超材料:技術及全球市場

超材料:技術及全球市場 是由出版商BCC Research在2012年01月所出版的。 這份英文市場調查報告書包含150 Pages 價格從美金4850起跳。

簡介

全球超材料市場2010年為2億2,230萬美元，BCC預計2011年將達到2億5,610萬美元的規模。該市場2011年以年複合成長率(複合年度成長率)24.3％增長，2016年將以7億5,870萬美元的規模擴大，年複合成長率19.6％的2021年將達到19億美元。

本報告提供全球超材料市場相關調查分析，超材料概要，種類，及應用彙整，人工介電質，負折射介質，活性兆赫超材料，手性材料，光晶體，極限參數超材料，磁性奈米複合材料，及聲波超材料等主要的市場區隔分析，各不同市場區隔的市場預測（∼2021年），主要的企業的資訊等，為您概述為以下內容。

第1章 簡介

第2章 摘要整理

第3章 概要

• 超材料概要
• 超材料種類與應用程式
• 整體的市場規模與市場區隔

第4章 人工介電質:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第5章 負折射介質:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第6章 活性兆赫超材料:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第7章 手性材料:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第8章 光晶體:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第9章 超傳導 超材料:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第10章 極限參數超材料:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第11章 磁性奈米複合材料:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第12章 聲波超材料:材料，最終用途，及市場(2010-2021年)

• 材料
• 應用程式
• 市場

第13章 企業簡介

• ALIGHT TECHNOLOGIES APS
• ALPS ELECTRIC CO., LTD.
• COLOSSAL STORAGE CORP.
• FIANIUM, LTD.
• ICX TECHNOLOGIES
• INFRAMAT CORP.
• JEM ENGINEERING, LLC
• LUMINUS DEVICES, INC.
• LUXTERA, INC.
• NEOMAX COMPANY, LTD.
• OMNIGUIDE, INC.
• NANOSTEEL COMPANY, INC.
• NEWPORT CORPORATION
• NKT PHOTONICS A/S
• OMNIGUIDE, INC.
• OPALUX INC.
• PHOTEON TECHNOLOGIES GMBH
• PHOTONIC LATTICE, INC.
• RAYSPAN, INC.
• ROOM TEMPERATURE SUPERCONDUCTORS, INC.
• SANDVIK MATERIALS TECHNOLOGY AB
• TERAVIEW, LTD.
• VACUUMSCHMELZE GMBH

第14章 附錄:專利分析

第15章 參考文獻

圖表

目錄

Abstract

REPORT HIGHLIGHTS

BCC estimates the global market for metamaterials was worth $222.3 million in 2010 and $256.1 million in 2011. BCC expects the market to grow to $758.7 million by 2016, a compound annual growth rate (CAGR) of 24.3% since 2011, and to reach nearly $1.9 billion by 2021, a CAGR of 19.6% between 2016 and 2021.

The Electromagnetic segment of the market was estimated to be worth $140 million in 2010 and $160.6 million in 2011. BCC expects the market to grow to $412.2 million by 2016, a CAGR of 20.7% since 2011, and to reach nearly $1.2 billion by 2021, a CAGR of 23.5% between 2016 and 2021.

The extreme-parameter and other segments were collectively estimated to be worth $82.3 million in 2010 and $95.5 million in 2011. BCC expects the market to grow to $346.5 million by 2016, a CAGR of 29.4% since 2011, and to reach nearly $630 million by 2021, a CAGR of 12.7% between 2016 and 2021.

REPORT SCOPE

INTRODUCTION

STUDY BACKGROUND

In October 2006, David R. Smith of Duke University and other researchers announced that they had created an " invisibility shield." Using concentric rings of fiberglass, circuit boards that had been printed with millimeter-scale metal wires, and C-shaped split rings, the researchers were able to divert microwaves around a metal cylinder placed at the center of the ring. The microwaves behaved as though there was nothing there.

In principle, there is no reason why a similar device that cloaks an object from visible light could not be built, although such a visible-light cloak is probably years away from becoming a reality. While not yet exactly the stuff of science fiction, the invisibility cloak is probably the most dramatic demonstration so far of what can be achieved with metamaterials, which are composites made up of precisely arranged patterns of two or more distinct materials.

Metamaterials can manipulate electro-magnetic radiation (e.g., light) in ways not readily observed in nature. Photonic crystals, which are periodic dielectric structures that diffract light of specific wavelengths and do not allow that light to leave the structure (i.e. the band gap), present a current example of optical metamaterials. Photonic crystals have a number of commercial applications, such as in ultrabright light-emitting diodes (LEDs).

Other commercial applications of metamaterials include radio frequency (RF) metamaterial air interface solutions for high-performance wireless communications networks. Most practical applications of metamaterials technology, however, still lie in the future, such as magnetic metamaterials for ultrasensitive magnetic resonance imaging (MRI) detectors and acoustical metamaterials for noise barriers.

STUDY GOALS AND OBJECTIVES

Metamaterials offer seemingly endless possibilities, but it is unlikely that all of these possibilities will become reality. The goal of this report, which is an update of an earlier BCC Research report published in 2008, is to survey emerging metamaterials technologies and applications, identify those that are most likely to achieve significant commercial sales in the next 5 to 10 years, and develop quantitative estimates of potential sales. The report generally avoids futuristic speculation concerning technology applications that might be possible 10 years or further into the future and instead focuses on applications that are expected make it to market by 2021.

The report's specific objectives, which include identifying the metamaterials with the greatest commercial potential in the 2012 to 2021 time frame, identifying market drivers and evaluating obstacles to their successful commercialization, and projecting their future sales, support this broad goal.

INTENDED AUDIENCE

This report is intended specifically for marketing executives, entrepreneurs, investors, venture capitalists, and other readers who need to know where the emerging metamaterials market is headed over the next 5 to 10 years. The information is organized around specific technologies, but it is largely non-technical in nature and coverage. Therefore, it is less concerned with theory and jargon, and more concerned with products that work, the amount of a particular product the market is likely to purchase, and the price consumers are willing to pay.

The report has not been written specifically for scientists and technologists, but its findings concerning the market for their work, including the availability of government and corporate research funding for different technologies and applications, should be of interest to them as well.

SCOPE AND FORMAT

This report addresses the emerging global market for metamaterials, including the following classes. The common thread uniting this diverse group of materials is that they are all artificial materials with characteristics usually not found in nature, and they owe these characteristics to their structure rather than to their constituent element or elements.

• Artificial dielectrics
• Negative refraction media
• Active terahertz (THz) materials (i.e., metamaterials that respond magnetically to far-infrared or THz electromagnetic radiation)
• Chiral materials
• Photonic crystals
• Superconducting metamaterials
• Extreme-parameter metamaterials (i.e., metamaterials whose internal structure has been modified or engineered on a molecular or nanoscale level to impart extraordinary strength, flexibility, or other characteristics)
• Acoustic metamaterials

The study format includes the following major elements:

• Executive summary
• Definitions
• General properties of metamaterials
• Historical milestones in the development of metamaterials
• Emerging and developmental metamaterials technologies and applications that demonstrate the greatest commercial potential through 2021
• Detailed market estimates and projections for each application and material during the period from 2011 to 2016
• General assessment of expected market trends in the longer term (i.e., 2016 - 2021)
• Patent analysis

INFORMATION SOURCES AND METHODOLOGY

Projecting the market for emerging technologies whose commercial potential has not yet been proven is a challenging task. This is most true in the metamaterials field, which may help to explain why many analysts focus on supply-side technology assessments.

BCC's objective in this report is to provide not just a technology assessment, but also an initial commercial assessment of the potential market for metamaterials. To accomplish this objective, BCC used a multiphase approach to identify the metamaterials with the greatest commercial potential and then quantified the related markets.

In the first phase of the analysis, BCC identified a long list of metamaterials technologies and applications, including those that are still under development. In the second phase, BCC used a literature review and interviews with industry sources to eliminate those metamaterials applications that appear to have little likelihood of making it into commercial use in the next 5 to 10 years. This second-phase research resulted in a short list of metamaterials with the greatest commercial potential over the time period covered by this report.

The third phase focused on quantifying the potential market for each short-listed metamaterial by application and identifying the main prerequisites for commercial success. This phase actually had two sub-phases: 1) development of near- to mid-term (2011 to 2016) projections, and 2) development of longer-term (2017 to 2021) projections. The development of such long-term projections is a departure from the usual BCC report format, but this is necessary due to the long time frame for commercialization of many of the technologies analyzed in this report. Obviously, the projections for the years beyond 2016 are more tentative than those for 2011 to 2016.

The specific assumptions and approach BCC used to develop the projections, both near/mid-term and long-term, for each metamaterial and application are documented in detail under the various segments addressed. This way, readers may see how the market estimates were developed and, if they so desire, test the impact on the final numbers of changing the underlying assumptions.

One of BCC's specific approaches deserves special mention here. BCC used the sales performance of a non-metamaterial application that has some of the same functions or shares other characteristics with the metamaterials application as a benchmark for assessing the latter's sales potential. This is especially relevant for metamaterials applications currently under development.

ANALYST CREDENTIALS

Andrew McWilliams is a partner at 43rd Parallel, LLC, a Boston-based international technology and marketing consulting firm. He is the author of a number of other BCC Research market opportunity reports on advanced materials technologies, including the previous edition of this report. Other reports by Mr. McWilliams include IFT066A Printed Electronics: The Global Market; NAN017F Nanostructured Materials: Electronic/Magnetic/Optoelectronic; AVM050B Smart and Interactive Textiles; AVM015E High Performance Ceramic Coatings: Markets and Technologies; AVM064A Geosynthetics: Materials, Applications and Markets; AVM025G Diamond, Diamond-like and CBN Films and Coating Products; NAN015F Advanced Ceramics and Nanoceramic Powders; NAN036A Nanotechnology for Photonics; AVM075A Graphene: Technologies, Applications, and Markets; AVM066B: Superconductors: Technologies and Global Markets; and AVM038D Advanced Structural Carbon Products: Fibers, Foams, and Composites.

Table of Contents

Chapter- 1: INTRODUCTION - Complimentary

• STUDY BACKGROUND
• STUDY GOALS AND OBJECTIVES
• INTENDED AUDIENCE
• SCOPE AND FORMAT
• INFORMATION SOURCES AND METHODOLOGY
• ANALYST CREDENTIALS
• RELATED BCC RESEARCH REPORTS
• BCC ONLINE SERVICES
• DISCLAIMER

Chapter- 2: EXECUTIVE SUMMARY

• Table 0 : GLOBAL MARKET FOR METAMATERIALS APPLICATIONS BY MATERIAL TYPE, THROUGH 2021
• Figure 0 : GLOBAL MARKET FOR METAMATERIALS APPLICATIONS BY MATERIAL TYPE, 2011-2021

Chapter- 3: OVERVIEW

• GENERAL DESCRIPTION OF METAMATERIALS
• TYPES AND APPLICATIONS OF METAMATERIALS
• OVERALL MARKET SIZE AND SEGMENTATION

Chapter- 4: ARTIFICIAL DIELECTRICS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• APPLICATIONS
• MARKETS

Chapter- 5: NEGATIVE REFRACTION MEDIA: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• APPLICATIONS
• MARKETS

Chapter- 6: ACTIVE TERAHERTZ METAMATERIALS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• APPLICATIONS
• MARKETS

Chapter- 7: CHIRAL MATERIALS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• APPLICATIONS
• MARKETS

Chapter- 8: PHOTONIC CRYSTALS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• APPLICATIONS
• MARKETS

Chapter- 9: SUPERCONDUCTING METAMATERIALS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• END USES
• MARKETS

Chapter- 10: EXTREME-PARAMETER METAMATERIALS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• END USES
• MARKETS

Chapter- 11: MAGNETIC NANOCOMPOSITES: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• END USES
• MARKETS
• Table 53 : GLOBAL CONSUMPTION OF MAGNETIC NANOCOMPOSITES FOR ELECTRICAL AND ELECTRONIC APPLICATIONS, THROUGH 2021

Chapter- 12: ACOUSTIC METAMATERIALS: MATERIALS, END USES, AND MARKETS, 2010 - 2021

• MATERIALS
• END USES
• MARKETS

Chapter- 13: COMPANY PROFILES

• ALIGHT TECHNOLOGIES APS
• ALPS ELECTRIC CO., LTD.
• COLOSSAL STORAGE CORP.
• FIANIUM, LTD.
• ICX TECHNOLOGIES
• INFRAMAT CORP.
• JEM ENGINEERING, LLC
• LUMINUS DEVICES, INC.
• LUXTERA, INC.
• NEOMAX COMPANY, LTD.
• OMNIGUIDE, INC.
• NANOSTEEL COMPANY, INC.
• NEWPORT CORPORATION
• NKT PHOTONICS A/S
• OMNIGUIDE, INC.
• OPALUX INC.
• PHOTEON TECHNOLOGIES GMBH
• PHOTONIC LATTICE, INC.
• RAYSPAN, INC.
• ROOM TEMPERATURE SUPERCONDUCTORS, INC.
• SANDVIK MATERIALS TECHNOLOGY AB
• TERAVIEW, LTD.
• VACUUMSCHMELZE GMBH

Chapter- 14: APPENDIX: PATENT ANALYSIS

• Figure 26 : RECENT U.S. METAMATERIALS-RELATED PATENTS ISSUED TO 11/15/1011
• Table L 26 :
• Table 58 : MAJOR U.S. METAMATERIALS PATENTS, TO NOVEMBER 15, 2011

Chapter- 15: REFERENCES

List of Tables

• Summary Table : GLOBAL MARKET FOR METAMATERIALS APPLICATIONS BY MATERIAL TYPE, THROUGH 2021
• Table 1 : MAJOR TYPES OF METAMATERIALS
• Table 2 : GLOBAL MARKET FOR METAMATERIALS BY MATERIAL TYPE, THROUGH 2021
• Table 3 : GLOBAL MARKET FOR METAMATERIALS BY END-USE SECTOR, THROUGH 2021
• Table 4 : MARKET FOR ARTIFICIAL DIELECTRICS, THROUGH 2021
• Table 5 : MATERIALS CONSUMPTION ASSOCIATED WITH AUTOMOTIVE RADAR APPLICATIONS, THROUGH 2021
• Table 6 : AIRBORNE ANTENNAS AND RELATED MARKET FOR METAMATERIALS, THROUGH 2021
• Table 7 : GLOBAL MARKET FOR 4G DATA COMMUNICATION EQUIPMENT AND POTENTIAL SUCCESSOR TECHNOLOGIES, THROUGH 2021
• Table 8 : SMART ANTENNAS AND THE RELATED MARKET FOR ARTIFICIAL DIELECTRICS, THROUGH 2021
• Table 9 : MARKET FOR NEGATIVELY REFRACTIVE METAMATERIALS, THROUGH 2021
• Table 10 : METAMATERIALS MARKET IN OPTICAL MICROSCOPY APPLICATIONS, THROUGH 2021
• Table 11 : METAMATERIALS MARKET IN PHOTOLITHOGRAPHY APPLICATIONS, THROUGH 2021
• Table 12 : METAMATERIALS MARKET IN DATA STORAGE APPLICATIONS, THROUGH 2021
• Table 13 : METAMATERIALS MARKET IN MRI APPLICATIONS, THROUGH 2021
• Table 14 : MARKET FOR THZ-ACTIVE METAMATERIALS, THROUGH 2021
• Table 15 : GLOBAL MARKET FOR THZ AND OTHER AIRPORT SECURITY SCREENING EQUIPMENT, THROUGH 2021
• Table 16 : GLOBAL MARKET FOR THZ AND OTHER RADIOGRAPHIC NDT EQUIPMENT, THROUGH 2021
• Table 17 : GLOBAL MARKET FOR THZ MEDICAL IMAGING APPLICATIONS, THROUGH 2021
• Table 18 : GLOBAL MARKET FOR THZ-ACTIVE METAMATERIALS IN MEDICAL IMAGING APPLICATIONS, THROUGH 2021
• Table 19 : GLOBAL MARKET FOR INTRAOPERATIVE IMAGING EQUIPMENT, THROUGH 2021
• Table 20 : GLOBAL MARKET FOR INTRAOPERATIVE THZ IMAGING EQUIPMENT, THROUGH 2021
• Table 21 : GLOBAL MARKET FOR THZ SKIN CANCER IMAGING EQUIPMENT, THROUGH 2021
• Table 22 : GLOBAL MARKET FOR THZ DENTAL CARIES IMAGING EQUIPMENT, THROUGH 2021
• Table 23 : MARKET FOR CHIRAL METAMATERIALS, THROUGH 2021
• Table 24 : METAMATERIALS MARKET IN QUANTUM ENCRYPTION APPLICATIONS, THROUGH 2021
• Table 25 : METAMATERIALS MARKET IN THROUGH 2021
• Table 26 : METAMATERIALS MARKET IN CATALYSIS APPLICATIONS, THROUGH 2021
• Table 27 : CONSUMPTION OF ASSYMETRIC CATALYSTS IN PHARMACEUTICALS PRODUCTION, THROUGH 2021
• Table 28 : CONSUMPTION OF ASSYMETRIC CATALYSTS IN OTHER CHEMICALS PRODUCTION, THROUGH 2021
• Table 29 : MARKET FOR PHOTONIC CRYSTALS, THROUGH 2021
• Table 30 : GLOBAL MARKET FOR PHOTONIC CRYSTAL FIBER USED IN FIBER LASER APPLICATIONS, THROUGH 2021
• Table 31 : GLOBAL MARKET FOR FIBER LASERS, THROUGH 2021
• Table 32 : GLOBAL MARKET FOR HIGH-BRIGHTNESS LEDS, THROUGH 2021
• Table 33 : GLOBAL CONSUMPTION OF PHOTONIC CRYSTALS IN THE FABRICATION OF HB-LEDS, THROUGH 2021
• Table 34 : MARKET FOR PHOTONIC CRYSTAL-BASED PHOTOVOLTAICS AND RELATED CONSUMPTION OF PHOTONIC CRYSTALS, THROUGH 2021
• Table 35 : MARKET FOR PHOTONIC CRYSTAL-BASED DATA STORAGE PRODUCTS AND RELATED CONSUMPTION OF PHOTONIC CRYSTALS, THROUGH 2021
• Table 36 : GLOBAL MARKET FOR QUANTUM DOTS IN BIODETECTION APPLICATIONS, THROUGH 2021
• Table 37 : GLOBAL MARKET FOR PHOTONIC CRYSTAL FLUORESCENCE ENHANCERS, THROUGH 2021
• Table 38 : GLOBAL MARKET FOR HIGH-PERFORMANCE PROCESSORS, THROUGH 2021
• Table 39 : GLOBAL MARKET FOR HIGH-PERFORMANCE ALL-OPTICAL PROCESSORS, THROUGH 2021
• Table 40 : GLOBAL MARKET FOR PHOTONIC CRYSTAL-BASED DISPLAYS AND RELATED CONSUMPTION OF PHOTONIC CRYSTAL MATERIALS, THROUGH 2021
• Table 41 : GLOBAL MARKET FOR PHOTONIC CRYSTAL ADD/DROP FILTERS, THROUGH 2021
• Table 42 : MARKET FOR SUPERCONDUCTING POLYMER METAMATERIALS, THROUGH 2021
• Table 43 : GLOBAL MARKET FOR SPECIALIZED HPC PROCESSORS, THROUGH 2021
• Table 44 : MARKET FOR SUPERCONDUCTING INTEGRATED CIRCUITS USED IN QUANTUM AND OTHER HIGH-PERFORMANCE AND RELATED CONSUMPTION OF METAMATERIALS, THROUGH 2021
• Table 45 : MARKET FOR SUPERCONDUCTING ELECTRIC TRANSMISSION WIRES AND RELATED CONSUMPTION OF METAMATERIALS, THROUGH 2021
• Table 46 : MARKET FOR EXTREME-PARAMETER METAMATERIALS, THROUGH 2021
• Table 47 : MEDICAL DEVICE MARKET FOR EXTREME-PARAMETER METAMATERIALS, THROUGH 2021
• Table 48 : GLOBAL MARKET FOR NANOSTRUCTURED STEEL SUTURE NEEDLES, THROUGH 2021
• Table 49 : GLOBAL CONSUMPTION OF CONVENTIONAL AND NANOSTRUCTURED TITANIUM IN MEDICAL IMPLANTS, THROUGH 2021
• Table 50 : GLOBAL CONSUMPTION OF NANOSTRUCTURED STEEL, THROUGH 2021
• Table 51 : GLOBAL CONSUMPTION OF NANOSTRUCTURED STEEL COATINGS, THROUGH 2021
• Table 52 : GLOBAL CONSUMPTION OF NANOSTRUCTURED STRUCTURAL STEEL, THROUGH 2021
• Table 53 : GLOBAL CONSUMPTION OF MAGNETIC NANOCOMPOSITES FOR ELECTRICAL AND ELECTRONIC APPLICATIONS, THROUGH 2021
• Table 54 : MARKET FOR ACOUSTIC METAMATERIALS, THROUGH 2021
• Table 55 : METAMATERIALS MARKET FOR ULTRASOUND IMAGING APPLICATIONS, THROUGH 2021
• Table 56 : ACOUSTIC METAMATERIALS MARKET IN OUTDOOR NOISE BARRIERS, THROUGH 2021
• Table 57 : ACOUSTIC METAMATERIALS MARKET IN SEISMIC PROTECTION APPLICATIONS, THROUGH 2021
• Table 58 : MAJOR U.S. METAMATERIALS PATENTS, TO NOVEMBER 15, 2011

List of Figures

• Summary Figure : GLOBAL MARKET FOR METAMATERIALS APPLICATIONS BY MATERIAL TYPE, 2011-2021
• Figure 1 : TRENDS IN THE GLOBAL MARKET FOR METAMATERIALS, 2010 - 2021
• Figure 2 : TRENDS IN THE METAMATERIALS MARKET BY METAMATERIAL TYPE, 2010 - 2021
• Figure 3 : TRENDS IN THE METAMATERIALS MARKET BY END USE, 2010 - 2021
• Figure 4 : TRENDS IN THE ARTIFICIAL DIELECTRICS MARKET, 2010 - 2021
• Figure 5 : TRENDS IN THE ARTIFICIAL DIELECTRICS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 6 : NEGATIVE REFRACTION
• Figure 7 : TRENDS IN THE NEGATIVELY REFRACTIVE METAMATERIALS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 8 : SPLIT-RING RESONATOR
• Figure 9 : TRENDS IN THE THZ-ACTIVE METAMATERIALS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 10 : INTRAOPERATIVE IMAGING TECHNOLOGIES MARKET SHARES, 2010
• Figure 11 : CHIRALITY
• Figure 12 : OPTICALLY ACTIVE CHIRAL METAMATERIAL
• Figure 13 : TRENDS IN THE CHIRAL METAMATERIALS MARKET, 2010 - 2021
• Figure 14 : TRENDS IN THE CHIRAL MATERIALS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 15 : TRENDS IN THE PHARMACEUTICAL MARKET FOR ASYMMETRIC CATALYSTS, 2010 - 2021
• Figure 16 : PHOTONIC CRYSTAL STRUCTURE
• Figure 17 : 2D VERSUS 3D PHOTONIC CRYSTALS
• Figure 18 : PHOTONIC CRYSTAL POINT DEFECT
• Figure 19 : WOOD PILE STRUCTURE
• Figure 20 : AUTOCLONED CRYSTAL STRUCTURE
• Figure 21 : GLOBAL MARKET TRENDS FOR PHOTONIC CRYSTAL METAMATERIALS, 2010 - 2021
• Figure 22 : TRENDS IN THE PHOTONIC CRYSTALS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 23 : TRENDS IN THE SUPERCONDUCTING POLYMER METAMATERIALS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 24 : TRENDS IN THE EXTREME-PARAMETER METAMATERIALS MARKET BY APPLICATION TYPE, 2010 - 2021
• Figure 25 : TRENDS IN THE ACOUSTIC METAMATERIALS MARKET BY APPLICATION TYPE, 2010-2021
• Figure 26 : RECENT U.S. METAMATERIALS-RELATED PATENTS ISSUED TO 11/15/1011

Press Release

2016年超材料(Metamaterial)•應用的全球市場將達到7億5,870萬美元規模

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