本報告已在2011年07月19日停止出版。
各國在國家安全防禦上對於能夠檢測出化學物質、生化武器及危險物的感測器需求遽升;汽車產業為了提高燃料效益及安全性對於機器感測器及化學感測器的需求也日益增加;醫療產業為了早期發現疾病已經正式採用生物感測器及 Lab-on-Chip 等高效率診斷方法。從各領域積極採用感測器的情況可以預料感測器的未來市場規模將會逐漸擴大。特別是奈米感測器由於體積小並且具有比其他感測器更高的感應度,因此一般預料未來將廣泛使用在各領域上。
專門在通訊、IT、半導體、生物醫藥及能源領域裡,調查與分析奈米科技影響的美國市調公司 NanoMarkets (總公司:維吉尼亞州),調查與分析奈米感測器市場,並有系統地出版綜合報告書"Nanosensor Market Analysis Report"。
此報告書在下面的內容裡,除了說明奈米感測器的潛在市場概要、奈米感測器的市場主要要素;也分析奈米感測器的開發環境概要、現今市場所推廣的製品、技術課題;另外也探討主要廠商間的合作關係、各用途、奈米感測器種類及材料平台的市場預測等。
本商品由於是事前預定的緣故,價格、內容及出版時間可能會有更改的情況發生。詳細內容敬請來電詢問。
第 1 章 序論
第 2 章 奈米感測器技術的評價
- 概要
- 奈米感測器的開發及商業化概況
- 奈米感測器技術的成功要素
- 奈米感測器技術課題
第 3 章 為何需要奈米感測器?顧客的觀點
第 4 章 可應用奈米感測器的市場
- 概要
- 環境及氣候觀測
- 能源觀測
- 工業管理
- 機械
- 普及運算
- 航空宇宙、汽車及其他傳輸
- 生物醫藥
- 國家安全
- 軍事
第 5 章 企業檔案
第 6 章 奈米感測器裝置在這 8 年內的投資預測
- 概要
- 各用途的投資預測
- 奈米感測器的各用途投資預測
- 各奈米材料平台的投資預測
圖表
Nanosensor Market Analysis Report
Summary:
Sensing systems in the form of burglar alarms, pressure sensors and medical
diagnostic kits, etc., have been around for decades, but suddenly the sensor
business seems ready to take a great leap forward. The World Semiconductor Trade
Statistics organization has the sensor market pegged as the fastest growing of
all the product segments that it covers for the 2003 to 2006 period.
The drivers for this growing market are very diverse. For example, concerns
about national security are pushing the need for sensors that warn against
chemical or biological attacks or dangerous items hidden in luggage. In the
transportation industry the need to make cars and planes safer, more fuel
efficient and more comfortable for passengers is spawning new generations of
mechanical and chemical sensors. In medicine, with its growing emphasis on early
prevention, new biosensors and labs-on-a-chip offer an especially cost effective
means of diagnosis. Meanwhile, the next big thing in computing will supposedly
be pervasive computing in which always on mobile and fixed computers will
process information from a myriad different sources including weather sensors
and security sensors.
Although the sensor market is so fragmented, nanotechnology has some unique
capabilities that suggest that it will have a large impact in many of the
markets most important segments. Nanosensors are inherently more sensitive than
any other kind of sensor, making them a future choice where lives are at stake.
In addition, their small size and potentially low cost means that they can be
widely deployed -- perhaps being embedded in construction materials -- thereby
providing more comprehensive readings than a few scattered "macrosensors"
Nanotechnology also promises to created integrated devices that combine both the
sensor itself and the mechanism that converts what is sensed into useful
information.
This new report from NanoMarkets analyzes and quantifies the market for
nanosensors over the next eight years. It first examines each of the key
applications areas for these emerging products and then traces how the needs of
each sector translates into the types of nanosensors required and the materials
platforms likely to be used. In this report we also provide a survey of the of
the nanosensor development work and the products that are currently available,
as well as the technology issues that still need to be resolved. We also review
the activities of all the leading materials and device manufacturers who are
currently focused on nanosensors and provide detailed forecasts by application,
type of nanosensor and materials platform used.
Table of Contents *(subject to change)
Executive Summary
Chapter One: Introduction
- 1.1 Background to this Report
- 1.2 Objective of this Report
- 1.3 Scope of this Report
- 1.4 Methodology and Sources of this Report
Chapter Two: Nanosensor Technology Assessment
- 2.1 Introduction
- 2.2 Review of Development and Commercialization of Nanosensors
- 2.2.1 Chemical and Gas Sensors
- 2.2.2 Radiation Sensors
- 2.2.3 Electrical and Magnetic Sensors
- 2.2.4 Mechanical and Fluidic Sensors
- 2.2.4.1 From MEMs to NEMs?
- 2.2.5 Thermal Sensors
- 2.2.6 Optical Sensors
- 2.2.7 Biosensors
- 2.2.7.1 Nanosensors and Labs-on-a-chip
- 2.3 Technology Enablers for Nanosensors
- 2.3.1 Computational Simulation.
- 2.3.2 Communications Technology
- 2.3.3 Microelectronics, Signal Processing and Photonics
- 2.3.4 New Materials and Surface Science
- 2.3.5 Improved Nanomanufacturing tools
- 2.4 Technology Challenges for Nanosensors
- 2.4.1 Advanced Materials Requirements, Cost and Availability
- 2.4.2 Manufacturability
- 2.4.3 Interfaces to Micro/Macro Level Devices
Chapter Three: Why Nanosensors? -- The Customer Perspective
- 3.1 Introduction
- 3.2 Analysis of the Marketplace Advantages of Nanosensors
- 3.2.1 Increased Sensitivity
- 3.2.2 Smaller and Lighter
- 3.2.3 Redundant Functionality
- 3.2.4 Less Power Consuming
- 3.2.5 Integration of Sensing and Information Processing Functionality
- 3.2.6 Cost Factors
- 3.3 New Product Opportunities
- 3.3.1 Nanosensor Networks
- 3.3.2 Nanosensor Swarms and Embedded Sensors
- 3.3.3 Nanosensors as a Replacement for Test Systems
- 3.3.4 Robotics
- 3.3.5 Personal Transportation Systems and Wearable Computing
Chapter Four: Addressable Markets for Nanosensors
- 4.1 Introduction
- 4.2 Environmental and Atmospheric Monitoring
- 4.3 Energy Monitoring
- 4.4 Industrial Control
- 4.5 Robotics
- 4.6 Pervasive Computing
- 4.7 Aerospace, Automotive and Other Transportation Applications
- 4.9 Biomedical Applications
- 4.10 Homeland Defense
- 4.11 Military
Chapter Five: The Players
- 5.1 Introduction
- 5.2 Profiles
- [The nanosensor R&D and marketing activities of the following
companies are being analyzed as part of the NanoMarkets research process.
Profiles of approximately 25 of the most influential firms will be included
in the final report. Other firms will be added as the research dictates.
What follows is a provisional list only.]
- Access Pharmaceuticals
- Advanced Diamond Technologies
- Advanced Metal Technologies/AS2T
- Affymetrix
- Agilent
- Ambri
- Applied Gene Technologies
- Boeing
- Broadley-James
- Cyrano Sciences
- Dendritech
- Dow Corning
- Genencor
- Graviton
- Honeywell
- Integrated Microsystems
- Integrated Nano-Technologies
- Jenoptik Laser
- Materials Modification
- MicroChemical Systems
- MicroSensor Systems
- Molecular Nanosystems
- Motorola
- Nanomix
- Nanoplex Technologies
- Nanoproducts
- Nanoproduktor
- Nanosensors
- Nanosphere
- Nanosys
- NanoTek
- Norsam
- Samsung
- Texas Instruments
- Zyvex
- 5.3 Emerging Alliances
Chapter Six: Eight-Year Projections of Expenditures for Nanosensor Devices
- 6.1 Forecast Methodology
- 6.2 Projections by Application Segment
- 6.2.1 Environmental and Atmospheric Monitoring
- 6.2.2 Energy Monitoring
- 6.2.3 Industrial Control
- 6.2.4 Robotics
- 6.2.5 Pervasive Computing
- 6.2.6 Aerospace, Automotive and Other Transportation
- 6.2.7 Biomedical Applications
- 6.2.8 Homeland Defense
- 6.2.9 Military
- 6.2.10 Other
- 6.3 Projections by Nanosensor Type
- 6.3.1 Chemical and Gas Sensors
- 6.3.2 Radiation Sensors
- 6.3.3 Electrical and Magnetic Sensors
- 6.3.4 Mechanical and Fluidic Sensors
- 6.3.5 Thermal Sensors
- 6.3.6 Optical Sensors
- 6.3.7 Biosensors
- 6.3.8 Other
- 6.4 Projections by Sensor Material Platform
- 6.4.1 Organic Molecular
- 6.4.2 Inorganic Molecular
- 6.4.3 Carbon Nanotube
- 6.4.4Polymer
- 6.4.5 NEMs
- 6.4.6 Other
