Worldwide Nanotechnology Electric Vehicle (EV) Market Shares Strategies, and Forecasts, 2009 to 2015
Breakthrough technology in electric vehicles brings advancements that provide customers with personal transportation choices never before available. Electric vehicles are real. They come in a variety of styles and capabilities. The BMW features driving control and style. The Chinese BYD hybrid backed by Warren Buffet’s company has features that enable plug-in hybrid power train flexibility. It has a full battery-powered electric mode. The series-hybrid mode has an engine which drives a generator to recharge the batteries, acting as a rangeextender. There is a parallel hybrid mode, in which the engine and motor both provide propulsive power.
Electric vehicles represent a quantum shift in transportation. The design trajectories are varied; the opportunities are significant as a quantum shift occurs in what the vehicle basic functions are and how the vehicle works. The car companies that leverage the market opportunity to shift to a new paradyne are likely to succeed. There are others who merely try to migrate existing styles and designs to electric vehicles. Buggy whips come to mind.
The ability to plug a car into a hardened backyard set of batteries charged from a solar panel provides relief from gasoline spending. To have a second car, powered by a battery pack promises to provide growth of a new industry. The banks can loan against the car and the solar panel. Solar panels are evolving modular capability where they can be quickly installed and provide electricity for the car.
Investment in electric vehicle infrastructure is a priority. With countries seeking to invest in infrastructure that will provide economic growth, it is clear that special infrastructure for electric vehicles will stimulate growth from the private sector. Electric vehicle market segment is positioned for growth for vehicles used for local driving.
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.
Markets for electric vehicles at 685 units in 2008 are anticipated to reach 32.7 million autos shipped by 2015, growing in response to demand for a renewable energy powered vehicle that lowers the total cost of ownership by a significant amount. Lithium-ion batteries used in cell phones and PCs, and in cordless power tools are proving the technology to power electric vehicles. Early electric vehicles are being used as city cars, proving the feasibility of electric cars. Think in Norway has a viable manufacturing operation and 1,000 cars on the road. The large emerging markets are for hybrid and electric vehicles powered by renewable energy systems.
Electric vehicles represent a quantum shift in transportation. The design trajectories are varied; the opportunities are significant as a quantum shift occurs in what the vehicle basic functions are and how the vehicle works. The car companies that leverage the market opportunity to shift to a new paradyne are likely to succeed. There are others who merely try to migrate existing styles and designs to electric vehicles. Buggy whips come to mind.
The ability to plug a car into a hardened backyard set of batteries charged from a solar panel provides relief from gasoline spending. To have a second car, powered by a battery pack promises to provide growth of a new industry. The banks can loan against the car and the solar panel. Solar panels are evolving modular capability where they can be quickly installed and provide electricity for the car.
Investment in electric vehicle infrastructure is a priority. With countries seeking to invest in infrastructure that will provide economic growth, it is clear that special infrastructure for electric vehicles will stimulate growth from the private sector. Electric vehicle market segment is positioned for growth for vehicles used for local driving.
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.
Markets for electric vehicles at 685 units in 2008 are anticipated to reach 32.7 million autos shipped by 2015, growing in response to demand for a renewable energy powered vehicle that lowers the total cost of ownership by a significant amount. Lithium-ion batteries used in cell phones and PCs, and in cordless power tools are proving the technology to power electric vehicles. Early electric vehicles are being used as city cars, proving the feasibility of electric cars. Think in Norway has a viable manufacturing operation and 1,000 cars on the road. The large emerging markets are for hybrid and electric vehicles powered by renewable energy systems.
ELECTRIC VEHICLE MARKET SHARES AND MARKET FORECASTS
Electric Vehicle Design Trajectories
TH!NK City Safety Concept
Daimler
REVA Electric Car
Ford Advances Electric Vehicle Technology
Charging Electric Cars
Warren Buffet with Berkshire Hathaway Grou
Electric Vehicle Market Driving Forces
Electric Vehicle Market Shares
Electric Vehicle Economic Market Driving Forces
Nanotechnology Forms the Base for Lithium-Ion Batteries
Electric Vehicles Market Forecasts
Electric Vehicle Battery Recharging
Variety Of Electric Vehicle Initiatives
Think Overnight Power Top-Up
Think Significant Advancements In Battery Technology
1. ELECTRIC VEHICLE MARKET DESCRIPTION AND MARKET DYNAMICS
1.1 Auto Industry
1.1.1 Electric Vehicle Economic Forces
1.1.2 Cars Represent 20% Of The US Economic Retail Spending
1.1.3 Electric Vehicle Design Trajectories
1.2 Electric Vehicle EVs
1.2.1 EVs Cost Effective In City Conditions
1.2.2 Lithium-Ion Car Batteries
1.2.3 Private-Public Partnerships
1.3 Lithium-Ion Battery Target Markets
1.3.1 Project Better Place and the Renault-Nissan Alliance
1.3.2 Largest Target Market, The Transportation Industry
1.3.3 Electric Grid Services Market
1.3.4 Portable Power Market, Power Tools
1.4 Lithium-Ion Battery Technologies Transportation Industry Target Market
1.5 Energy Storage For Grid Stabilization
1.5.1 Local Energy Storage Benefit For Utilities
1.6 Applications Require On-Printed Circuit Board Battery Power
1.6.1 Thin-film vs. Printed Batteries
1.7 Smart Buildings
1.7.1 Permanent Power for Wireless Sensors
1.8 Battery Safety / Potential Hazards
1.9 Thin Film Solid-State Battery Construction
1.10 Battery Is Electrochemical Device
1.11 Battery Depends On Chemical Energy
1.11.1 Characteristics Of Battery Cells
1.11.2 Batteries Are Designed Differently For Various Applications
2. ELECTRIC VEHICLE MARKET SHARES AND MARKET FORECASTS
2.1 Electric Vehicle Economic Market Driving Forces
2.1.1 Nanotechnology Forms the Base for Lithium-Ion Batteries
2.1.2 Lithium-Ion Batteries
2.2 Electric Vehicle Market Shares
2.2.1 Daimler Safety Cell
2.2.2 Daimler Smart Car
2.2.3 BYD
2.2.4 Think Environmentally Friendly Vehicles
2.2.5 TH!NK City Safety Concept
2.2.6 Think Overnight Power Top-Up
2.2.7 GM Volt
2.2.8 GM Opel
2.2.9 Tesla Motors
2.2.10 i MiEV Electric Car by Mitsubishi
2.2.11 Mitsubishi
2.2.12 Subaru Selling EVs In Japan In 2009
2.2.13 BMW
2.2.14 REVA Electric Car
2.2.15 Ford Advances Electric Vehicle Technology
2.2.16 Ford Partnership With Utility Industry
2.2.17 Toyota Hybrid Prius
2.2.18 Nissan
2.2.19 Phoenix Motorcars
2.2.20 Fuji Heavy Industries / Subaru
2.2.21 Chrysler
2.3 Electric Vehicles Market Forecasts
2.4 Electric Vehicle Battery Recharging
2.4.1 Changing Electric Vehicles On The Fly
2.5 2008 / 2009 Auto Sales Overview
2.5.1 Korean Cars Succeed In US
2.5.2 Total Vehicles Sold / GM Profile
2.5.3 GM Global Vehicle Sales and Market Share – 2007
2.5.4 Worldwide Automotive Sales For 2007
2.5.5 Deepening Slowdown
2.6 Electric Vehicles As A Very Fancy Golf Cart
2.7 Worldwide Nanotechnology Thin Film Lithium-Ion Battery Market Driving Forces
2.7.1 Market Driving Forces
2.7.2 Nanotechnology Forms the Base for Lithium-Ion Batteries
2.7.3 Competitors
2.8 Lithium-Ion Battery Market Shares
2.8.1 ExxonMobil Affiliate in Japan / Tonen Chemical
2.8.2 A123Systems Patent for Nanophosphate™ Lithium Ion Battery Technology
2.9 Lithium-Ion Battery Market Forecasts
2.10 Electric Vehicle and Hybrid Vehicle Lithium-Ion Battery Market Shares
2.10.1 BYD
2.10.2 Johnson Controls-Saft
2.10.3 Saft Battery Technologies
2.10.4 A123Systems 32 Series Automotive Class Lithium Ion™ Cells:
2.10.5 NEC and Nissen
2.10.6 LG Chem
2.10.7 EnerDel
2.10.8 Competition
2.11 Electric and Hybrid Vehicle Lithium-Ion Battery Market Forecasts
2.11.1 Largest Target Market, The Transportation Industry
Thin Film Advanced Lithium-Ion Battery EV Market
Thin Film Lithium-Ion And Lithium Polymer Automotive Batteries
3. ELECTRIC VEHICLE PRODUCT DESCRIPTION
3.1 BMW
3.1.1 BMW Second Version Of The Electric Mini
3.2 BYD / MidAmerican Energy Holdings
3.2.1 Warren Buffet - MidAmerican, A Collection Of Electric Utilities In The Midwest
3.2.2 BYD Plug-in Hybrid Power Train Flexibility
3.2.3 BYD E6 Electric Car and F6
3.2.4 BYD E6 Electric Vehicle Specifications
3.3 Tesla Motors
3.3.1 Electric Roadster by Tesla Motors
3.3.2 Tesla Motors Next Generation Model S
3.3.3 Telsa Battery Pack And Frame
3.4 Daimler AG
3.4.1 Daimler Smart Car Model Features
3.4.2 Electric Car by Daimler Mercedes (2010)
3.5 Think
3.5.1 A123Systems / GE Production Contract for Norwegian Think Electric Vehicles
3.5.2 Think Overnight Power Top-Up
3.5.3 TH!NK City Safety Concept
3.5.4 TH!NK City Environmentally Friendly
3.5.5 Thinking Globally
3.6 General Motors
3.6.1 GM Volt
3.6.2 GM Challenge to Battery Developers
3.6.3 GM and A123Systems Co-Develop Lithium-Ion Battery Cell for Chevrolet Volt
3.6.4 GM Cadillac Electric Vehicle
3.6.5 GM / Opel
3.6.6 GM Chevrolet Equinox Fuel-Cell Vehicles
3.7 Miles XS500 Electric Car
3.8 Mitsubishi i MiEV Electric Car to be Sold 1 Year Ahead of Schedule in Japan
3.8.1 Mitsubishi i MiEV Electric Car Specifications
3.8.2 Mitsubishi i MiEV Electric Car Pricing
3.8.3 i MiEV Electric Car by Mitsubishi
3.8.4 Mitsubishi Electric Car i MiEV Coming to Europe
3.8.5 Mitsubishi Electric Car i MiEV Production Plans
3.8.6 i MiEV Electric Car Specifications
3.8.7 i MiEV Electric Car to be Sold 1 Year Ahead of Schedule
3.9 Fuji Heavy Industries / Subaru R1e Electric CarSource: Subaru.
3.9.1 Subaru Selling EVs In Japan In 2009
3.9.2 Subaru G4e Source: Subaru.
3.9.3 NEC / Fuji Heavy Industries / Subaru
3.9.4 NEC / Fuji Heavy Industries / Subaru Thin Film Battery Flat Shape
3.10 Electric Supercar by Hybrid Technologies
3.11 Electric Mini by PML
3.12 Electric Car by Nissan (2010-2012)
3.12.1 NEC / Nissan Low-Cost Lithium-Manganese Batteries
3.13 REVA Electric Car
3.14 Zenn Low Speed Electric Car
3.15 Commuter Cars Tango Electric Car
3.16 Eliica Electric Car by KEIO University
3.17 Wrightspeed X1 Electric Car
3.18 Saturn SP1 Electric Car Conversion by Students of Napoleon High School
3.19 Toyota Hybrid Prius
3.19.1 Toyota iQ Microcar
3.19.2 Toyota FT-EV Battery Electric Vehicle
3.20 Ford
3.21 Chrysler
3.21.1 Chrysler Town & Country EV
3.21.2 Chrysler Personal Mobility Revolution
3.21.3 Chrysler Dodge Circuit EV
3.21.4 Chrysler Jeep® Wrangler Unlimited EV
3.22 Phoenix
3.23 Shelby Supercars
3.24 Aptera
4. ELECTRIC VEHICLE TECHNOLOGY
4.1 Phoenix Motorcars Altairnano Lithium Titanate Battery Technology
4.1.1 Altairnano Battery Comparison
4.1.2 Lead-Acid Battery Technology
4.1.3 Nickel Metal Hydride (NiMH)
4.1.4 Lithium-Ion
4.2 Globalization Model For Electric Cars
4.2.1 Better Place Electric Vehicle Network
4.2.2 Better Place has partnered with AGL Energy in Australia
4.3 EFOY Pro Fuel Cell Electric Vehicle Charging Kit
4.3.1 Smart Fuel Cells SFC
4.3.2 Citycom AG’s CityEL
4.4 Vendor Lithium-ion Battery Strategy
4.4.1 Rechargeable Lithium Batteries Characteristics
4.5 Challenges in Battery Design
4.5.1 Advanced Lithium-ion Batteries Requirements
4.6 Vendor Lithium-Ion Battery Positioning
4.6.1 High-Quality, Volume Manufacturing Facilities
4.7 Applications Of Lithium-Ion Batteries
4.8 Mobile Phone Industry
4.8.1 Nanowires
4.8.2 Thin Film Battery Enabling Chemistries
4.8.3 The Cathodes
4.8.4 Solid State Devices Provide More Energy Density
4.9 Advantages of Lithium-Ion Batteries
4.9.1 Lithium-Ion Battery Shortcomings
4.9.2 Charging
4.9.3 Applications
4.9.4 Costs
4.10 Lithium Cell Chemistry Variants
4.10.1 Lithium-ion
4.10.2 Lithium-ion Polymer
4.10.3 Other Lithium Cathode Chemistry Variants
4.10.4 Lithium Cobalt LiCoO2
4.10.5 Lithium Manganese LiMn2O4
4.10.6 Lithium Nickel LiNiO2
4.10.7 Lithium (NCM) Nickel Cobal Manganese - Li(NiCoMn)O2
4.10.8 Lithium Iron Phosphate LiFePO4
4.11 Operating Performance Of The Cell Can Be Tuned
4.12 Lithium Metal Polymer
4.12.1 Lithium Sulphur Li2S8
4.12.2 Alternative Anode Chemistry
4.13 ExxonMobil affiliate, Tonen Chemical Polyethylene-Based, Porous Film
4.14 Cymbet Alternate Manufacturing
4.15 Thin-Film Batteries Packaging
4.16 ITN Energy Systems Fibrous Substrates, PowerFiber
4.16.1 ITN Sensors
4.17 Cell Construction
4.18 Impact Of Nanotechnology
4.19 Thin Film Batteries
4.19.1 Thin Film Battery Timescales and Costs
4.19.2 High Power And Energy Density
4.19.3 High Rate Capability
4.20 Comparison Of Rechargeable Battery Performance
4.21 Polymer Film Substrate
4.22 Micro Battery Solid Electrolyte
5. ELECTRIC VEHICLE COMPANY PROFILES
5.1 A123 Systems
5.1.1 A123 Systems Revenue
5.1.2 A123Systems Registration Statement for Initial Public Offering
5.1.3 A123 Systems Batteries Benefits
5.1.4 A123 Systems Competitive Advantage
5.1.5 A123 Systems Strategy
5.1.6 A123Systems and GE
5.1.7 A123 Acquisition of Hymotion
5.1.8 Procter & Gamble Duracell and A123 Systems Collaborate
5.1.9 Cobasys and A123 Systems
5.2 Aperta
5.3 Better Place Model
5.4 BMW
5.5 BYD
5.5.1 Warren Buffett Buys 10 Percent Stake In BYD Chinese Battery Manufacturer
5.6 E-One Moli Energy Group
5.7 Ener1
5.7.1 Ener1 Third Quarter 2008 Revenue
5.7.2 Ener1 Positioning Technology Originally Pioneered By Argonne National Lab
5.7.3 Ener1 Acquires Enertech Leading Korean Lithium-ion Battery Cell Producer
5.7.4 Ener1 / Enertech Specializes In Producing Large Format Flat ("Prismatic") Cells
5.7.5 EnerDel Operations
5.8 Ford
5.8.1 Ford Electric Vehicle Positioning
5.8.2 Ford’s Comprehensive Sustainability Strategy
5.8.3 Ford Partnership With Southern California Edison Electric Utility
5.8.4 Ford Partnership with Johnson Controls-Saft for Thin Film Batteries
5.8.5 Ford Partnership with Utility Industry
5.8.6 Building A Business Case
5.8.7 Governments Of Japan, China, Korea, And India Significantly Funding EV Research
5.8.8 Ford Energy Future Vision
5.9 Fuji Heavy Industries / Subaru
5.9.1 Subaru of America
5.9.2 Subaru of America Revenue 2008
5.10 General Motors
5.10.1 General Motors Factory In Michigan To Build Battery Packs
5.10.2 GM 2008 Global Sales of 8.35 Million Vehicles
5.10.3 GM Continues Growth in Emerging Markets
5.10.4 GM's North America Regional Performance
5.10.5 GM Europe
5.10.6 GM Strongly Believes In The Electrification Of The Automobile
5.11 Miles Electric Vehicles
5.11.1 Miles Zero Emissions, Full Electric Car
5.12 Johnson Controls-Saft
5.13 LG Petrochemical
5.13.1 LG Chem
5.14 Mitsubishi
5.14.1 Fleet Testing Of The Zero-Emissions iMiev Electric Vehicle
5.15 NEC / Nissan Low-Cost Lithium-Manganese Batteries
5.15.1 NEC Lamilion Energy
5.16 Panasonic / Sanyo
5.17 Phoenix Motorcars
5.17.1 Phoenix Motorcars Customers: Maui Electric
5.17.2 Phoenix MC All-Electric, Light-Duty Trucks
5.18 REVA
5.18.1 REVA Car Features
5.18.2 REVA Globally Tested Product
5.19 Saft
5.19.1 Saft Battery Technologies
5.19.2 Saft Industrial Battery Group (IBG)
5.19.3 Saft Specialty Battery Group (SBG)
5.19.4 Saft Rechargeable Battery Systems (RBS)
5.19.5 Saft Research and Development
5.19.6 Johnson Controls-Saft United States Advanced Battery Consortium (USABC)
5.20 Samsung
5.21 Shelby SuperCars
5.21.1 Sheffield International Finance Corporation
5.21.2 SSC Monthly Newsletter
5.22 Tesla Motors
5.22.1 Tesla Battery Packs
5.22.2 Tesla Roadster
5.22.3 Tesla Restructuring
5.23 Think
5.23.1 Think Manufacturing Capacity
5.23.2 Think Employees Called Back From Lay-Off
5.23.3 Think Confirms Interim Financing - Private Equity Firm Ener1 Group Is The Lead Investor
5.23.4 Kleiner Perkins And Rockport Capital, Two Leading Us Cleantech Investors Launch Joint Venture With Norwegian Electrical Vehicle Company Think
5.23.5 TH!NK city Crash-Tested And Highway-Certified EV
5.23.6 Think Strategic Partnership With Energy Giant General Electric
5.23.7 Think collaboration with Porsche Consulting
5.24 Toyota
5.25 ZENN Motor Company
5.25.1 Zenn Motor Strategic Energy Storage Partner, Eestor
Electric Vehicle Design Trajectories
TH!NK City Safety Concept
Daimler
REVA Electric Car
Ford Advances Electric Vehicle Technology
Charging Electric Cars
Warren Buffet with Berkshire Hathaway Grou
Electric Vehicle Market Driving Forces
Electric Vehicle Market Shares
Electric Vehicle Economic Market Driving Forces
Nanotechnology Forms the Base for Lithium-Ion Batteries
Electric Vehicles Market Forecasts
Electric Vehicle Battery Recharging
Variety Of Electric Vehicle Initiatives
Think Overnight Power Top-Up
Think Significant Advancements In Battery Technology
1. ELECTRIC VEHICLE MARKET DESCRIPTION AND MARKET DYNAMICS
1.1 Auto Industry
1.1.1 Electric Vehicle Economic Forces
1.1.2 Cars Represent 20% Of The US Economic Retail Spending
1.1.3 Electric Vehicle Design Trajectories
1.2 Electric Vehicle EVs
1.2.1 EVs Cost Effective In City Conditions
1.2.2 Lithium-Ion Car Batteries
1.2.3 Private-Public Partnerships
1.3 Lithium-Ion Battery Target Markets
1.3.1 Project Better Place and the Renault-Nissan Alliance
1.3.2 Largest Target Market, The Transportation Industry
1.3.3 Electric Grid Services Market
1.3.4 Portable Power Market, Power Tools
1.4 Lithium-Ion Battery Technologies Transportation Industry Target Market
1.5 Energy Storage For Grid Stabilization
1.5.1 Local Energy Storage Benefit For Utilities
1.6 Applications Require On-Printed Circuit Board Battery Power
1.6.1 Thin-film vs. Printed Batteries
1.7 Smart Buildings
1.7.1 Permanent Power for Wireless Sensors
1.8 Battery Safety / Potential Hazards
1.9 Thin Film Solid-State Battery Construction
1.10 Battery Is Electrochemical Device
1.11 Battery Depends On Chemical Energy
1.11.1 Characteristics Of Battery Cells
1.11.2 Batteries Are Designed Differently For Various Applications
2. ELECTRIC VEHICLE MARKET SHARES AND MARKET FORECASTS
2.1 Electric Vehicle Economic Market Driving Forces
2.1.1 Nanotechnology Forms the Base for Lithium-Ion Batteries
2.1.2 Lithium-Ion Batteries
2.2 Electric Vehicle Market Shares
2.2.1 Daimler Safety Cell
2.2.2 Daimler Smart Car
2.2.3 BYD
2.2.4 Think Environmentally Friendly Vehicles
2.2.5 TH!NK City Safety Concept
2.2.6 Think Overnight Power Top-Up
2.2.7 GM Volt
2.2.8 GM Opel
2.2.9 Tesla Motors
2.2.10 i MiEV Electric Car by Mitsubishi
2.2.11 Mitsubishi
2.2.12 Subaru Selling EVs In Japan In 2009
2.2.13 BMW
2.2.14 REVA Electric Car
2.2.15 Ford Advances Electric Vehicle Technology
2.2.16 Ford Partnership With Utility Industry
2.2.17 Toyota Hybrid Prius
2.2.18 Nissan
2.2.19 Phoenix Motorcars
2.2.20 Fuji Heavy Industries / Subaru
2.2.21 Chrysler
2.3 Electric Vehicles Market Forecasts
2.4 Electric Vehicle Battery Recharging
2.4.1 Changing Electric Vehicles On The Fly
2.5 2008 / 2009 Auto Sales Overview
2.5.1 Korean Cars Succeed In US
2.5.2 Total Vehicles Sold / GM Profile
2.5.3 GM Global Vehicle Sales and Market Share – 2007
2.5.4 Worldwide Automotive Sales For 2007
2.5.5 Deepening Slowdown
2.6 Electric Vehicles As A Very Fancy Golf Cart
2.7 Worldwide Nanotechnology Thin Film Lithium-Ion Battery Market Driving Forces
2.7.1 Market Driving Forces
2.7.2 Nanotechnology Forms the Base for Lithium-Ion Batteries
2.7.3 Competitors
2.8 Lithium-Ion Battery Market Shares
2.8.1 ExxonMobil Affiliate in Japan / Tonen Chemical
2.8.2 A123Systems Patent for Nanophosphate™ Lithium Ion Battery Technology
2.9 Lithium-Ion Battery Market Forecasts
2.10 Electric Vehicle and Hybrid Vehicle Lithium-Ion Battery Market Shares
2.10.1 BYD
2.10.2 Johnson Controls-Saft
2.10.3 Saft Battery Technologies
2.10.4 A123Systems 32 Series Automotive Class Lithium Ion™ Cells:
2.10.5 NEC and Nissen
2.10.6 LG Chem
2.10.7 EnerDel
2.10.8 Competition
2.11 Electric and Hybrid Vehicle Lithium-Ion Battery Market Forecasts
2.11.1 Largest Target Market, The Transportation Industry
Thin Film Advanced Lithium-Ion Battery EV Market
Thin Film Lithium-Ion And Lithium Polymer Automotive Batteries
3. ELECTRIC VEHICLE PRODUCT DESCRIPTION
3.1 BMW
3.1.1 BMW Second Version Of The Electric Mini
3.2 BYD / MidAmerican Energy Holdings
3.2.1 Warren Buffet - MidAmerican, A Collection Of Electric Utilities In The Midwest
3.2.2 BYD Plug-in Hybrid Power Train Flexibility
3.2.3 BYD E6 Electric Car and F6
3.2.4 BYD E6 Electric Vehicle Specifications
3.3 Tesla Motors
3.3.1 Electric Roadster by Tesla Motors
3.3.2 Tesla Motors Next Generation Model S
3.3.3 Telsa Battery Pack And Frame
3.4 Daimler AG
3.4.1 Daimler Smart Car Model Features
3.4.2 Electric Car by Daimler Mercedes (2010)
3.5 Think
3.5.1 A123Systems / GE Production Contract for Norwegian Think Electric Vehicles
3.5.2 Think Overnight Power Top-Up
3.5.3 TH!NK City Safety Concept
3.5.4 TH!NK City Environmentally Friendly
3.5.5 Thinking Globally
3.6 General Motors
3.6.1 GM Volt
3.6.2 GM Challenge to Battery Developers
3.6.3 GM and A123Systems Co-Develop Lithium-Ion Battery Cell for Chevrolet Volt
3.6.4 GM Cadillac Electric Vehicle
3.6.5 GM / Opel
3.6.6 GM Chevrolet Equinox Fuel-Cell Vehicles
3.7 Miles XS500 Electric Car
3.8 Mitsubishi i MiEV Electric Car to be Sold 1 Year Ahead of Schedule in Japan
3.8.1 Mitsubishi i MiEV Electric Car Specifications
3.8.2 Mitsubishi i MiEV Electric Car Pricing
3.8.3 i MiEV Electric Car by Mitsubishi
3.8.4 Mitsubishi Electric Car i MiEV Coming to Europe
3.8.5 Mitsubishi Electric Car i MiEV Production Plans
3.8.6 i MiEV Electric Car Specifications
3.8.7 i MiEV Electric Car to be Sold 1 Year Ahead of Schedule
3.9 Fuji Heavy Industries / Subaru R1e Electric CarSource: Subaru.
3.9.1 Subaru Selling EVs In Japan In 2009
3.9.2 Subaru G4e Source: Subaru.
3.9.3 NEC / Fuji Heavy Industries / Subaru
3.9.4 NEC / Fuji Heavy Industries / Subaru Thin Film Battery Flat Shape
3.10 Electric Supercar by Hybrid Technologies
3.11 Electric Mini by PML
3.12 Electric Car by Nissan (2010-2012)
3.12.1 NEC / Nissan Low-Cost Lithium-Manganese Batteries
3.13 REVA Electric Car
3.14 Zenn Low Speed Electric Car
3.15 Commuter Cars Tango Electric Car
3.16 Eliica Electric Car by KEIO University
3.17 Wrightspeed X1 Electric Car
3.18 Saturn SP1 Electric Car Conversion by Students of Napoleon High School
3.19 Toyota Hybrid Prius
3.19.1 Toyota iQ Microcar
3.19.2 Toyota FT-EV Battery Electric Vehicle
3.20 Ford
3.21 Chrysler
3.21.1 Chrysler Town & Country EV
3.21.2 Chrysler Personal Mobility Revolution
3.21.3 Chrysler Dodge Circuit EV
3.21.4 Chrysler Jeep® Wrangler Unlimited EV
3.22 Phoenix
3.23 Shelby Supercars
3.24 Aptera
4. ELECTRIC VEHICLE TECHNOLOGY
4.1 Phoenix Motorcars Altairnano Lithium Titanate Battery Technology
4.1.1 Altairnano Battery Comparison
4.1.2 Lead-Acid Battery Technology
4.1.3 Nickel Metal Hydride (NiMH)
4.1.4 Lithium-Ion
4.2 Globalization Model For Electric Cars
4.2.1 Better Place Electric Vehicle Network
4.2.2 Better Place has partnered with AGL Energy in Australia
4.3 EFOY Pro Fuel Cell Electric Vehicle Charging Kit
4.3.1 Smart Fuel Cells SFC
4.3.2 Citycom AG’s CityEL
4.4 Vendor Lithium-ion Battery Strategy
4.4.1 Rechargeable Lithium Batteries Characteristics
4.5 Challenges in Battery Design
4.5.1 Advanced Lithium-ion Batteries Requirements
4.6 Vendor Lithium-Ion Battery Positioning
4.6.1 High-Quality, Volume Manufacturing Facilities
4.7 Applications Of Lithium-Ion Batteries
4.8 Mobile Phone Industry
4.8.1 Nanowires
4.8.2 Thin Film Battery Enabling Chemistries
4.8.3 The Cathodes
4.8.4 Solid State Devices Provide More Energy Density
4.9 Advantages of Lithium-Ion Batteries
4.9.1 Lithium-Ion Battery Shortcomings
4.9.2 Charging
4.9.3 Applications
4.9.4 Costs
4.10 Lithium Cell Chemistry Variants
4.10.1 Lithium-ion
4.10.2 Lithium-ion Polymer
4.10.3 Other Lithium Cathode Chemistry Variants
4.10.4 Lithium Cobalt LiCoO2
4.10.5 Lithium Manganese LiMn2O4
4.10.6 Lithium Nickel LiNiO2
4.10.7 Lithium (NCM) Nickel Cobal Manganese - Li(NiCoMn)O2
4.10.8 Lithium Iron Phosphate LiFePO4
4.11 Operating Performance Of The Cell Can Be Tuned
4.12 Lithium Metal Polymer
4.12.1 Lithium Sulphur Li2S8
4.12.2 Alternative Anode Chemistry
4.13 ExxonMobil affiliate, Tonen Chemical Polyethylene-Based, Porous Film
4.14 Cymbet Alternate Manufacturing
4.15 Thin-Film Batteries Packaging
4.16 ITN Energy Systems Fibrous Substrates, PowerFiber
4.16.1 ITN Sensors
4.17 Cell Construction
4.18 Impact Of Nanotechnology
4.19 Thin Film Batteries
4.19.1 Thin Film Battery Timescales and Costs
4.19.2 High Power And Energy Density
4.19.3 High Rate Capability
4.20 Comparison Of Rechargeable Battery Performance
4.21 Polymer Film Substrate
4.22 Micro Battery Solid Electrolyte
5. ELECTRIC VEHICLE COMPANY PROFILES
5.1 A123 Systems
5.1.1 A123 Systems Revenue
5.1.2 A123Systems Registration Statement for Initial Public Offering
5.1.3 A123 Systems Batteries Benefits
5.1.4 A123 Systems Competitive Advantage
5.1.5 A123 Systems Strategy
5.1.6 A123Systems and GE
5.1.7 A123 Acquisition of Hymotion
5.1.8 Procter & Gamble Duracell and A123 Systems Collaborate
5.1.9 Cobasys and A123 Systems
5.2 Aperta
5.3 Better Place Model
5.4 BMW
5.5 BYD
5.5.1 Warren Buffett Buys 10 Percent Stake In BYD Chinese Battery Manufacturer
5.6 E-One Moli Energy Group
5.7 Ener1
5.7.1 Ener1 Third Quarter 2008 Revenue
5.7.2 Ener1 Positioning Technology Originally Pioneered By Argonne National Lab
5.7.3 Ener1 Acquires Enertech Leading Korean Lithium-ion Battery Cell Producer
5.7.4 Ener1 / Enertech Specializes In Producing Large Format Flat ("Prismatic") Cells
5.7.5 EnerDel Operations
5.8 Ford
5.8.1 Ford Electric Vehicle Positioning
5.8.2 Ford’s Comprehensive Sustainability Strategy
5.8.3 Ford Partnership With Southern California Edison Electric Utility
5.8.4 Ford Partnership with Johnson Controls-Saft for Thin Film Batteries
5.8.5 Ford Partnership with Utility Industry
5.8.6 Building A Business Case
5.8.7 Governments Of Japan, China, Korea, And India Significantly Funding EV Research
5.8.8 Ford Energy Future Vision
5.9 Fuji Heavy Industries / Subaru
5.9.1 Subaru of America
5.9.2 Subaru of America Revenue 2008
5.10 General Motors
5.10.1 General Motors Factory In Michigan To Build Battery Packs
5.10.2 GM 2008 Global Sales of 8.35 Million Vehicles
5.10.3 GM Continues Growth in Emerging Markets
5.10.4 GM's North America Regional Performance
5.10.5 GM Europe
5.10.6 GM Strongly Believes In The Electrification Of The Automobile
5.11 Miles Electric Vehicles
5.11.1 Miles Zero Emissions, Full Electric Car
5.12 Johnson Controls-Saft
5.13 LG Petrochemical
5.13.1 LG Chem
5.14 Mitsubishi
5.14.1 Fleet Testing Of The Zero-Emissions iMiev Electric Vehicle
5.15 NEC / Nissan Low-Cost Lithium-Manganese Batteries
5.15.1 NEC Lamilion Energy
5.16 Panasonic / Sanyo
5.17 Phoenix Motorcars
5.17.1 Phoenix Motorcars Customers: Maui Electric
5.17.2 Phoenix MC All-Electric, Light-Duty Trucks
5.18 REVA
5.18.1 REVA Car Features
5.18.2 REVA Globally Tested Product
5.19 Saft
5.19.1 Saft Battery Technologies
5.19.2 Saft Industrial Battery Group (IBG)
5.19.3 Saft Specialty Battery Group (SBG)
5.19.4 Saft Rechargeable Battery Systems (RBS)
5.19.5 Saft Research and Development
5.19.6 Johnson Controls-Saft United States Advanced Battery Consortium (USABC)
5.20 Samsung
5.21 Shelby SuperCars
5.21.1 Sheffield International Finance Corporation
5.21.2 SSC Monthly Newsletter
5.22 Tesla Motors
5.22.1 Tesla Battery Packs
5.22.2 Tesla Roadster
5.22.3 Tesla Restructuring
5.23 Think
5.23.1 Think Manufacturing Capacity
5.23.2 Think Employees Called Back From Lay-Off
5.23.3 Think Confirms Interim Financing - Private Equity Firm Ener1 Group Is The Lead Investor
5.23.4 Kleiner Perkins And Rockport Capital, Two Leading Us Cleantech Investors Launch Joint Venture With Norwegian Electrical Vehicle Company Think
5.23.5 TH!NK city Crash-Tested And Highway-Certified EV
5.23.6 Think Strategic Partnership With Energy Giant General Electric
5.23.7 Think collaboration with Porsche Consulting
5.24 Toyota
5.25 ZENN Motor Company
5.25.1 Zenn Motor Strategic Energy Storage Partner, Eestor
LIST OF TABLES AND FIGURES
Figure ES-1
Aptera Pre-Production Model 2e
Figure ES-2
REVA Electric Car
Table ES-3
Electric Vehicle Market Driving Forces
Table ES-3 (Continued)
Electric Vehicle Market Driving Forces
Figure ES-4
Worldwide Electric Vehicles
On The Road Market Shares, Units, 2009
Figure ES-5
Worldwide Electric Vehicle Penetration of
Automotive and Light Truck Market Forecasts, Percent,
2009-2015
Figure ES-6
Worldwide Electric Vehicle Retail Forecasts, Dollars,
2009-2015
Table ES-7
Reasons For Aggressive Forecast For Electric Vehicle Markets
Table ES-7 (Continued)
Reasons For Aggressive Forecast For Electric Vehicle Markets
Table ES-8
New Infrastructure, New Driving Modalities Brought By
Electric Vehicles
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
Table 2-1
Lithium-Ion Battery Market Driving Forces
Table 2-2
Energy Advantages Of Thin-Film Batteries
Figure 2-3
Aptera Pre-Production Model 2e
Table 2-4
Electric Vehicle Market Driving Forces
Table 2-4 (Continued)
Electric Vehicle Market Driving Forces
Figure 2-5
Worldwide Electric Vehicles
On The Road Market Shares, Units, 2009
Table 2-6
Worldwide Electric Vehicle Shipments Market Shares,
Units On the Road 2009
Figure 2-7
i MiEV Electric Car by Mitsubishi - Red
Figure 2-8
REVA Electric Car
Figure 2-9
Worldwide Electric Vehicle Penetration of Automotive
and Light Truck Market Forecasts, Percent,
2009-2015
Table 2-10
Worldwide Electric Vehicle (EV) Unit Shipments
and Automotive Market Retail Forecasts and
Penetration Analysis, 2009-2015
Figure 2-11
Worldwide Electric Vehicle Retail Forecasts, Dollars,
2009-2015
Table 2-12
Worldwide Electric Vehicle (EV) Unit Shipments
and Automotive Market Retail Forecasts and
Penetration Analysis, 2009-2015
Table 2-13
Worldwide Electric Vehicle (EV) Unit Shipments
and Automotive Market Retail Forecasts, Penetration Analysis,
2009-2015
Table 2-14
Worldwide Automotive and Light Truck Small
Size Electric Vehicle (EV) Market Forecasts, Dollars, 2009-2015
Table 2-15
Worldwide Small Electric Vehicle (EV) Market
Forecasts, Units, 2009-2015
Table 2-16
Worldwide Small Car and Small Light Truck Electric
Vehicle (EV) Automotive Market Retail Forecasts,
Units and Dollars, 2009-2015
Table 2-17
Worldwide Sedan Size Automotive and Light Truck
Electric Vehicle (EV) Retail Market Forecasts, Dollars, 2009-2015
Table 2-18
Worldwide Sedan Size Automotive and Light Truck
Electric Vehicle (EV) Shipments Retail Market Forecasts, Units,
2009-2015
Table 2-19
Worldwide Sedan Size Car and Light Truck Electric
Vehicle (EV) Unit Shipments and Automotive Market
Retail Forecasts, Units and Dollars, 2009-201
Table 2-20
Reasons For Aggressive Forecast For Electric Vehicle Markets
Table 2-21
New Infrastructure, New Driving Modalities Brought By
Electric Vehicles
Table 2-22
Lithium-Ion Battery Market Driving Forces
Table 2-23
Energy Advantages Of Thin-Film Batteries
Figure 2-24
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2008
Table 2-25
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2008
Figure 2-26
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2009-2015
Figure 2-27
Worldwide Lithium-Ion and Advanced Lithium-ion
Battery Market Forecasts, Automotive, Power Tools,
Electric Grid, and PC Card, Dollars, 2009-2015
Figure 2-28
Worldwide Lithium-Ion Thin Film Automotive Advanced Battery
Shipments, Market Shares, Dollars, 2008
Figure 2-29
Worldwide Lithium-Ion Thin Film Automotive Advanced Battery
Shipments, Market Shares, Dollars, 2008
Figure 2-30
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2009-2015
Figure 2-31
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Units, 2009-2015
Figure 2-32
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Units and Dollars, 2009-2015
Table 2-33
Commercialization Challenges Of The Automotive,
Truck, and Bus Thin Film Battery Industry
Table 2-34
Integrated Thin Film Battery Personal Transport Power Systems
Figure 3-1
BMW’S Mini E Electric Car Powered By A Rechargeable
Lithium-Ion Battery
Figure 3-2
BYD E6 Electric Car
Figure 3-3
BYD F3DM Front View
Figure 3-4
BYD F3DM Rear View
Figure 3-5
BYD F3 Moon Roof
Table 3-6
BYD Plug-in Hybrid Powertrain Flexibility
Figure 3-7
BYD E6 Electric Car
Figure 3-8
BYD F6
Figure 3-9
Tesla Motors Roadster
Figure 3-10
Tesla Motors Roadster Torque and Power Graph
Figure 3-11
Model S by Tesla Motors
Figure 3-12
Daimler AG Smart car
Figure 3-13
Daimler Smart Car
Figure 3-14
Daimler Electric Mercedes
Figure 3-15
Prince Albert of Monaco Driving TH!NK city
Figure 3-16
Driving TH!NK city
Figure 3-17
Think Driver Console
Figure 3-18
Think Open
Figure 3-19
Think OX
Figure 3-20
Think City Electric Vehicle
Table 3-21
TH!NK City Specifications
Table 3-22
Think City Standard Equipment:
Table 3-22 (Continued)
Think City Standard Equipment:
Table 3-23
TH!NK City Features
Figure 3-24
Think Lineup of Electric Cars
Figure 3-25
General Motors Chevrolet Volt – Front View
Figure 3-26
General Motors Chevrolet Volt - Angle View
Figure 3-27
General Motors Chevrolet Volt - Rear View
Figure 3-28
General Motors Chevrolet Volt
Figure 3-29
GM Cadillac Electric Vehicle
Figure 3-30
General Motors EV1 Electric Car
Figure 3-31
XS500 Electric Car by Miles
Figure 3-32
i MiEV Electric Car by Mitsubishi - In Traffic
Figure 3-33
i MiEV Electric Car by Mitsubishi - Battery Packaging
Figure 3-34
i MiEV Electric Car by Mitsubishi - Red
Figure 3-35
i MiEV Electric Car by Mitsubishi - Gray
Figure 3-36
i MiEV Electric Car by Mitsubishi - Interior
Figure 3-37
i MiEV Electric Car by Mitsubishi - Features
Figure 3-38
Mitsubishi I Miev Electric Car
Figure 3-39
Mitsubishi I Miev Electric Car Interior Engine and
Drive Train Layout
Figure 3-40
Fuji Heavy Industries / Subaru R1e Electric Car
Figure 3-41
Subaru R1e Electric Car Plug Station
Figure 3-42
Subaru G4e Electric Car
Figure 3-43
Hybrid Technologies Electric Supercar
Figure 3-44
Electric Mini by PML
Figure 3-45
Test Electric Car by Nissan
Figure 3-46
REVA Electric Car
Figure 3-47
Zenn Auto
Figure 3-48
Zenn Electric Auto Close-up
Figure 3-49
Zenn Auto Parked in Street
Figure 3-50
Zenn Electric Auto – Gray with Sun Roof
Figure 3-51
Commuter Cars Tango Electric Car
Figure 3-52
Commuter Cars Tango in Washington DC
Figure 3-53
Eliica Electric Car
Figure 3-54
Wrightspeed X1 Electric Car
Figure 3-55
Saturn SP1 Electric Car Conversion
Figure 3-56
Toyota Hybrid Prius
Figure 3-57
Toyota FT-EV Battery Electric Vehicle
Figure 3-58
Toyota Electric Car
Table 3-59
Chrysler ENVI Electric Minivan Features
Figure 3-60
Interior of The Concept Car, The Chrysler 200C EV
Table 3-61
Chrysler Electric Vehicle Positioning
Table 3-62
Chrysler Electric Vehicle EV
Figure 3-63
Chrysler Electric Vehicles
Figure 3-64
Dodge Circuit EV
Table 3-65
Dodge Circuit EV Features
Figure 3-66
Chrysler Jeep® Wrangler Unlimited EV
Figure 3-67
Jeep® Wrangler Unlimited EV Features
Figure 3-68
Phoenix Motorcars SUT Truck
Figure 3-69
Phoenix Motorcars SUV Vehicle
Figure 3-70
Shelby Supercars
Figure 3-71
Shelby Supercars - Doors Raised
Figure 3-72
Aptera Pre-Production Model 2e
Figure 3-73
Aptera 2e Pre-Production Models
Figure 3-74
Aperta Three Wheel Vehicle
Figure 3-75
Aperta Three Wheel Vehicle - Rear View
Figure 4-1
Altairnano Battery Performance:
Figure 4-2
EFOY Pro Fuel Cell Kit For Electric Vehicles
Figure 4-3
Electrica City Car - Red
Figure 4-4
Electrica City Car - Yellow
Figure 4-5
Electrica City Car - Open
Figure 4-6
Electrica City Car - Dashboard
Figure 4-7
Smart Fuel Cells (SFC) Supply The StartLab Open With Power
Table 4-8
Challenges in Lithium-ion Battery Design
Table 4-9
Advantages of Lithium-Ion Batteries
Source: ITN.
Table 4-10
Thin Film Battery Unique Properties
Table 4-11
Comparison of battery performances
Table 4-12
Comparison Of Battery Performances
Table 4-13
Thin Films For Advanced Batteries
Table 4-14
Thin Film Batteries Technology
Table 4-15
Thin Film Battery / Lithium Air Batteries Applications
Figure 4-16
Polymer Film Substrate Thin Flexible Battery Profiles
Figure 4-17
Design Alternatives of Thin Film Rechargable Batteries
Table 5-1
A123 Systems Batteries Benefits
Table 5-2
A123 Systems Competitive Positioning
Table 5-2 (Continued)
A123 Systems Competitive Positioning
Table 5-2 (Continued)
A123 Systems Competitive Positioning
Figure 5-3
Aptera Vehicle Early Drawings
Figure 5-4
Assembly Facility: Vista, CA
Figure 5-5
Aperta Composite Facility: Carlsbad, CA
Figure 5-6
EnerDel Operations
Figure 5-7
EnerDel Lithium Power Systems
Figure 5-8
EnerDel Lithium Power USABC Contracts
Figure 5-9
EnerDel Lithium Power Think Projct
Table 5-10
Ford Key Government Energy Actions Recommendations
Figure 5-11
Sanyo Battery Targets 2020
Figure 5-12
REVA Electric Car
Figure 5-13
Saft Revenue H1 2008
Figure 5-14
Shelby Supercars
Figure 5-15
Think Auto Production Facility
Figure 5-16
TH!NK North America
Figure 5-17
Toyota Consolidated Vehicle Sales
Figure 5-18
Toyota Strategy
Figure 5-19
Toyota Car
COMPANIES PROFILED
Tesla Motors
Daimler AG
Think
General Motors
BMW
BYD / MidAmerican Energy Holdings
Miles XS500 Electric Car
A123 Systems
Aperta
Better Place Model
E-One Moli Energy Group
Ener1 / Enertech
EnerDel Operations
LG Petrochemical
Panasonic / Sanyo
Saft
Mitsubishi i MiEV Electric Car
NEC / Fuji Heavy Industries / Subaru
NEC / Nissan
REVA Electric Car
Zenn Low Speed Electric Car
Ford
Shelby Supercars
Samsung
Electric Supercar by Hybrid Technologies
Electric Mini by PML
Commuter Cars Tango Electric Car
Eliica Electric Car by KEIO University
Wrightspeed X1 Electric Car
Toyota Hybrid Prius
Chrysler
Phoenix
Aptera
Figure ES-1
Aptera Pre-Production Model 2e
Figure ES-2
REVA Electric Car
Table ES-3
Electric Vehicle Market Driving Forces
Table ES-3 (Continued)
Electric Vehicle Market Driving Forces
Figure ES-4
Worldwide Electric Vehicles
On The Road Market Shares, Units, 2009
Figure ES-5
Worldwide Electric Vehicle Penetration of
Automotive and Light Truck Market Forecasts, Percent,
2009-2015
Figure ES-6
Worldwide Electric Vehicle Retail Forecasts, Dollars,
2009-2015
Table ES-7
Reasons For Aggressive Forecast For Electric Vehicle Markets
Table ES-7 (Continued)
Reasons For Aggressive Forecast For Electric Vehicle Markets
Table ES-8
New Infrastructure, New Driving Modalities Brought By
Electric Vehicles
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
Table 2-1
Lithium-Ion Battery Market Driving Forces
Table 2-2
Energy Advantages Of Thin-Film Batteries
Figure 2-3
Aptera Pre-Production Model 2e
Table 2-4
Electric Vehicle Market Driving Forces
Table 2-4 (Continued)
Electric Vehicle Market Driving Forces
Figure 2-5
Worldwide Electric Vehicles
On The Road Market Shares, Units, 2009
Table 2-6
Worldwide Electric Vehicle Shipments Market Shares,
Units On the Road 2009
Figure 2-7
i MiEV Electric Car by Mitsubishi - Red
Figure 2-8
REVA Electric Car
Figure 2-9
Worldwide Electric Vehicle Penetration of Automotive
and Light Truck Market Forecasts, Percent,
2009-2015
Table 2-10
Worldwide Electric Vehicle (EV) Unit Shipments
and Automotive Market Retail Forecasts and
Penetration Analysis, 2009-2015
Figure 2-11
Worldwide Electric Vehicle Retail Forecasts, Dollars,
2009-2015
Table 2-12
Worldwide Electric Vehicle (EV) Unit Shipments
and Automotive Market Retail Forecasts and
Penetration Analysis, 2009-2015
Table 2-13
Worldwide Electric Vehicle (EV) Unit Shipments
and Automotive Market Retail Forecasts, Penetration Analysis,
2009-2015
Table 2-14
Worldwide Automotive and Light Truck Small
Size Electric Vehicle (EV) Market Forecasts, Dollars, 2009-2015
Table 2-15
Worldwide Small Electric Vehicle (EV) Market
Forecasts, Units, 2009-2015
Table 2-16
Worldwide Small Car and Small Light Truck Electric
Vehicle (EV) Automotive Market Retail Forecasts,
Units and Dollars, 2009-2015
Table 2-17
Worldwide Sedan Size Automotive and Light Truck
Electric Vehicle (EV) Retail Market Forecasts, Dollars, 2009-2015
Table 2-18
Worldwide Sedan Size Automotive and Light Truck
Electric Vehicle (EV) Shipments Retail Market Forecasts, Units,
2009-2015
Table 2-19
Worldwide Sedan Size Car and Light Truck Electric
Vehicle (EV) Unit Shipments and Automotive Market
Retail Forecasts, Units and Dollars, 2009-201
Table 2-20
Reasons For Aggressive Forecast For Electric Vehicle Markets
Table 2-21
New Infrastructure, New Driving Modalities Brought By
Electric Vehicles
Table 2-22
Lithium-Ion Battery Market Driving Forces
Table 2-23
Energy Advantages Of Thin-Film Batteries
Figure 2-24
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2008
Table 2-25
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2008
Figure 2-26
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2009-2015
Figure 2-27
Worldwide Lithium-Ion and Advanced Lithium-ion
Battery Market Forecasts, Automotive, Power Tools,
Electric Grid, and PC Card, Dollars, 2009-2015
Figure 2-28
Worldwide Lithium-Ion Thin Film Automotive Advanced Battery
Shipments, Market Shares, Dollars, 2008
Figure 2-29
Worldwide Lithium-Ion Thin Film Automotive Advanced Battery
Shipments, Market Shares, Dollars, 2008
Figure 2-30
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Dollars, 2009-2015
Figure 2-31
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Units, 2009-2015
Figure 2-32
Worldwide Lithium-Ion Thin Film Advanced Battery
Shipments, Market Shares, Units and Dollars, 2009-2015
Table 2-33
Commercialization Challenges Of The Automotive,
Truck, and Bus Thin Film Battery Industry
Table 2-34
Integrated Thin Film Battery Personal Transport Power Systems
Figure 3-1
BMW’S Mini E Electric Car Powered By A Rechargeable
Lithium-Ion Battery
Figure 3-2
BYD E6 Electric Car
Figure 3-3
BYD F3DM Front View
Figure 3-4
BYD F3DM Rear View
Figure 3-5
BYD F3 Moon Roof
Table 3-6
BYD Plug-in Hybrid Powertrain Flexibility
Figure 3-7
BYD E6 Electric Car
Figure 3-8
BYD F6
Figure 3-9
Tesla Motors Roadster
Figure 3-10
Tesla Motors Roadster Torque and Power Graph
Figure 3-11
Model S by Tesla Motors
Figure 3-12
Daimler AG Smart car
Figure 3-13
Daimler Smart Car
Figure 3-14
Daimler Electric Mercedes
Figure 3-15
Prince Albert of Monaco Driving TH!NK city
Figure 3-16
Driving TH!NK city
Figure 3-17
Think Driver Console
Figure 3-18
Think Open
Figure 3-19
Think OX
Figure 3-20
Think City Electric Vehicle
Table 3-21
TH!NK City Specifications
Table 3-22
Think City Standard Equipment:
Table 3-22 (Continued)
Think City Standard Equipment:
Table 3-23
TH!NK City Features
Figure 3-24
Think Lineup of Electric Cars
Figure 3-25
General Motors Chevrolet Volt – Front View
Figure 3-26
General Motors Chevrolet Volt - Angle View
Figure 3-27
General Motors Chevrolet Volt - Rear View
Figure 3-28
General Motors Chevrolet Volt
Figure 3-29
GM Cadillac Electric Vehicle
Figure 3-30
General Motors EV1 Electric Car
Figure 3-31
XS500 Electric Car by Miles
Figure 3-32
i MiEV Electric Car by Mitsubishi - In Traffic
Figure 3-33
i MiEV Electric Car by Mitsubishi - Battery Packaging
Figure 3-34
i MiEV Electric Car by Mitsubishi - Red
Figure 3-35
i MiEV Electric Car by Mitsubishi - Gray
Figure 3-36
i MiEV Electric Car by Mitsubishi - Interior
Figure 3-37
i MiEV Electric Car by Mitsubishi - Features
Figure 3-38
Mitsubishi I Miev Electric Car
Figure 3-39
Mitsubishi I Miev Electric Car Interior Engine and
Drive Train Layout
Figure 3-40
Fuji Heavy Industries / Subaru R1e Electric Car
Figure 3-41
Subaru R1e Electric Car Plug Station
Figure 3-42
Subaru G4e Electric Car
Figure 3-43
Hybrid Technologies Electric Supercar
Figure 3-44
Electric Mini by PML
Figure 3-45
Test Electric Car by Nissan
Figure 3-46
REVA Electric Car
Figure 3-47
Zenn Auto
Figure 3-48
Zenn Electric Auto Close-up
Figure 3-49
Zenn Auto Parked in Street
Figure 3-50
Zenn Electric Auto – Gray with Sun Roof
Figure 3-51
Commuter Cars Tango Electric Car
Figure 3-52
Commuter Cars Tango in Washington DC
Figure 3-53
Eliica Electric Car
Figure 3-54
Wrightspeed X1 Electric Car
Figure 3-55
Saturn SP1 Electric Car Conversion
Figure 3-56
Toyota Hybrid Prius
Figure 3-57
Toyota FT-EV Battery Electric Vehicle
Figure 3-58
Toyota Electric Car
Table 3-59
Chrysler ENVI Electric Minivan Features
Figure 3-60
Interior of The Concept Car, The Chrysler 200C EV
Table 3-61
Chrysler Electric Vehicle Positioning
Table 3-62
Chrysler Electric Vehicle EV
Figure 3-63
Chrysler Electric Vehicles
Figure 3-64
Dodge Circuit EV
Table 3-65
Dodge Circuit EV Features
Figure 3-66
Chrysler Jeep® Wrangler Unlimited EV
Figure 3-67
Jeep® Wrangler Unlimited EV Features
Figure 3-68
Phoenix Motorcars SUT Truck
Figure 3-69
Phoenix Motorcars SUV Vehicle
Figure 3-70
Shelby Supercars
Figure 3-71
Shelby Supercars - Doors Raised
Figure 3-72
Aptera Pre-Production Model 2e
Figure 3-73
Aptera 2e Pre-Production Models
Figure 3-74
Aperta Three Wheel Vehicle
Figure 3-75
Aperta Three Wheel Vehicle - Rear View
Figure 4-1
Altairnano Battery Performance:
Figure 4-2
EFOY Pro Fuel Cell Kit For Electric Vehicles
Figure 4-3
Electrica City Car - Red
Figure 4-4
Electrica City Car - Yellow
Figure 4-5
Electrica City Car - Open
Figure 4-6
Electrica City Car - Dashboard
Figure 4-7
Smart Fuel Cells (SFC) Supply The StartLab Open With Power
Table 4-8
Challenges in Lithium-ion Battery Design
Table 4-9
Advantages of Lithium-Ion Batteries
Source: ITN.
Table 4-10
Thin Film Battery Unique Properties
Table 4-11
Comparison of battery performances
Table 4-12
Comparison Of Battery Performances
Table 4-13
Thin Films For Advanced Batteries
Table 4-14
Thin Film Batteries Technology
Table 4-15
Thin Film Battery / Lithium Air Batteries Applications
Figure 4-16
Polymer Film Substrate Thin Flexible Battery Profiles
Figure 4-17
Design Alternatives of Thin Film Rechargable Batteries
Table 5-1
A123 Systems Batteries Benefits
Table 5-2
A123 Systems Competitive Positioning
Table 5-2 (Continued)
A123 Systems Competitive Positioning
Table 5-2 (Continued)
A123 Systems Competitive Positioning
Figure 5-3
Aptera Vehicle Early Drawings
Figure 5-4
Assembly Facility: Vista, CA
Figure 5-5
Aperta Composite Facility: Carlsbad, CA
Figure 5-6
EnerDel Operations
Figure 5-7
EnerDel Lithium Power Systems
Figure 5-8
EnerDel Lithium Power USABC Contracts
Figure 5-9
EnerDel Lithium Power Think Projct
Table 5-10
Ford Key Government Energy Actions Recommendations
Figure 5-11
Sanyo Battery Targets 2020
Figure 5-12
REVA Electric Car
Figure 5-13
Saft Revenue H1 2008
Figure 5-14
Shelby Supercars
Figure 5-15
Think Auto Production Facility
Figure 5-16
TH!NK North America
Figure 5-17
Toyota Consolidated Vehicle Sales
Figure 5-18
Toyota Strategy
Figure 5-19
Toyota Car
COMPANIES PROFILED
Tesla Motors
Daimler AG
Think
General Motors
BMW
BYD / MidAmerican Energy Holdings
Miles XS500 Electric Car
A123 Systems
Aperta
Better Place Model
E-One Moli Energy Group
Ener1 / Enertech
EnerDel Operations
LG Petrochemical
Panasonic / Sanyo
Saft
Mitsubishi i MiEV Electric Car
NEC / Fuji Heavy Industries / Subaru
NEC / Nissan
REVA Electric Car
Zenn Low Speed Electric Car
Ford
Shelby Supercars
Samsung
Electric Supercar by Hybrid Technologies
Electric Mini by PML
Commuter Cars Tango Electric Car
Eliica Electric Car by KEIO University
Wrightspeed X1 Electric Car
Toyota Hybrid Prius
Chrysler
Phoenix
Aptera
