全球奈米尺度智慧材料市場 是由出版商Nanoposts.com在2010年02月所出版的。
這份英文市場調查報告書包含187 Pages 價格從美金1600起跳。
本報告書為奈米科技以及智慧材料領域的現在技術動向與將來動向之相關分析,包含智慧材料的將來優勢、今後的應用領域等,概述如下。
第1章 導論
第2章 調査方法
第3章 智慧材料與奈米科技
- 智慧系統
- 壓電材料
- 電歪以及磁歪材料
- 電致變色材料
- 形狀記憶合金
- 熱電材料
- 電子流體、磁流體、流變流體
- 智慧膠
第4章 智慧奈米材料
- 薄膜與鍍膜
- 奈米粒子
- 奈米結晶材料
- 碳奈米管
- 奈米索
- 富勒烯
- 量子點
第5章 奈米尺度智慧材料市場
- 商品化
- 生命科學・醫療
- 能源
- 環境
- 航太
- 軍事
- 汽車
- 農業・食品封裝
- 運動・休閒
- 建設
- 線維
- 奈米尺度智慧材料類的主要企業
第6章 壓電智慧材料
第7章 熱電智慧材料
第8章 自己發熱智慧材料
第9章 用語解說
Abstract
Description
This report provides intelligence on market potential, current technology
status and future trends in the area of nanotechnology and smart materials.
The market constantly asks for better devices and materials. In the market
there is technical progression of all types of materials' size (from macro to
nano), introduction of new materials, and the growing need to follow new laws
regarding the traceability of parts after the usability cycle. The potential
future benefits of smart materials, structures and systems enabled by
nanotechnology to meet such needs, are diverse in their scope. The development
and application of new smart materials can and will have a significant effect
on our use of energy and our health, our use of communications' technology and
our security.
The Global Market for Nanoscale Smart Materials is in depth look at how
nanotechnology is enhancing the smart materials area, providing both intrinsic
smartness and enhancement of existing smart materials.
Areas covered include Nanotechnology and Piezoelectric Materials;
Electrostrictive and magnetostrictive materials; Shape Memory Alloys;
Electrochromics and Smart Gels to name but a few.
In depth market coverage and likely short to long term applications are also
described in detail. Markets include Healthcare and Life Sciences,
Environment, Aerospace, Construction and Textiles etc. covering applications
such as tissue engineering, self-healing and responsive surfaces and new
sensors for aerospace and transport.
The scaling of existing smart materials to the nanoscale and the incorporation
of new nanomaterials into smart systems and structures, will allow for
material enhancement and efficiency not possible at other scales. For example,
in the area of thermoelectric converters for the direct conversion of
geothermal and solar thermal energy sources into electricity, nanoscaled
materials are applied because they lower the heat conductivity in the n- and
p-type semiconductors dramatically, and thus enhance the conversion efficiency.
This report describes the future market opportunities, challenges, and drivers
in the area of nanotechnology and smart materials. In depth focus will be
placed on the areas of piezoelectric, thermoelectric and self-repairing
(healing) smart materials.
Report Statistics
- Pages: 187
- Format: PDF and hard copy
- Published: February 2010
Table of Contents
1. INTRODUCTION
2. METHODOLOGY
- 2.1 Quantitative data collection
- 2.2 Qualitative data collection
- 2.3 Market forecasting
3. SMART MATERIALS AND NANOTECHNOLOGY
- 3.1 SMART SYSTEMS
- 3.2 PIEZOELECTRIC MATERIALS
- 3.3 ELECTROSTRICTIVE AND MAGNETOSTRICTIVE MATERIALS
- 3.4 ELECTROCHROMIC MATERIALS
- 3.5 SHAPE MEMORY ALLOYS
- 3.6 THERMOELECTRICS
- 3.7 ELECTRO-, MAGNETO-, RHEOLOGICAL FLUIDS
- 3.7.1 Electrorheological (ER) fluids
- 3.7.1.1 Mechanical damper
- 3.7.1.2 Clutch, brake/brake control
- 3.7.1.3 Sports equipment
- 3.7.2 Magneto-rheological (MR) fluids
- 3.8 SMART GELS
4. NANOMATERIALS FOR SMARTNESS
- 4.1 THIN FILMS AND COATINGS
- 4.2 NANOPARTICLES
- 4.3 NANOCRYSTALLINE MATERIALS
- 4.4 CARBON NANOTUBES
- 4.5 NANOWIRES
- 4.6 FULLERENES
- 4.7 QUANTUM DOTS
5. MARKETS FOR NANOSCALE SMART MATERIALS
- 5.1 COMMERCIALISATION
- 5.1.1 Need for smart materials
- 5.1.2 Drivers of Change
- 5.1.3 Future Trends and Outlook
- 5.1.4 State of the art in nanotechnology in smart materials
- 5.2 LIFE SCIENCES AND HEALTHCARE
- 5.2.1 Tissue engineering
- 5.2.2 Biomedicine
- 5.2.3 Drug delivery
- 5.2.4 Implants
- 5.2.5 In vivo sensing
- 5.2.6 Applications timeline
- 5.3 ENERGY
- 5.3.1 Energy conversion/production
- 5.3.2 Energy storage
- 5.3.3 Energy saving
- 5.3.4 Applications timeline
- 5.4 ENVIRONMENT
- 5.4.1 Detection
- 5.4.2 Treatment
- 5.4.3 Remediation
- 5.4.4 Applications Timeline
- 5.5 AEROSPACE AND AVIATION
- 5.5.1 Wings
- 5.5.2 Self-sensing structures
- 5.5.3 Adaptive Control
- 5.5.4 Self-healing coatings
- 5.5.5 Applications timeline
- 5.6 DEFENCE
- 5.6.1 Self healing and repair systems
- 5.6.2 Self-Decontaminating surfaces
- 5.6.3 Biosensing and biodefense
- 5.6.4 Protective clothing
- 5.6.5 Applications Timeline
- 5.7 AUTOMOTIVE
- 5.7.1 Brakes
- 5.7.2 Tires
- 5.7.3 Vibration Control
- 5.7.4 Applications timeline
- 5.8 AGRICULTURE, FOOD AND PACKAGING
- 5.8.1 Supply chain
- 5.8.2 Sensing
- 5.8.3 Smart labels
- 5.8.4 Bioactive Surfaces
- 5.8.5 Packaging
- 5.8.6 Applications timeline
- 5.9 SPORTS AND LEISURE
- 5.9.1 Piezoelectric vibration reduction
- 5.9.2 Applications timeline
- 5.10 CONSTRUCTION
- 5.10.1 Structural Health Monitoring
- 5.10.2 Vibration control
- 5.10.3 Applications timeline
- 5.11 TEXTILES
- 5.11.1 Protective clothing
- 5.11.2 Functional fabrics
- 5.11.3 Applications Timeline
- 5.12 KEY PLAYERS IN NANOSCALE SMART MATERIALS
6. PIEZOELECTRIC SMART MATERIALS
- 6.1 NANOMATERIALS FOR PIEZOELECTRICS
- 6.1.1 Piezoelectrically Actuated MEMS RF Switch
- 6.1.2 Quantum chaos in a NEMS structure
- 6.1.3 Processing and deposition
- 6.1.4 State of Art of Theory and Simulation
- 6.2 MARKETS AND APPLICATIONS
- 6.2.1 Tubular Actuators
- 6.2.2 Bending-mode actuators
- 6.2.3 Active Noise Control
- 6.2.4 Active shape control
- 6.2.5 Smart sensors for side impact diagnostics in automobiles
- 6.2.6 Cochlear implant for hearing losses
- 6.2.7 Nano shutter for space applications
- 6.2.8 Sensors Market
- 6.2.9 Smart Sensors for Automotive manufacturing
- 6.2.10 Smart Sensors for Healthcare
- 6.2.11 Market Demands and competitive situation
- 6.2.11.1 Information and communication
- 6.2.11.2 Automobiles, consumer products and environment
- 6.2.11.3 Medical and biological
- 6.2.11.4 Production and inspection
- 6.3 CHALLENGES AND BARRIERS
- 6.3.1 Ultra low defects materials
- 6.3.2 High Tc materials
7. THERMOELECTRIC SMART MATERIALS
- 7.1 NANOMATERIALS FOR THERMOELECTRICS
- 7.2 MARKETS AND APPLICATIONS
- 7.2.1 Thermoelectric Coolers
- 7.2.2 Thermoelectric Power Generators
- 7.2.3 Applications
- 7.2.3.1 Thermoelectric Coolers
- 7.2.3.2 Solar Thermoelectric Generation
- 7.2.3.3 Thermal energy sensors
- 7.2.3.4 Cryogenic heat flux sensor
- 7.2.3.5 Ultrasonic intensity sensor
- 7.2.3.6 Detection of water condensation
- 7.2.3.7 Fluid flow sensor
- 7.2.3.8 Infrared sensor
- 7.2.3.9 Thin film thermoelectric sensor
- 7.3 CHALLENGES AND BARRIERS
- 7.3.1 Challenges in Material Synthesis
- 7.3.2 Challenges in Characterization and Measurement
- 7.3.3 Challenges in Understanding and Modeling Transport Phenomena
- 7.3.4 Challenges in Device Integration and Operation
- 7.3.4.1 Sublimation
- 7.3.4.2 Device Integration
- 7.3.4.3 Lifetime Thermoelectric Property Variations
8. SELF-HEALING SMART MATERIALS
- 8.1 NANOMATERIALS FOR SELF-REPAIR
- 8.2 MARKETS AND APPLICATIONS
- 8.2.1 Plastics/polymers
- 8.2.2 Paint
- 8.2.3 Metals
- 8.2.4 Ceramics/concrete
- 8.2.5 LOW COST SENSITIVE APPLICATIONS
- 8.2.5.1 Medical dental/ artificial body replacements
- 8.2.5.2 Aerospace
- 8.2.5.3 Military
- 8.2.6 HIGH COST SENSITIVE APPLICATIONS
- 8.2.6.1 Car painting
- 8.2.6.2 Civil construction
- 8.3 CHALLENGES AND BARRIERS
9. GLOSSARY OF TERMS
