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市場調査レポート

世界の固体薄膜電池:市場シェア・戦略・予測・ナノテクノロジー

Solid State Thin Film Battery: Market Shares, Strategies, and Forecasts, Worldwide, Nanotechnology, 2013 to 2019

発行 WinterGreen Research, Inc. 商品コード 230736
出版日 ページ情報 英文 344 Pages
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世界の固体薄膜電池:市場シェア・戦略・予測・ナノテクノロジー Solid State Thin Film Battery: Market Shares, Strategies, and Forecasts, Worldwide, Nanotechnology, 2013 to 2019
出版日: 2013年01月18日 ページ情報: 英文 344 Pages
概要

2012年における固体薄膜電池市場は6億5,900万米ドルとなり、2019年までに59億5,000万米ドルへ達する見込みです。市場成長は、センサーによるコネクテッドワールドの実施からもたらされます。

当レポートでは、世界の固体薄膜電池市場における現状と見通しについて調査分析し、市場概要、市場シェア、市場予測、技術、主要製品の概要、主要企業のプロファイルなどをまとめ、概略下記の構成でお届けいたします。

エグゼクティブサマリー

第1章 固体薄膜電池市場の概説・市場力学

  • 変貌を遂げようとしている世界経済
  • よりスマートなコンピューティングは固体薄膜電池に依存
  • 固体薄膜電池のターゲット市場
  • 充電式電池との比較に用いられる基本機能
  • 統合型エネルギー貯蔵
  • グリッドエネルギーロスの削減

第2章 固体薄膜電池の市場シェア・予測

  • 固体電池のメリット
  • 固体電池の市場シェア
  • 固体薄膜電池(TFB)の市場予測
  • 固体薄膜電池のアプリケーション
  • 電池市場
  • ワイヤレスセンサー市場
  • 固体薄膜電池の価格・インストールベース分析
  • 固体薄膜電池の地域別分析

第3章 固体薄膜電池製品の概説

  • Cymbetの固体電池(SSB)
  • Infinite Power Solutions (IPS)
  • Excelatron
  • NEC(日本電気)

第4章 固体薄膜電池技術

  • 固体薄膜電池の製造技術
  • Cymbet のEnerChip™−固体薄膜電池は並列接続された10個のチップを充電
  • Infinite Power Solutions (IPS)のセラミック
  • NEC(日本電気)のリチウムイオン電池技術
  • 空気電池:リチウムイオンが酸素を過酸化リチウムに変換
  • ナノテクノロジーと固体薄膜電池
  • John Bates 氏の特許
  • MEMSアプリケーション
  • 結晶シリコン(c-Si)製造技術の発展
  • 遷移金属酸化物、MnO
  • 電池の構造
  • ナノテクノロジーの影響
  • 電池識別のための命名基準
  • 充電式電池の性能比較
  • マイクロバッテリーの固体電解質
  • 電池の種類
  • 電池の安全性/潜在的危険性

第5章 固体薄膜電池企業のプロファイル

  • Balsara Research Group, UC Berkley
  • Cymbet
  • Johnson Research & Development / Excellatron
  • Infinite Power Solutions, Inc.
  • MIT Solid State Battery Research
  • NEC(日本電気)
  • Planar Energy Devices
  • Seeo
  • トヨタ
  • Watchdata Technologies

図表

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目次
Product Code: SH25381314

Batteries are changing. Solid state batteries permit units to be miniaturized, standalone, and portable. Solid-state batteries have advantages in power and density: low-power draw and high-energy density. They have limitations in that there is difficulty getting high currents across solid - solid interfaces.

Power delivery is different in solid state thin film batteries, - there is more power per given weight. The very small and very thin size of solid state batteries helps to reduce the physical size of the sensor or device using the battery. Units can stay in the field longer. Solid state batteries can store harvested energy. When combined with energy harvesting solid state batteries can make a device stay in the field almost indefinitely, last longer, power sensors better.

Temperature is a factor with batteries. The solid state batteries work in a very broad range of temperatures, making them able to be used for ruggedized applications. Solid state batteries are ecofriendly. Compared with traditional batteries, solid state thin film batteries are less toxic to the environment.

Development trends are pointing toward integration and miniaturization. Many technologies have progressed down the curve, but traditional batteries have not kept pace. The technology adoption of solid state batteries has implications to the chip grid. One key implication is a drive to integrate intelligent rechargeable energy storage into the chip grid. In order to achieve this requirement, a new product technology has been embraced: Solid state rechargeable energy storage devices are far more useful than non-rechargeable devices.

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 solid state battery electrolyte is a solid, not porous liquid. The solid is denser than liquid, contributing to the higher energy density. Charging is complex. In an energy-harvesting application, where the discharge is only a little and then there is a trickle back up, the number of recharge cycles goes way up. The cycles increase by the inverse of the depth of discharge. Long shelf life is a benefit of being a solid state battery. The fact that the battery housing does not need to deal with gases and vapors as a part of the charging/discharging process is another advantage.

According to IBM, the world continues to get “smaller” and “flatter.” Being connected holds new potential: the planet is becoming smarter because sensors let us manage the environment. Intelligence is being infused into the way the world works.

Sensor networks are being built as sensors are integrated into the systems, processes and infrastructure that comprise surroundings. These sensor networks enable physical goods to be developed, manufactured, bought and sold with more controls than were ever available before.

Table of Contents

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
  • Solid State Battery Market Shares
  • Solid State Thin-Film Battery (TFB) Market Forecasts

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) ThinergyR 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

List of Tables and Figures

Solid State Battery Executive Summary

  • Table ES-1: Solid-State Battery Advantages and Disadvantages
  • Table ES-2: Thin Film Battery Market Driving Forces
  • Figure ES-3: Solid State Thin Film Battery Market Shares, Dollars, First Three Quarters 2012
  • Figure ES-4: Solid State Thin Film Market Forecasts, Dollars, Worldwide, 2013-2019

Solid State Battery Market Description and Market Dynamics

  • Table 1-1: Thin Film Battery Target Markets
  • Table 1-2: Principal Features Used To Compare Rechargeable Batteries
  • Figure 1-3: Energy Storage and Generation for Wireless Sensor Network
  • Figure 1-4: Energy Information Administration and Energy Loss Presentation

Solid State Battery Market Shares and Market Forecasts

  • Table 2-1: Solid-state battery Advantages and Disadvantages
  • Table 2-2: Thin Film Battery Market Driving Forces
  • Figure 2-3: Solid State Thin Film Battery Market Shares, Dollars, First Three Quarters 2012
  • Table 2-4: Solid State Thin Film Battery Market Shares, Dollars, Worldwide, First Three Quarters 2012
  • Figure 2-5: Solid State Thin Film Market Forecasts, Dollars, Worldwide, 2013-2019
  • Table 2-6: Solid State Thin Film Battery Market Application Forecasts, Units and Dollars, Worldwide, 2013-2019
  • Figure 2-7: Solid State Thin Film Market Forecasts, Units, Worldwide, 2013-2019
  • Table 2-8: Solid State Thin Film Battery Market Forecasts Units and Dollars, Worldwide, 2013-2019
  • Figure 2-8: Small Solid State Thin Film Battery Market Shipments Forecasts Dollars, Worldwide, 2013-2019
  • Figure 2-9: Mid-Size Solid State Thin Film Battery, Market Forecasts Dollars, Worldwide, 2013-2019
  • Figure 2-10: Small Solid State Thin Film Battery Market Forecasts, Units, Worldwide, 2013-2019
  • Figure 2-11: Mid-Size Solid State Thin Film Market Forecasts, Units, Worldwide, 2013-2019
  • Figure 2-12: IBM Smarter Planet: Trillions of Interconnected Sensors
  • Figure 2-13: Cymbet Energy Harvesting (EH) Building Automation
  • Figure 2-14: Cymbet Energy Harvesting (EH) Medical Applications
  • Figure 2-15: Cymbet Semi Passive RF Tag Applications
  • Figure 2-16: RF Charging and Comms - TI and Cymbet
  • Figure 2-17: Cymbet Millimeter Scale Applications
  • Figure 2-18: Solid State Thin Film Battery Market Segments, Dollars, Worldwide, 2012
  • Figure 2-19: Solid State Thin Film Battery Market Segments, Dollars, Worldwide, 2019
  • Table 2-20: Solid State Thin Film Battery Market Application Forecasts Units and Dollars, Worldwide, 2013-2019
  • Figure 2-21: Solid State Thin Film Battery Market Application Forecasts Units and Dollars, Worldwide, 2013-2019
  • Figure 2-22: Cymbet Energy Harvesting Applications
  • Table 2-23: Excelatron Comparison of Battery Performances
  • Table 2-24: Solid State Thin Film Battery Market Installed Base Forecasts Units and Dollars, Worldwide, 2013-2019
  • Figure 2-25: Solid State Thin Film Battery Regional Market Segments, 2012
  • Table 2-26: Solid State Thin Film Battery Regional Market Segments, 2012

State Battery Product Description

  • Table 3-1: EnerChip device Eco-Friendly Attributes:
  • Table 3-2: Cymbet Embedded Energy And The Advantages Of Point Of Load Energy Delivery Functions
  • Table 3-3: Cymbet Solid State Energy Storage Devices And IC
  • Table 3-4: Cymbet Pervasive Power Architecture Advantages
  • Table 3-5: Cymbet Pervasive Power architecture Embedded Energy Advantages
  • Table 3-6: Cymbet Cross Power Grid Functions
  • Table 3-7: Cymbet Point of Load Power-On-Chip Benefits
  • Table 3-8: Cymbet Assessment of Chip Grid Trends
  • Figure 3-9: Cymbet Solid State Rechargeable Energy Storage Devices
  • Figure 3-10: Cymbet Rechargeable Solid State Energy bare die Co-Packaged Side-By Side With An IC:
  • Figure 3-11: Rechargeable Solid State Energy bare die Co-packaged in “wedding cake” die stack:
  • Figure 3-12: Cymbet Rechargeable Solid State Energy bare die in System on Chip module:
  • Figure 3-13: Solid State Energy Storage Built On Silicon Wafer Solder Attached To The Circuit Board Surface
  • Figure 3-14: Solid State Energy Storage Silicon Wafer Solder Attached To The Circuit Board Surface
  • Figure 3-15: Cymbet Millimeter Scale Applications
  • Figure 3-16: Cymbet Millimeter-Sized Solar Energy Harvesting Sensor Sits On A Solid State Rechargeable Energy Storage Device
  • Figure 3-17: Cymbet Millimeter Scale Computer Wireless Sensor Photo On US Penny for Size Reference
  • Figure 3-18: EnerChip 1uAh Battery On US Dollar For Size Reference
  • Figure 3-19: Cymbet Millimeter Scale EH-based Computer IOPM Layers Block Diagram
  • Figure 3-20: Cymbet Wireless Sensor IOPM Block Diagram
  • Table 3-21: Cymbet Intra Ocular Pressure Sensor IOPM basic elements:
  • Figure 3-22: Infinite Power Solutions Thinergy MEC201
  • Figure 3-23: Infinite Power Solutions (IPS) THINERGY MEC225
  • Table 3-24: Device: THINERGY MEC225 Specifications
  • Figure 3-25: Infinite Power Solutions (IPS) Device: THINERGY MEC220
  • Table 3-26: Infinite Power Solutions (IPS) THINERGY MEC220 Specifications
  • Figure 3-27: Device: THINERGY MEC201
  • Table 3-28: Device: THINERGY MEC201
  • Figure 3-29: Infinite Power Solutions (IPS) THINERGYR MEC202
  • Table 3-30: Device: Infinite Power Solutions (IPS) THINERGY MEC202
  • Table 3-31: Infinite Power Solutions (IPS) THINERGY MEC202 Features
  • Table 3-32: Infinite Power Solutions (IPS) THINERGY MEC202 Applications
  • Table 3-33: Infinite Power Solutions (IPS) THINERGY MEC202 Benefits
  • Figure 3-34: Infinite Power Solutions (IPS) THINERGY MEC202 Typical Discharge Curves @25°C (1.7 mAh Standard Grade Cell)
  • Figure 3-35: Infinite Power Solutions (IPS) THINERGY MEC202 Typical Discharge Curves @25°C (1.7 mAh Performance Grade Cell)
  • Figure 3-36: Typical Maximum Current vs. Temperature - All Capacity Options
  • Figure 3-37: Typical Charge Curve @ 25°C - All Capacity Options
  • Figure 3-38: OCV as a Function of State of Charge at 25°C
  • Table 3-39: Infinite Power Solutions (IPS) THINERGY MEC202 Functions
  • Table 3-40: Infinite Power Solutions (IPS) THINERGY Charging Methods
  • Table 3-41: Infinite Power Solutions (IPS) THINERGY Energy Harvesting Charging Methods
  • Figure 3-42: Excelatron Schematic Cross Section Of A Thin Film Solid-State Battery
  • Figure 3-43: Charge/discharge profile of Excellatron's thin film battery at 25oC.
  • Figure 3-44: Charge/discharge profile of Excellatron's thin film battery at 150oC.
  • Figure 3-45: High temperature (150oC) charge and Discharge Capacity As A Function Of Cycle Number For A Thin Film Battery.
  • Figure 3-46: Excelatron Capacity And Resistance
  • Figure 3-47: Excelatron High Rate Pulse Discharge
  • Figure 3-48: Excelatron High Rate Pulse Discharge
  • Figure 3-49: Excelatron Long Term Cyclability of a Thin Film Solid State Battery
  • Figure 3-50: Excelatron Long Term Cyclability Of A Thin Film Battery Thicker Cathode
  • Figure 3-51: Excelatron Discharge Capacity
  • Figure 3-52: Excelatron Thin film Batteries Deposited On A Thin Polymer Substrate
  • Figure 3- 53: Excelatron Rechargeable Thin Film Solid State Battery Thickness
  • Table 3-54: Excelatron Comparison of Battery Performances
  • Table 3-55: Excellatron High Capacity Thin Film Batteries
  • Figure 3-56: Excellatron Voltage And Current Profile of a 10 mAh Battery Characteristics
  • Figure 3-57: NEC High Voltage, Long Life Manganese Lithium-Ion Battery

Solid State Battery Technology

  • Figure 4-1: Cymbet EnerChip CC Smart Solid State Batteries Functional DIagram
  • Table 4-2: Cymbet EnerChip Single Chip Ups Provides Many Advantages For Electronics Designers:
  • Figure 4-3: Cymbet Energy Processor for Max Peak Power
  • Figure 4-4: Cymbet Energy Harvesting Building Automation
  • Table 4-5: Cymbet Solutions Areas
  • Figure 4-6: Cymbet Energy Harvesting Evaluation Kit
  • Table 4-7: Cymbet Products Offered by Digi-Key
  • Table 4-8: Infinite Power Solutions (IPS) Technology and Chemistry
  • Figure 4-9: IPS THINERGY MECs
  • Table 4-10: Thin Film Battery Unique Properties
  • Figure 4-11: Solid-State Lithium-Air Battery (Highlighted In Orange)
  • Figure 4-12: Department of Energy's Oak Ridge National Laboratory Battery Behavior At The Nanoscale
  • Figure 4-13: Rice Researchers Advanced Lithium-Ion Technique has Microscopic Pores That Dot A Silicon Wafer
  • Figure 4-14: Rice University50 Microns Battery
  • Figure 4-15: Discharge of a Lithium Battery
  • Figure 4-16: Nanoparticle Illustration
  • Figure 4-17: Silver Nanoplates Decorated With Silver Oxy Salt Nanoparticles
  • Figure 4-17a: Graphene Molecular Illustration (Lawrence Berkeley National Laboratory)
  • Figure 4-18: John Bates Patent: Thin Film Battery and Method for Making Same
  • Table 4-19: Approaches to Selective Emitter (SE) Technologies
  • Figure 4-20: XRD Patterns of MnO Thin Films
  • Table 4-21: Comparison Of Battery Performances
  • Table 4-22: Common Household-Battery Sizes, Shape, and Dimensions
  • Table 4-23: Thin Films For Advanced Batteries
  • Table 4-24: Thin Film Batteries Technology Aspects
  • Table 4-25: Solid State Thin Film Battery Applications
  • Figure 4-26: Design Alternatives of Thin Film Rechargable Batteries
  • Table 4-27: Challenges in Battery and Battery System Design
  • Figure 4-28: Typical Structure Of A Thin Film Solid State Battery
  • Table 4-30: Characteristics Of Battery Cells

Solid State Battery Company Profiles

  • Figure 5-1: Balsara Research Group Transported Material and Transporting Medium
  • Table 5-2: Balsara Research Group Collaborators:
  • Table 5-3: Balsara Research Group Funding Sources
  • Table 5-4: Cymbet Supporting Technologies
  • Table 5-5: Cymbet Smart Energy
  • Figure 5-6: Cymbet Industry Trends and Storage Solutions Alignment
  • Table 5-7: Cymbet Addresses Energy Storage Requirements for New Products
  • Figure 5-8: Key Battery Characteristics
  • Figure 5-9: Cymbet Solid State Batteries - Wafer to PCB
  • Table 5-10: Cymbet Customers
  • Table 5-11: Cymbet / TI EnerChip Key Benefits
  • Table 5-12: Cymbet / TI EnerChip Key Features
  • Figure 5-13: RF Charging and Comms - TI and Cymbet
  • Figure 5-14: Cymbet EH Building Automation
  • Figure 5-15: Cymbet Semi Passive RF Tag Applications
  • Figure 5-16: Cymbet Enerchips Environmental Regulation Compliance
  • Table 5-17: Cymbet Solid State Energy Storage Innovation
  • Figure 5-18: Cymbet Strategic Investors
  • Figure 5-19: Cymbet Investors
  • Figure 5-20: Cymbet Distribution Partners
  • Figure 5-21: Cymbet Distributors
  • Table 5-22: Cymbet Authorized Resellers
  • Figure 5-23: Cymbet Industry Awards and Recognition
  • Table 5-24: Characteristics of Excellatron Batteries
  • Table 5-25: Technology of Excellatron Batteries
  • Table 5-26: Excellatron Achievements:
  • Table 5-27: Excellatron Strategic Relationships
  • Figure 5-28: Solid-State Lithium-Air Battery (Highlighted In Orange)
  • Figure 5-29: Toyota Thin Film Battery
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