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INTRODUCTION
STUDY BACKGROUND Nanophotonics technologies play an increasingly important role in various sectors of the global economy. However, various technical, marketing and other hurdles need to be overcome before nanophotonics can realize their full potential.Most analyses of the nanophotonics market focus on the development of new nanophotonics technologies and applications, rather than quantifying the potential market for these technologies. These analyses have made valuable contributions to raising investors' awareness of and interest in nanophotonics.
However, these analyses by themselves do not provide sufficient information to guide corporate or individual investment decisions. Investors require additional information, such as the size of specific nanophotonics markets, prices, competition, and potential regulation, as provided in this report.
STUDY GOALS AND OBJECTIVES This report is an update of an earlier BCC Research report, published in 2006. Its goal is to provide investors and others with the latest information on the commercial potential of various nanophotonics technologies and to complement the growing body of technical information. Specific objectives include identifying segments of the nanophotonics market with the greatest commercial potential in the near to mid-term (2011-2016), projecting future demand in these segments and evaluating the challenges that must be overcome for each segment to realize its potential in order to estimate the probability of successful commercialization.INTENDED AUDIENCE This report is intended especially for entrepreneurs, investors, venture capitalists and other readers who need to know where the nanophotonics market is headed in the next five years. Other readers who should find the report particularly valuable include nanotechnology marketing executives and government officials associated with the U.S. National Nanotechnology Initiative and other government programs to promote the development of the nanotechnology industry. The report's findings and conclusions should also be of interest to the broader nanotechnology community.SCOPE AND FORMAT The study addresses the global market for nanophotonics devices. Nanophotonic devices are defined as devices that interact with light at the nanoscale level. ("Nanoscale" is defined as having at least one dimension measuring less than 100 nanometers, or billionths of a meter.)As defined above, nanophotonics are closely related to nano-optoelectronics. Many photonic devices, such as diodes, are also commonly classified as optoelectronic devices. This study does not exclude any application that meets the basic definition of a photonic device, even if it is also classifiable as an optoelectronic device.
Major types of nanoscale devices covered in this report include optical fiber, channel add/drop filters, optical switches and gates, light-emitting diodes, optical amplifiers, solar cells and holographic memory. The report format includes the following major elements:
Executive summaryDefinitionsMilestones in the development of nanophotonicsCurrent and potential nanophotonics applicationsApplications and end-users with the greatest commercial potential through 2016Global nanophotonics market trends, 2010-2016Factors that will influence the long-term development of nanophotonicsMarket shares and industry structure
METHODOLOGY AND INFORMATION SOURCES
Projecting the market for emerging technologies such as most nanophotonics devices, whose commercial potential has not yet been proven, is a challenging task, which may help to explain why most analysts so far have focused on technology assessments. This report uses a multi-phase approach to identify the nanophotonics applications and devices with the greatest commercial potential and quantify the resulting market for these devices, as described below.
In the first phase of the analysis, we identified a "long list" of potential nanophotonics applications (including applications that are still under development) and mapped them against potential applications such as data storage, computing, sensing and others.
In the second phase, we eliminated those nanophotonics applications and devices that appear to have little likelihood of making it into commercial production in the next five years, determined by a literature review and statements from industry sources. The result of phase two was a "short list" of devices with the greatest near- to mid-term commercial potential.
The third phase focused on quantifying the potential broader market for each short-listed nanophotonics device and identifying the main prerequisites for commercial success. Various methodologies and data sources were used to develop the projections, including trend line projections, input-output analysis and estimates of future demand from industry sources. Dozens of industry sources were consulted in the preparation of this report.
ANALYST CREDENTIALS Andrew McWilliams, the author of this report, is a partner in the Boston-based international technology and marketing consulting firm, 43rd Parallel LLC. He is also the author of numerous Business Communications Co. reports, including the predecessor to this report as well as several related market assessments, such as NAN031D Nanotechnology: A Realistic Market Assessment, NAN021D Nanocomposites, Nanoparticles, Nanoclays, and Nanotubes, and AVM067A Metamaterials: Technologies and Global Markets.TABLE OF CONTENTS CHAPTER ONE: INTRODUCTION . 1STUDY BACKGROUND 1
STUDY GOALS AND OBJECTIVES . 1
INTENDED AUDIENCE 1
SCOPE AND FORMAT 2
METHODOLOGY AND INFORMATION SOURCES. 2
ANALYST CREDENTIALS 3
RELATED BCC RESEARCH REPORTS . 3
BCC ONLINE SERVICES 4
DISCLAIMER . 4
CHAPTER TWO: EXECUTIVE SUMMARY . 5
SUMMARY TABLE NANOPHOTONIC DEVICES MARKET, THROUGH
2016 ($ MILLIONS) . 5
SUMMARY FIGURE NANOPHOTONIC DEVICES MARKET, 2010-2016
($ MILLIONS) 6
CHAPTER THREE: OVERVIEW 7
GENERAL DESCRIPTION 7
DEFINITIONS . 7
Photonics 7
Nanophotonics . 7
BRIEF HISTORY OF PHOTONICS 8
Brief History of Photonics (Continued) . 9
TECHNOLOGY ASSESSMENT 10
TECHNOLOGY PLATFORMS 10
TABLE 1 PHOTONICS TECHNOLOGY PLATFORMS 11
Photonic Crystals . 11
Description 11
FIGURE 1 PHOTONIC CRYSTAL STRUCTURE . 12
Properties 13
Two Dimensional vs. Three Dimensional
Crystals 13
FIGURE 2 2D VS. 3D PHOTONIC CRYSTALS . 14
Defects . 14
FIGURE 3 PHOTONIC CRYSTAL POINT DEFECT 15
Composition . 15
Static vs. Tunable Crystals . 16
Applications . 16
Fabrication 17
Micromachining . 18
Microlithographic Techniques . 18
Layer-by-Layer Fabrication 19
FIGURE 4 "WOODPILE" STRUCTURE . 19
Autocloning . 20
FIGURE 5 AUTOCLONED CRYSTAL STRUCTURE . 21
Holographic Lithography . 21
Multibeam Interference Lithography . 22
Glancing Angle Deposition 22
Stack Methods . 23
Low Temperature Deposition . 23
Self-Assembly 24
Opal Method 24
Other Self-Assembly Techniques . 24
Drawing and Extruding 25
Patents 26
FIGURE 6 TRENDS IN U.S. PHOTONIC CRYSTAL PATENTS, 2000–
2011 (NUMBER OF PATENTS) 26
TABLE 2 PHOTONIC PATENTS BY PATENT HOLDER (NUMBER/%
OF PATENTS) 27
FIGURE 7 LEADING PHOTONIC CRYSTAL PATENT HOLDERS
(PERCENT OF PATENTS) . 28
Manufacturers . 28
TABLE 3 PHOTONIC CRYSTAL MANUFACTURERS 29
Nanowires 29
Description 29
Properties 30
Applications . 30
Fabrication 30
Patents 31
TABLE 4 U.S. NANOWIRE PATENTS BY PATENT HOLDER
(NUMBER/% OF PATENTS) . 31
FIGURE 8 LEADING NANOWIRE PATENT HOLDERS (PERCENT OF
U.S. PATENTS) 32
Nanoribbons . 32
Description 32
Properties 33
Applications . 33
Fabrication 33
Patents 33
Nanotubes 34
Description 34
Photonic Properties . 34
Photonic Applications . 35
Fabrication 35
Patents 36
TABLE 5 U.S. PATENTS RELATING TO PHOTONIC APPLICATIONS
OF CARBON NANOTUBES BY PATENT HOLDER (NUMBER/% OF
PATENTS) 37
FIGURE 9 LEADING HOLDERS OF U.S. PATENTS RELATING TO
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