continuously being challenged by innovators,
large and small that develop more cost efficient units. Systems integration
and manufacturing capabilities have developed a broad family of high - power
lithium - ion batteries and battery systems. A family of battery products,
combined with strategic partner relationships in the transportation, electric
grid services and portable power markets, position vendors to address these
markets for lithium - ion batteries.
Electric Vehicles depend on design, development, manufacture, and support of
advanced, rechargeable lithium - ion batteries. Batteries provide a
combination of power, safety and life. Next - generation energy storage
solutions are evolving as commercially available batteries. Lithium - ion
batteries will play an increasingly important role in facilitating a shift
toward cleaner forms of energy. Innovative approaches to materials science and
battery engineering are available from a large number of very significant
companies - - GE, Panasonic Sanyo / Matsushita Industrial Co., Ltd., NEC,
Saft, Toshiba, BYD / Berkshire Hathaway, LG Chem, Altair Nanotechnologies,
Samsung, Sony, A123 Systems with MIT technology, and Altair Nanotechnologies.
Markets for lithium - ion batteries at $911 million in 2008 are anticipated to
reach $9.1 billion by 2015, growing in response to decreases in unit costs and
increases. Lithiumion batteries used in cell phones and PCs, and in cordless
power tools are proving the technology. Units are shipped into military
markets and are used in satellites, proving the feasibility of systems. Small,
lithium - ion prismatic batteries prove the feasibility of this technology.
The large emerging markets are for hybrid and electric vehicles powered by
renewable energy systems.
Table of Contents
THIN FILM BATTERY EXECUTIVE SUMMARY
THIN FILM LITHIUM ION BATTERY EXECUTIVE SUMMARY
- Worldwide Nanotechnology Thin Film Lithium-Ion
- Battery Market Driving Forces
- Market Driving Forces
- Nanotechnology Forms the Base for Lithium-Ion Batteries
- Competitors
- Lithium-Ion Battery Market Shares
- Lithium-Ion Battery Market Forecasts
THIN FILM BATTERY DESCRIPTION AND MARKET DYNAMICS
1. THIN FILM LITHIUM ION BATTERY MARKET DESCRIPTION AND MARKET DYNAMICS
- 1.1 Lithium-Ion Battery Target Markets
- 1.1.1 Project Better Place and the Renault-Nissan Alliance
- 1.1.2 Largest Target Market, The Transportation Industry
- 1.1.3 Electric Grid Services Market
- 1.1.4 Portable Power Market, Power Tools
- 1.2 Lithium-Ion Battery Technologies Transportation Industry Target Market
- 1.3 Energy Storage For Grid Stabilization
- 1.3.1 Local Energy Storage Benefit For Utilities
- 1.4 Applications Require On-Printed Circuit Board Battery Power
- 1.4.1 Thin-film vs. Printed Batteries
- 1.5 Smart Buildings
- 1.5.1 Permanent Power for Wireless Sensors
- 1.6 Battery Safety / Potential Hazards
- 1.7 Thin Film Solid-State Battery Construction
- 1.8 Battery Is Electrochemical Device
- 1.9 Battery Depends On Chemical Energy
- 1.9.1 Characteristics Of Battery Cells
- 1.9.2 Batteries Are Designed Differently For Various Applications
THIN FILM BATTERY SHARES AND MARKET FORECASTS
2. THIN FILM LITHIUM ION BATTERY MARKET SHARES AND MARKET FORECASTS
- 2.1 Worldwide Nanotechnology Thin Film Lithium-Ion Battery Market Driving
Forces
- 2.1.1 Market Driving Forces
- 2.1.2 Nanotechnology Forms the Base for Lithium-Ion Batteries
- 2.1.3 Competitors
- 2.2 Lithium-Ion Battery Market Shares
- 2.2.1 ExxonMobil Affiliate in Japan / Tonen Chemical
- 2.3 Lithium-Ion Battery Market Forecasts
- 2.4 Electric Vehicle and Hybrid Vehicle Lithium-Ion Battery Market Shares
- 2.4.1 BYD 2-16
- 2.4.2 Johnson Controls-Saft
- 2.4.3 Saft Battery Technologies
- 2.4.4 A123Systems 32 Series Automotive Class Lithium Ion"! Cells: 2-17
- 2.4.5 NEC and Nissen
- 2.4.6 LG Chem
- 2.4.7 EnerDel
- 2.4.8 Competition
- 2.5 Electric and Hybrid Vehicle Lithium-Ion Battery Market Forecasts
- 2.5.1 Largest Target Market, The Transportation Industry
- Thin Film Advanced Lithium-Ion Battery EV Market
- Thin Film Lithium-Ion And Lithium Polymer Automotive Batteries
- 2.6 Thin-Film and Printed Batteries: On-Board Solutions for Low-Power
Electronics
- 2.6.1 Solicore Tiny Flat Battery
- 2.6.2 Thin-Film, Organic, and Printed Batteries: On-Board Solutions for
Low-Power Electronics
- 2.7 Cell Phone, Communications, And PC Lithium-Ion Battery Technology
Markets Discussion
- 2.7.1 Samsung SDI
- 2.7.2 BYD 2-33
- 2.7.3 Saft 2-33
- 2.7.4 Portable Power Competition
- 2.8 Lithium-Ion Battery Technology Portable Power Market, Power Tools
Market Shares
- 2.9 Lithium-Ion Battery Technology Portable Power, Power Tools Market
Forecasts
- 2.10 Lithium-Ion Battery Technology Electric Grid Services Markets
- 2.10.1 Electric Grid Services
- 2.11 Thin Film Lithium-Ion Battery Market Positioning
- 2.11.1 US And Its Allies Are Changing The Military Landscape
- 2.12 Digital Device Battery Forecasts
THIN FILM BATTERY PRODUCTS
3. THIN FILM LITHIUM-ION BATTERY PRODUCT DESCRIPTION
- 3.1 A123 Systems
- 3.1.1 A123 Systems Lithium Ion Cell Construction Based On A Dual Plate
Tubular Design
- 3.1.2 A123Systems 32 Series Automotive Class Lithium Ion"! Cells: 3-5
- 3.1.3 GM and A123Systems Co-Develop Lithium-Ion Battery Cell for
Chevrolet Volt
- 3.1.4 A123Systems / GE Production Contract for Norewegian Think Electric
Vehicles
- 3.1.5 A123Systems Patent for Nanophosphate"! Lithium Ion Battery
Technology
- 3.2 LG Chem
- 3.2.1 LG Lithium-Ion Cylindrical Battery
- 3.2.2 LG Lithium-ion Polymer Battery
- 3.2.3 LG Lithium-ion Battery Prismatic Type
- 3.2.4 LG Chem
- 3.3 SAFT
- 3.3.1 Saft Lithium-ion (Li-ion) Batteries
- 3.3.2 Saft is Li-ion Batteries For Commercial GEO Satellites to JSC ISS
of Russia
- 3.3.3 Saft Contract To Power Hybrid Electric Mobile Utility Systems From
Titan Energy Development
- 3.3.4 Saft and ABB Develop New High Voltage Li-ion Battery System 3-22
- 3.3.5 Saft Hybrid Battery Technology for Wisconsin Clean Energy
- 3.3.6 Saft High-Energy Lithium-Ion (Li-ion) Batteries For Raytheon
- 3.3.7 Saft Lithium-Ion (Li-ion) Battery Backup Systems
- 3.3.8 Saft Energy Storage As A Key Renewable Energy Enabling Technology
- 3.3.9 Saft / Solion Large Li-ion batteries
- 3.3.10 Saft Lithium-Sulfur Dioxide (Li-So2) Batteries
- 3.3.11 Saft Lithium Technologies
- 3.3.12 Saft Lithium-thionyl chloride (Li-SOCl2)
- 3.3.13 Lithium-thionyl chloride (Li-SOCl2) - LS/LST/LSG cell ranges
- 3.3.14 Saft Small LS/LST bobbin cells
- 3.3.15 Saft Large LS/T bobbin cells
- 3.3.16 Saft Lithium-Manganese Dioxide (Li-MnO2)
- 3.3.17 Saft Lithium-ion (Li-ion)
- 3.4 BYD 3-50
- 3.4.1 Warren Buffett Buys 10 Percent Stake In BYD Chinese Battery
Manufacturer
- 3.4.2 BYD Battery Expertise
- 3.5 Panasonic / Sanyo
- 3.6 Samsung
- 3.7 Ener1 / EnerDel
- 3.7.1 EnerDel Lithium-Ion Prismatic Design
- 3.7.2 EnerDel Addressing Market Demand for Hybrid Electric Vehicles
(HEVs)
- 3.7.3 EnerDel 5Amp Battery Pack
- 3.8 Imara 3-60
- 3.9 ExxonMobil Affiliate in Japan / Tonen Chemical
- 3.9.1 Tonen Chemical Leading Supplier Of Separators For Lithium Ion
Batteries
- 3.10 NEC 3-63
- 3.10.1 Nissan and NEC Group
- 3.10.2 Nissan And NEC Joint Venture
- 3.10.3 NEC High-Performance Lithium-Ion Batteries Employ A Compact
Laminated Configuration 3.10.4 NEC / Nissan Low-Cost Lithium-Manganese
Batteries
- 3.10.5 NEC Lamilion Energy
- 3.10.6 NEC Subaru
- 3.10.7 NEC Thin Film Battery Has Sixteen Modules Consisting Of Twelve
Cells, Serially Connected
- 3.10.8 NEC / Subaru Thin Film Battery Flat Shape
- 3.11 Sony 3-71
- 3.12 Matshushita Industrial Co., Ltd. (Panasonic)
- 3.12.1 Panasonic Lithium Batteries
- 3.12.2 Panasonic Lithium-Ion Rechargeable Batteries
- 3.13 E-One Moli Energy
- 3.13.1 Product Data Sheets
- 3.14 QuantumSphere
- 3.15 Solicore Ultra Thin-Film Battery
- 3.15.1 Solicore' s Flexion Lithium Polymer Batteries
- 3.15.2 Solicore Flexion Lithium Powered Cards
- 3.15.3 Solicore RFID (Radio Frequency Identification) Devices
- 3.15.4 Solicore' s FlexionR Batteries Bluechip Million Unit Purchase
- 3.15.5 Solicore Supports Smart Cards
- 3.16 Cymbet EnerChip"! Solid-State, Rechargeable Thin-Film Batteries
- 3.16.1 Cymbet Enerchip"! Sensors Support
- 3.17 Front Edge Technology
- 3.18 Excellatron Thin-Film Micro-Batteries
- 3.18.1 Contrast To Conventional Lithium Cells
- 3.18.2 Excellatron Market Advantage
- 3.18.3 Excellatron Battery Current State of the Art
- 3.18.4 Excellatron Battery Intrinsically Safe
- 3.18.5 High Temperature Performance of Excellatron Thin Film Batteries
- 3.18.6 Excellatron Long Cycle Life
- 3.18.7 Excellatron Polymer Film Substrate for Thin Flexible Profile
- 3.18.8 Excellatron Unique Proprietary Passivation Barrier and Packaging
Solution
- 3.19 Front Edge 50,000 Prototypes Of Nanoenergy Batteries
- 3.19.1 Front Edge Technology (FET)
- 3.20 Infinite Power Solutions (IPS) Flexible Thin-Film Batteries
- 3.20.1 Infinite Power Solutions
- 3.21 Oak Ridge Micro-Energy
- 3.21.1 Oak Ridge Micro-Energy Thin Film Batteries
- 3.22 Energizer
- 3.22.1 Energizer Holdings
- 3.23 Valence 3-134
- 3.23.1 PVI for Valence' s U-Charge(R) XP Energy Storage Systems
- 3.23.2 Valence Lithium Phosphate
- 3.23.3 Valence Lithium Phosphate Stability and Dependability
- 3.23.4 Valence Safety Focus
- 3.23.5 Valence Lithium Phosphate Alternative to Lead-Acid
- 3.23.6 Valence Lithium Phosphate Storage and Run-Time
- 3.23.7 Valence Lithium Phosphate Safety and Maintenance Free
- 3.24 ITN Energy Systems
- 3.24.1 ITN Intelligent Processing, Sensors, & Controls:
- 3.24.2 ITN Control:
- 3.24.3 ITN Sensors
- 3.24.4 ITN Unique Sensors: X-Ray Fluorescence And Parallel Detection
Spectroscopic Ellipsometer
- 3.25 ULVAC 3-159
- 3.26 Intersil 3-159
THIN FILM BATTERY TECHNOLOGY
4. THIN FILM LITHIUM ION BATTERY TECHNOLOGY
- 4.1 Vendor Lithium-ion Battery Strategy
- 4.1.1 Rechargeable Lithium Batteries Characteristics
- 4.2 Challenges in Battery Design
- 4.2.1 Advanced Lithium-ion Batteries Requirements
- 4.3 Vendor Lithium-Ion Battery Positioning
- 4.3.1 High-Quality, Volume Manufacturing Facilities
- 4.4 Applications Of Lithium-Ion Batteries
- 4.5 Mobile Phone Industry
- 4.5.1 Nanowires
- 4.5.2 Thin Film Battery Enabling Chemistries
- 4.5.3 The Cathodes
- 4.5.4 Solid State Devices Provide More Energy Density
- 4.6 Advantages of Lithium-Ion Batteries
- 4.6.1 Lithium-Ion Battery Shortcomings
- 4.6.2 Charging
- 4.6.3 Applications
- 4.6.4 Costs 4-20
- 4.7 Lithium Cell Chemistry Variants
- 4.7.1 Lithium-ion
- 4.7.2 Lithium-ion Polymer
- 4.7.3 Other Lithium Cathode Chemistry Variants
- 4.7.4 Lithium Cobalt LiCoO2
- 4.7.5 Lithium Manganese LiMn2O4
- 4.7.6 Lithium Nickel LiNiO2
- 4.7.7 Lithium (NCM) Nickel Cobal Manganese - Li(NiCoMn)O2
- 4.7.8 Lithium Iron Phosphate LiFePO4
- 4.8 Operating Performance Of The Cell Can Be Tuned
- 4.9 Lithium Metal Polymer
- 4.9.1 Lithium Sulphur Li2S8
- 4.9.2 Alternative Anode Chemistry
- 4.10 ExxonMobil affiliate, Tonen Chemical Polyethylene-Based, Porous Film
- 4.11 Cymbet Alternate Manufacturing
- 4.12 Thin-Film Batteries Packaging
- 4.13 ITN Energy Systems Fibrous Substrates, PowerFiber
- 4.13.1 ITN Sensors
- 4.14 Cell Construction
- 4.15 Impact Of Nanotechnology
- 4.16 Thin Film Batteries
- 4.16.1 Thin Film Battery Timescales and Costs
- 4.16.2 High Power And Energy Density
- 4.16.3 High Rate Capability
- 4.17 Comparison Of Rechargeable Battery Performance
- 4.18 Polymer Film Substrate
- 4.19 Micro Battery Solid Electrolyte
THIN FILM BATTERY COMPANY PROFILES
5.1 NANOTECHNOLOGY THIN FILM BATTERY LITHIUM-ION COMPANY PROFILES
- 5.1 Nanotechnology Thin Film Battery Lithium-Ion
- 5.2 A123 Systems
- 5.2.1 A123 Systems Revenue
- 5.2.2 A123Systems Registration Statement for Initial Public Offering
- 5.2.3 A123 Systems Batteries Benefits
- 5.2.4 A123 Systems Competitive Advantage
- 5.2.5 A123 Systems Strategy
- 5.2.6 A123Systems and GE
- 5.2.7 A123 Acquisition of Hymotion
- 5.2.8 Procter & Gamble Duracell and A123 Systems Collaborate
- 5.2.9 Cobasys and A123 Systems
- 5.3 Advanced Cerametrics
- 5.4 Altair Nanotechnologies
- 5.4.1 Altair Nanotechnologies Power and Energy Group
- 5.4.2 Altair Nanotechnologies Performance Materials Division
- 5.4.3 Altair Nanotechnologies Life Sciences Division
- 5.4.4 Altair Nanotechnologies One-Megawatt Battery System Available for
Commercial Operation by AES Energy Storage, LLC
- 5.4.5 Altair Nanotechnologies Revenues
- 5.5 Applied Data
- 5.6 Bekaert
- 5.7 Robert Bosch GmbH
- 5.8 Boston Power / Sonata
- 5.9 BYD 5-21
- 5.9.1 Warren Buffett Buys 10 Percent Stake In BYD Chinese Battery
Manufacturer
- 5.10 Cymbet 5-23
- 5.10.1 Cymbet Thin-Film, Solid-State Battery Technology
- 5.10.2 Cymbet and ANT Wireless Sensor Network
- 5.10.3 Garmin International ANT"! Wireless Network
- 5.11 Dow 5-25
- 5.12 E-One Moli Energy Group
- 5.13 Ener1 5-27
- 5.13.1 Ener1 Third Quarter 2008 Revenue
- 5.13.2 Ener1 Positioning Technology Originally Pioneered By Argonne
National Lab
- 5.13.3 Ener1 Acquires Enertech Leading Korean Lithium-ion Battery Cell
Producer
- 5.13.4 Ener1 / Enertech Specializes In Producing Large Format Flat
("Prismatic") Cells
- 5.13.5 EnerDel Operations
- 5.14 Energizer
- 5.15 Excellatron
- 5.16 Exon 5-45
- 5.16.1 ExxonMobil Chemical / Tonen Chemical Corporation
- 5.17 Front Edge Technology (FET)
- 5.18 GE 5-47
- 5.18.1 GE Global Research
- 5.18.2 GE Energy Financial Services
- 5.19 GM 5-48
- 5.19.1 General Motors Faces Bankruptcy
- 5.20 Ignite 5-51
- 5.21 IPS 5-51
- 5.22 Johnson Controls-Saft
- 5.23 KSW Microtec
- 5.24 LG Petrochemical
- 5.25 MMT Funds
- 5.26 NEC 5-54
- 5.26.1 Nissan Motor Co., Ltd., NEC, And Subsidiary NEC TOKIN
Joint-Venture Company - Automotive Energy Supply Corporation (AESC) -
- 5.26.2 First Commercial Application For AESC' s Li-Ion Batteries
- 5.26.3 NEC TOKIN Lithium-Manganese Electrodes by 2009
- 5.26.4 Nissan Partnership With NEC
- 5.26.5 NEC Lamilion Energy
- 5.27 Oak Ridge Micro-Energy
- 5.28 Panasonic / Sanyo
- 5.29 QuantumSphere
- 5.30 Saft 5-64
- 5.30.1 Saft Battery Technologies
- 5.30.2 Saft Industrial Battery Group (IBG)
- 5.30.3 Saft Specialty Battery Group (SBG)
- 5.30.4 Saft Rechargeable Battery Systems (RBS)
- 5.30.5 Saft Research and Development
- 5.30.6 Johnson Controls-Saft United States Advanced Battery Consortium
(USABC)
- 5.31 Samsung
- 5.32 Solicore 5-73
- 5.32.1 Solicore' s FlexionR Batteries Bluechip Million Unit Purchase
- 5.32.2 Solicore Embedded Power Solutions
- 5.33 Think 5-75
- 5.34 Valence 5-76
- 5.34.1 Valence Strategy
- 5.34.2 Phases Of Valence Business Strategy
- 5.35 Ulvac 5-80
List of Tables and Figures
THIN FILM BATTERY EXECUTIVE SUMMARY
- Table ES-1
- Lithium-Ion Battery Market Driving Forces
- Table ES-2
- Energy Advantages Of Thin-Film Batteries
- Figure ES-3
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Dollars, 2008
- Figure ES-4
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Dollars, 2009-2015
THIN FILM BATTERY MARKET DESCRIPTION AND MARKET DYNAMICS
- Table 1-1
- Principal Features Used To Compare Rechargeable Batteries
- Figure 1-2
- BMW' s Mini E Electric Car Powered By A Rechargeable Lithium-Ion Battery
- Table 1-3
- Examples of Hybrid Electric Vehicles
- Figure 1-4
- Typical Structure Of A Thin Film Solid State Battery
- Table 1-5
- Characteristics Of Battery Cells
THIN FILM BATTERY SHARES AND MARKET FORECASTS
- Table 2-1
- Lithium-Ion Battery Market Driving Forces
- Table 2-2
- Energy Advantages Of Thin-Film Batteries
- Figure 2-3
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Dollars, 2008
- Table 2-4
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Dollars, 2008
- Figure 2-5
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Dollars, 2009-2015
- Figure 2-6
- Worldwide Lithium-Ion and Advanced Lithium-ion Battery Market Forecasts,
Automotive, Power Tools, Electric Grid, and PC Card, Dollars, 2009-2015
- Figure 2-7
- Worldwide Lithium-Ion Thin Film Automotive Advanced Battery Shipments,
Market Shares, Dollars, 2008
- Figure 2-8
- Worldwide Lithium-Ion Thin Film Automotive Advanced Battery Shipments,
Market Shares, Dollars, 2008
- Figure 2-9
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Dollars, 2009-2015
- Figure 2-10
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Units, 2009-2015
- Figure 2-11
- Worldwide Lithium-Ion Thin Film Advanced Battery Shipments, Market
Shares, Units and Dollars, 2009-2015
- Figure 2-12
- Worldwide PC Card On Board Lithium-Ion Batteries Market Forecasts,
Dollars, 2009-2015
- Figure 2-13
- Worldwide Lithium-Ion Thin Film Cordless Tool Advanced Battery
Shipments, Market Shares, Dollars, 2008
- Table 2-14
- Worldwide Lithium-Ion Thin Film Cordless Tool Advanced Battery
Shipments, Market Shares, Dollars, 2008
- Figure 2-15
- Worldwide Lithium-Ion Battery Portable Power Tool and Advanced Portable
Battery Shipments, Market Forecasts, Dollars, 2009-2015
- Figure 2-16
- Worldwide Electric Grid Lithium-Ion Battery Storage Market Forecasts,
Dollars, 2009-2015
- Table 2-17
- Commercialization Challenges Of The Automotive, Truck, and Bus Thin Film
Battery Industry
- Table 2-18
- Integrated Thin Film Battery Personal Transport Power Systems
- Table 2-19
- Requirements For Advanced Power Sources In A Variety Of Military
Applications
- Table 2-20
- Large-Format Lithium-Ion Battery Key Advantages
THIN FILM BATTERY PRODUCT POSITIONING
- Figure 3-1
- A123 Systems Lithium Ion Battery
- Table 3-2
- A123 Systems APR18650M1 Features
- Figure 3-3
- A123 Systems lithium ion battery Cells: 26650
- Figure 3-4
- Figure 3-5
- A123 Systems Hybrid Characteristics
- Figure 3-6
- A123 Systems Hybrid Discharge Characteristics
- Table 3-7
- Table 3-8
- A123 Systems Heavy Duty Custom and Standard Solutions
- Figure 3-9
- LG Chem Lithium-Ion Batteries
- Table 3-10
- Saft Lithium Technologies
- Table 3-11
- Saft Lithium-Ion Battery Main applications
- Table 3-11 (Continued)
- Saft Lithium-Ion Battery Main applications
- Figure 3-12
- Saft Non Rechargeable Battery
- Table 3-13
- Saft Lithium-Ion Construction Features
- Table 3-14
- Saft Lithium-Ion Battery Benefits
- Figure 3-15
- Saft Lithium-Sulfur Dioxide (Li-SO2) Batteries
- Table 3-16
- Saft Lithium-Ion Battery Variations
- Figure 3-17
- EnerDel Automotive Battery
- Table 3-18
- EnerDel Lithium Ion Battery System for HEVs
- Table 3-19
- EnerDel Automotive Battery Features
- Table 3-20
- Imara Thin Film Battery Cells
- Figure 3-21
- NEC Fuel Cells and Catalysts
- Table 3-22
- Key Features of Sony NP-FP71 Hybrid Lithium Ion Rechargeable Battery
- Table 3-22 (Continued)
- Key Features of Sony NP-FP71 Hybrid Lithium Ion Rechargeable Battery
- Figure 3-23
- Panasonic Lithium Batteries
- Figure 3-24
- Panasonic Lithium-Ion Rechargable Batteries
- Table 3-25
- Panasonic Rechargeable Lithium ion Batteries Features:
- Table 3-26
- Panasonic Rechargeable Lithium ion Batteries
- Table 3-27
- Panasonic Rechargeable Lithium ion Batteries
- Table 3-28
- Solicore Flexion Battery Product Features:
- Table 3-29
- Solicore' s Flexion Lithium Polymer Battery Applications
- Table 3-30
- Solicore' s Flexion Lithium Polymer Battery Uses
- Figure 3-31
- Solicore Flexion High Temperature Batteries Survive Lamination
- Table 3-31A
- Solicore RFID (Radio Frequency Identification) Applications
- Table 3-32
- Excellatron Nanotechnology Thin Film Battery Features
- Table 3-33
- Excellatron Battery Advantages
- Table 3-34
- Excellatron Battery Thin Film Solid State Battery Components
- Figure 3-35
- Excellatron Thin Film Battery Charge/Discharge Profile at 25oC.
- Figure 3-36
- Excellatron Thin Film Battery Charge/Discharge Profile At 150oC.
- Figure 3-37
- Excellatron High Temperature (150oC) Charge And Discharge Capacity
- Figure 3-38
- Excellatron Capacity And Resistance Of Thin Film Battery As A Function
Of Temperature
- Figure 3-39
- Excellatron' s Battery (0.1 mAh) Discharged By A 100 mA Pulse at 80oC.
- Figure 3-40
- Excellatron High Rate Pulse Discharge
- Figure 3-41
- Long Term Cyclability Of A Thin Film Solid State Battery
- Figure 3-42:
- Excellatron Thin Film Battery Long Term Cyclability
- Figure 3-43
- Discharge Capacity Of Several Typical Cathode Materials
- Figure 3-44:
- Excellatron Thin film batteries deposited on a thin polymer substrate.
- Figure 3-45
- Excellatron Proprietary Passivation Barrier and Packaging
- Table 3-46
- Comparison Of Battery Performances
- Figure 3-47
- Oak Ridge Construction of a Thin Film Battery
- Table 3-48
- Key Features of Valence Lithium Phosphate Technology
- Table 3-49
- Figure 3-50
- Table 3-51
- ITN Thin Film Battery Design Features/Advantages
- Table 3-52
- ITN Thin Film Battery Economical production
- Table 3-53
- ITN Thin Film Battery Strengths
- Figure 3-54
- ITN Intelligent Process Control
- Figure 3-55
- Framework of Intelligent Processing of Materials
- Figure 3-56
- XRF Instrument Developed by ITN Used on a System
- Figure 3-57
- Figure 3- 58
- Table 3-59
- Thin-film Process Capabilities
- Table 3-60
- ITNThin-film Material Processing Experience Metals
THIN FILM BATTERY TECHNOLOGY
- Table 4-1
- Challenges in Lithium-ion Battery Design
- Table 4-2
- Thin Film Battery Unique Properties
- Table 4-3
- Comparison of battery performances
- Table 4-4
- Comparison of battery performances
- Table 4-5
- Thin Films For Advanced Batteries
- Table 4-6
- Thin Film Batteries Technology
- Table 4-7
- Thin Film Battery / Lithium Air Batteries Applications
- Figure 4-8
- Polymer Film Substrate Thin Flexible battery Profiles
- Figure 4-9
- Design Alternatives of Thin Film Rechargable Batteries
THIN FILM BATTERY COMPANY PROFILES
- Table 5-1
- A123 Systems Batteries Benefits
- Table 5-2
- A123 Systems Competitive Positioning
- Figure 5-3
- Boston-Power Charge Curve
- Figure 5-4
- Boston-Power Discharge Curve
- Figure 5-5
- Figure 5-6
- EnerDel Lithium Power Systems
- Figure 5-7
- EnerDel Lithium Power USABC Contracts
- Figure 5-8
- EnerDel Lithium Power Think Projct
- Figure 5-9
- Sanyo Battery Targets 2020
- Figure 5-10
- Saft Sales Segments Half 1, 2008
- Figure 5-11
- Figure 5-12
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