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Transparent Conductive Films (TCF) 2014-2024: Forecasts, Markets, Technologies

Name: Transparent Conductive Films (TCF) 2014-2024: Forecasts, Markets, Technologies
Brand: IDTechEx

Assessment of ITO alternatives including silver nanowires, metal mesh, carbon nanotubes, graphene and others

By Raghu Das

모두 보기 설명 목차, 표 및 그림 목록 자주 묻는 질문 가격

The transparent conductive film and glass markets are complex and fragmented along many application lines. The market is booming with growth being fuelled mostly by tablets and penetration of touch capability in more mobile phones, notebooks and monitors. OLED lighting, OPV and DSSCs are also potentially large area markets, although growth here will initially be slow due to strong competition, prevailing unfavourable market conditions, and low technology market-readiness levels.

New market drivers

The market is fast being transformed. New applications and market trends are changing the requirement landscape, and in many instances stretching it beyond what the incumbent solution can readily achieve. The key drivers are market tendencies towards (a) large-sized devices, (b) low power consumption, (c) minimal reflection, (d) thinness, (e) robustness and/or flexibility, (f) ease of patterning, (g) simplified value chain, and (h) low cost.

A vast multitude of technologies and players worldwide are emerging and/or re-positioning to fight for a slice of this booming yet intensely competitive market space. These technologies include silver nanowires, organic transparent conductors, carbon nanotubes, graphene, fine wire, and a variety of metal mesh and novel nanoparticle-based solutions.

TCF and TCG technology market share in the touch notebook sector*

*Each colour corresponds to a different TCF and TCG technology (e.g., ITO-on-Glass, metal mesh, etc). For more information please refer to our report

Source: IDTechEx

Complex range of options

The multiplicity of options is giving rise to market uncertainty and confusion. Indeed, the decision-making and investment process is made more complex by the fact that there is no one-size-fits-all solution and/or a clear winner. This is because each technology option presents several trade-offs between sheet resistance, transmittance, flexibility, haze, cost and compatibility with existing value chain; while each players is working off a different business plan and technology portfolio/capability.

Full analysis and assessment

This report provides a detailed and complete assessment of incumbent and emerging technology solutions. For each technology, IDTechEx assess production method, key cost drives, key figures-of-merit including sheet resistance, optical transmission, haze, flexibility, surface smoothness, stability, etc. IDTechEx provides a SWOT analysis for each technology. Moreover, IDTechEx identifies all suppliers globally, outlining their commercialisation progress.

IDTechEx has built a detailed, granular and accurate market forecast model. IDTechEx has used its forecast model to provide the following key market data charts:

Ten year forecasts for the following applications in unit sales or market value

Mobile and smart phones
Notebooks and touch notebooks
Montiors and touch monitors
Tablets
OLED lighting
Organic phototovotaics
Dye-sensitised solar cells
Electroluminescent displays

Ten year market forecasts for TCF and TCG by area and value for the above applications.

Ten year market forecasts in area, market share, and value for the following technologies

ITO-on-Glass
ITO-on-PET
Silver nanowires
Carbon nanotubes
Graphene
PEDOT
Metal mesh

Market intelligence

100+ companies are profiled including 35+ detailed profiles based on direct interviews and company visits. The rest are profiled based on conference attendance, tradeshow visits, patent searchers and/or web searches.

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Table of Contents

1.	EXECUTIVE SUMMARY
1.1.	Key trends
1.1.	Benchmarking different TCF and TCG technologies on the basis of sheet resistance, optical transmission, ease of customisation, haze, ease of patterning, thinness, stability, flexibility, reflection and low cost. The technology com
1.2.	Technology Assessment
2.	MARKETS ANALYSIS
2.1.	Smart Phones
2.1.	Ten year market forecasts in million USD for TCFs and TCGs by application
2.2.	Ten year market forecast in million USD for TCFs and TCGs by application
2.2.	Tablets
2.3.	Notebooks
2.3.	Ten-year market forecast in Km sqm for TCFs and TCGs broken by technology
2.4.	Ten-year market forecast in million USD for TCFs and TCGs broken by technology
2.4.	Monitors
2.5.	Mobile, tablet, notebook, monitor and TV displays
2.6.	OLED lighting
2.7.	OPV and DSSCs
2.8.	Electroluminescent Displays
2.9.	Key market forecasts
2.10.	Players
3.	OVERVIEW OF TOUCH TECHNOLOGIES
3.1.	Types of touch technology
3.2.	Features of touch technologies
4.	TARGET MARKETS- PERFORMANCE TARGETS, MARKET DRIVERS, AND MARKET DYNAMICS
4.1.	The typical sheet resistance values used in different applications such as touch screens, smart windows, LCDs, OLED, and solar cells
4.2.	Ten year forecast for mobile phone and smart phone sales
4.2.	Smart phones and tablets
4.3.	Notebooks and monitors
4.3.	Tablets sales as a function of year between 2013 and 2023
4.3.	Key technical requirements set by each application.
4.4.	Sales of standard and touch notebooks as a function of year between 2013 and 2023. Market share for touch notebooks as a function of year in the total notebook market
4.4.	OLED, OPV, DSSC
4.5.	Other thin film
4.5.	Sales of standard and touch monitors as a function of year between 2013 and 2023. Market share for touch monitor as a function of year in the total monitor market
4.6.	OLED lighting market size as a function of year between 2013 and 2013 in million USD
4.6.	LCD Displays
4.7.	Transparent heaters
4.7.	OPV and DSSC market size as a function of year between 2013 and 2013 in million USD
4.8.	Structure of TFT-LCD devices including the position of the transparent conducting layers
4.8.	EMI shielding
4.9.	Summary
4.9.	Structure of a typical LCD backplane layout
4.10.	Comparing the change in temperature as a function of heating time between an ITO and a self-assembled nanoparticle transparent heater
5.	KEY MARKET DRIVERS AND CHANGING LANDSCAPE
5.1.	Large- sized devices
5.1.	Touch capability is coming onto ever larger screens
5.2.	Examples of flexible displays
5.2.	Current-driven devices
5.3.	Flexibility
5.4.	Cost
5.5.	Low power consumption
6.	TECHNOLOGY OPTIONS
6.1.	Indium tin oxide
6.1.	A typical sputtering apparatus used in deposing ITO thin films
6.1.	Summary of deposition technologies used by each metal mesh producer
6.1.2.	Large area
6.1.3.	Index-Matching
6.1.4.	Cost
6.1.5.	Thinness
6.1.6.	SWOT analysis
6.1.7.	Current uses
6.1.8.	Future uses
6.1.9.	Players
6.2.	Non-ITO oxides
6.2.	Optical transmission as a function of sheet resistance for ITO-on-PET sold by main industry suppliers
6.2.	Benchmarking different TCF and TCG technologies on the basis of sheet resistance, optical transmission, ease of customisation, haze, ease of patterning, thinness, stability, flexibility, reflection and low cost. The technology com
6.3.	Sheet resistance as a function of thickness for sputtered ITO on glass
6.3.	Silver nanowires
6.3.2.	SWOT analyses
6.3.3.	Current uses
6.3.4.	Future trends and market drivers
6.3.5.	Players
6.4.	Graphene
6.4.	Optical transmission as a function of wavelength (nm) for ITO on glass with different sheet resistances
6.4.2.	SWOT analyses
6.4.3.	Current uses
6.4.4.	Future trends and market drives
6.4.5.	Players
6.5.	Carbon nanotubes
6.5.	Different touch sensor configurations
6.5.2.	SWOT analyses
6.5.3.	Current uses
6.5.4.	Future trends and market drives
6.5.5.	Players
6.5.6.	PDOT:PSS
6.5.7.	SWOT analyses
6.5.8.	Current uses
6.5.9.	Future trends and market drives
6.5.10.	Players
6.6.	Metal Mesh
6.6.	Cost of ITO transparent conductive films compared to CNT ones
6.6.2.	Direct printing
6.6.3.	SWOT analyses
6.6.4.	Current uses
6.6.5.	Future trends
6.6.6.	Players
6.6.7.	Embossing/Imprinting
6.6.8.	SWOT analyses
6.6.9.	Current uses
6.6.10.	Future trends
6.6.11.	Players
6.6.12.	Photolithography and etching
6.6.13.	SWOT analyses
6.6.14.	Current uses
6.6.15.	Future trends
6.6.16.	Players
6.6.17.	Summary of metal mesh TCF
6.7.	Micro fine wire
6.7.	Normalised conductance as a function of radius
6.7.1.	SWOT analyses
6.7.2.	Current uses
6.7.3.	Future Trends
6.7.4.	Players
6.8.	Other nanotechnology-enabled TCFs
6.8.	Schematic showing the bending experiment carried out on ITO-on-PET
6.8.2.	Players
6.9.	Benchmarking
6.9.	Flexible, thin, and light ITO on PET
6.10.	ITO cracking when bent too much and/or too many times
6.11.	Sheet resistance as a function of radius of curvature
6.12.	Efficiency of two OPV cells as a function of cells size
6.13.	Comparing a complicated touch solution based on ITO with a simple version based on CNTs
6.14.	Price of primary indium as a function of year
6.15.	Market share of the total global production of primary indium by country
6.16.	Total annual indium consumption as a function of year
6.17.	Sheet resistance as a function of thickness for different TCF technologies
6.18.	ITO on film production capacity worldwide
6.19.	Images of silver nanowire networks with different surface coverage levels
6.20.	Change in optical transmission as a function of surface coverage
6.21.	A simplified schematic of a manufacturing process flow
6.22.	Transmission as a function of sheet resistance
6.23.	Sheet resistance as a function of bending angle
6.24.	Transparent silver nanowire TCF
6.25.	Flexible roll of silver nanowire coated films used as a transparent EMI shield
6.26.	Commodity price of silver as a function of year between 1976 and 2013
6.27.	All-in-One LG monitors using silver nanowires
6.28.	Huawei smart phone with Cambrios's silver nanowires
6.29.	Process for manufacturing graphene using the chemical vapour deposition technique
6.30.	Process flow for a typical transfer process of graphene from a copper substrate and onto a polymer sheet
6.31.	The process flow for transferring graphene from Cu substrates using self-release layers
6.32.	Process flow for transfer graphene from a Cu substrate using a bubbling process
6.33.	Example of large-sized cylindrical copper furnace
6.34.	Sheet resistance as a function of transmittance for best laboratory scale graphene derived using the oxidation-reduction techniques (it produces powders)
6.35.	Sheet resistance as a function of transmittance for best laboratory scale graphene derived using CVD (it produces sheets)
6.36.	Sheet resistance as a function of transmission for graphene compared with ITO
6.37.	Sheet resistance as a function of thickness for different TCF technologies
6.38.	Sheet resistance as a function of bending angle for graphene, CNT and ITO films
6.39.	Flexible graphene transparent conductive sheet
6.40.	Patent filing by company or institution and by patent authority 2012
6.41.	Prototype of a graphene-enabled touch sensor
6.42.	Prototype of a large-sized graphene transparent conductive film
6.43.	Types and quality of CNTs
6.44.	Single-walled carbon nanotube schematic
6.45.	Single-walled carbon nanotube - real image
6.46.	Steps required to separate the SWCNTs into pure semiconducting or metallic ones
6.47.	The deposition roll process
6.48.	CNT networks without full surface coverage
6.49.	High concentration of CNTs on a surface
6.50.	Sheet resistance as a function of optical tranmission
6.51.	Sheet resistance of laboratory scale purified SWCNT
6.52.	Sheet resistance of SWNTs vs. MWNTs
6.53.	Sheet resistance of SWCNTs deposited using different techniques
6.54.	Variations in sheet resistance as a function of bending cycle
6.55.	CNT film applied to a 3D surface
6.56.	Comparing the stack complexity and calculated reflection of CNT-based and ITO-based TCFs
6.57.	Example of CNT TFC-based mobile phone
6.58.	Example of CNT transparent conductive film
6.59.	Example of flexible CNT transpatenc conductive film
6.60.	Example of flexible CNT transpatenc conductive film
6.61.	Chemical structure of PDOT:PSS
6.62.	Schematic picture of a dispersed gel particle
6.63.	A process flow for patterning PDOT:PSS using photolithography and CELVIOSTM etchant
6.64.	A process flow for patterning PDOT:PSS using gravure (or screen) printing and CELVIOSTM etchant
6.65.	Comparing the performance of ITO on foil (similar to ITO on PET) with PEDOT:PSS in 2002
6.66.	Optical transmission (%) as a function of wavelength for different grades of PDOT:PSS on glass
6.67.	Improvements in performance of PDOT:PSS
6.68.	Improvement in conductivity for PDOT:PSS has a function of year
6.69.	Optical transmission as a function of sheet resistance for PDOT:PSS/PET films (here referred to as Baytron) compared with common ITO-on-PET films on the market
6.70.	Optical transmission (%) of PDOT/PET and PET as a function of wavelength (screen printed PDOT)
6.71.	Relative changes in sheet resistance as a function of number of bending cycles (bending radius 8mm) for ITO/PET and PDOT:PSS/PET films
6.72.	Changes in sheet resistance as a function of radius of curvature for ITO/PET and PEDOT:PSS/PET films
6.73.	Sheet resistance as a function distance from fixed point in PDOT:PSS films
6.74.	Silver nanowires, metal mesh ad PDOT
6.75.	Change in sheet resistance as a function of exposure time to effective sunlight
6.76.	A Navigation system with a resistive touch technology (continous film) incorporating PDOT:Fil
6.77.	A laptop incorporating a PDOT:PSS as the sensing layer and resistive touch technology
6.78.	A small-sized capacitive tocuh sensor using PDOT:PSS
6.79.	Various touch-enabled mobile front covers incorporating PDOT:PSS
6.80.	An OLED lighting device with PDOT:PSS TCF layer
6.81.	A 12.5 cm2 OLED on PET with a PDOT transparent conductive layer
6.82.	A typical device stack for PDOT:PSS TCF films coated by Eastman Kodak
6.83.	Various metal grid patterns
6.84.	Concept behind a metal grid TCF
6.85.	Transparent conductive films printed using high precision screen printing on PET substrates
6.86.	Sheet resistance as a function of optical transmission for different materials
6.87.	Comparing optical clarity of TCFs
6.88.	A schematic of the manufacturing process flow used by UniPixel
6.89.	Various touch sensor film configurations produced by UniPixel. suitable for projective capacitive
6.90.	Metal mesh pattern structure produced by UniPixel
6.91.	Product characteristics for transparent conductive films produced using embossing/plating by UniPixel
6.92.	Nanoparticle tracks embedded in the substrate
6.93.	The difference between embedded and overlaid track configuration
6.94.	A schematic giving insight into MNTech's manufacturing process and a table outlining performance levels
6.95.	Manufacturing process flow for making metal mesh TCFs using silver halides
6.96.	Metalized mesh (etched copper metalized film
6.97.	Picture and pattern of transparent thermally conductive film
6.98.	Key performance data characteristics 3M's metal mesh TCFs
6.99.	An example of a photo-lithographically-patterned silver metal mesh TCF
6.100.	A suggested production method for creating 3M's silver metal mesh based on their patents
6.101.	A schematic of the Rolith's production process using a rolling photolithography equipment
6.102.	Comparing transmission vs sheet resistance of Rolith's metal mesh again Cambrios, Cima Nanotech, Heraeus, Canatu's and Unidym's products
6.103.	Transmission as a function of wavelength for Rolith's transparent conductors
6.104.	Image of metal mesh structure created using rolling photolithography
6.105.	Application areas using fine micro wire
6.106.	The silver nanoparticle self-assembly process
6.107.	Overlapping silver nanoparticle rings creating a transparent conductive film layer
7.	MARKET SHARE, GROWTH RATES AND SIZES BY APPLICATION
7.1.	Key conclusions
7.1.	Total coverage area for transparent conductive films and glass as a function of year between 2013 and 2024
7.1.	Average selling prices for different technologies as a function of year between 2013 and 2023 in $/m2
7.2.	Ten year market forecast for graphene adoption in transparent conductive film and glass markets (US$ million)
7.2.	Total market size for transparent conductive films and glass as a function of year between 2013 and 2024
7.2.	Smart phones (touch)
7.3.	Tablets (touch)
7.3.	Total market size for transparent conductive films and glass as a function of year between 2013 and 2024 (including LCD displays)
7.4.	Ten-year market forecast for conductive films and glass in the smart phone sector
7.4.	Notebooks (touch)
7.5.	Monitors (touch)
7.5.	Market share evolution for transparent conductive film and glass technologies in the smart phone (touch) sector as a function of year between 2013 and 2024
7.6.	Ten-year market forecast for conductive films and glass in the tablet sector
7.6.	Mobile, tablet, notebook, monitor and TV displays
7.7.	OLED Lighting
7.7.	Market share evolution for transparent conductive film and glass technologies in the tablet (touch) sector as a function of year between 2013 and 2023
7.8.	Ten-year market forecast for conductive films and glass in the touch notebook sector
7.8.	Organic photovoltaics
7.9.	Dye Sensitised Solar Cells
7.9.	Market share evolution for transparent conductive film and glass technologies in the touch notebook sector as a function of year between 2013 and 2024
7.10.	Ten-year market forecast for conductive films and glass in the touch monitor sector
7.10.	Electroluminescent displays
7.11.	Market growth rate and size by technology
7.11.	Market share evolution for transparent conductive film and glass technologies in the touch monitor sector as a function of year between 2013 and 2024
7.12.	Ten-year market forecast for conductive films and glass in the displays sector (mobile, tablet, notebook, monitor and LCD TV)
7.12.	Averages selling point projections
7.13.	Graphene
7.13.	Ten-year market forecast for conductive films and glass in the OLED lighting sector
7.14.	Market share evolution for transparent conductive film and glass technologies in the OLED lighting sector as a function of year between 2013 and 2024
7.14.	Carbon nanotubes
7.15.	Metal mesh
7.15.	Ten-year market forecast for conductive films and glass in the OPV sector
7.16.	Market share evolution for transparent conductive film and glass technologies in the OPV sector as a function of year between 2013 and 2024
7.16.	Silver nanowires
7.17.	ITO on PET
7.17.	Ten-year market forecast for conductive films and glass in the DSSC sector
7.18.	Market share evolution for transparent conductive film and glass technologies in the DSSC sector as a function of year between 2013 and 2024
7.18.	ITO on Glass
7.19.	PEDOT
7.19.	Ten-year market forecast for conductive films and glass in the EL display sector
7.20.	Market share evolution for transparent conductive film and glass technologies in the EL display sector as a function of year between 2013 and 2023
7.21.	Ten year market forecast for transparent conductive films and glass across all applications broken down by technology
7.22.	Ten year market forecast for transparent conductive films and glass across all applications broken down by technology
7.23.	Ten year forecast for carbon nanotube application area growth
7.24.	Ten year market forecast for carbon nanotubes in different TCF markets
7.25.	Ten year forecast for metal mesh application area growth
7.26.	Ten year market forecast for metal mesh in different TCF markets
7.27.	Ten year forecast for silver nanowires application area growth
7.28.	Ten year market forecast for silver nanowires in different markets
7.29.	Ten year forecast for ITO-on-PET application area growth
7.30.	Ten year market forecast for ITO-on-PET in different TCF markets
7.31.	Ten year forecast for ITO-on-Glass application area growth
7.32.	Ten year market forecast for ITO-on-Glass in different markets
7.33.	Ten year market forecast for ITO-on-Glass in different markets
7.34.	Ten year forecast for PEDOT and other organic transparent conductor application area growth
7.35.	Ten year market forecast for PEDOT and other organic transparent conductors in different markets
8.	COMPANY INTERVIEWS
8.1.	Arkema, France
8.2.	Blue Nano, USA
8.3.	Bluestone Global Tech, USA
8.4.	Cambrios, USA
8.5.	Canatu, Finland
8.6.	Carestream Advanced Materials, USA
8.7.	Cima Nanotech, USA
8.8.	ClearJet, Israel
8.9.	Dai Nippon Printing, Japan
8.10.	Displax Interactive Systems, Portugal
8.11.	Goss International Americas, USA
8.12.	Graphene Laboratories, USA
8.13.	Graphene Square, South Korea
8.14.	Heraeus, Germany
8.15.	Nanogap, Spain
8.16.	Nanotech and Beyond, South Korea
8.17.	O-Film, China
8.18.	Peratech, UK
8.19.	PolyIC, Germany
8.20.	Poly-Ink, France
8.21.	Rolith, USA
8.22.	Seashell Technology, USA
8.23.	Showa Denko, Japan
8.24.	Sinovia Technologies, USA
8.25.	SouthWest NanoTechnologies, USA
8.26.	Unidym, USA
8.27.	UniPixel, USA
8.28.	University of Exeter, UK
8.29.	Visual Planet, UK
8.30.	XinNano Materials, Taiwan
8.31.	Zytronic, UK
9.	COMPANY PROFILES
9.1.	Agfa-Gevaert, Belgium
9.1.	Typical properties on PET with bar coater
9.2.	Key performance data characteristics 3M's metal mesh TCFs
9.2.	3M, USA
9.3.	Atmel, USA
9.3.	Yielded cost per unit area of TCF for touch panel applications
9.4.	Tiny copper wires can be built in bulk and then "printed" on a surface to conduct current, transparently.
9.4.	C3Nano, USA
9.5.	Chasm Technologies, USA
9.5.	Eastman Kodak HCF Film
9.6.	Opportunity for PEDOT in the Display industry
9.6.	Cheil Industries, South Korea
9.7.	Chimei Innolux, Taiwan
9.7.	Performance of PEDOT formulation from Eastman Kodak versus ITO
9.8.	CNT Ink Production Process
9.8.	Chisso Corp., Japan
9.9.	Conductive Inkjet Technologies (Carlco), USA
9.9.	Target application areas of Eikos
9.10.	Transmittance (%) as a function of wavelength (nm) for organic conductive polymers and ITO.
9.10.	Dontech Inc., USA
9.11.	Duke University, USA
9.11.	Comparison of organic conductive polymers and configuration of the developed organic conductive polymer film
9.12.	Gunze's flexible display, presented early 2009
9.12.	Eastman Kodak, USA
9.13.	Eikos, USA
9.13.	Picture and pattern of transparent thermally conductive film
9.14.	Efficiency of TCF vs cell size
9.14.	ELK, South Korea
9.15.	Evaporated Coatings Inc., USA
9.15.	Indium migration vs other TCFs
9.16.	A schematic giving insight into MNTech's manufacturing process and a table outlining performance levels
9.16.	Evonik, Germany
9.17.	Fujifilm Ltd, Japan
9.17.	Ga:ZnO films on a glass panel with the inventors and scanning electron images of 3D transparent conducting electrodes
9.18.	The owners of Nicanti
9.18.	Fujitsu, Japan
9.19.	Gunze Ltd, Japan
9.19.	Nicanti Printaf project
9.20.	Transparent conductive film - ELECRYSTA
9.20.	Hitachi Chemical, Japan
9.21.	Holst Center, Netherlands
9.21.	Sales and operating profits for Nitto Denko
9.22.	Nitto Denko's product offerings for displays including ITO film
9.22.	Iljin Display, South Korea
9.23.	Institute of Chemical and Engineering Sciences (ICES), Singapore
9.23.	Transparent conductive film using organic semiconductors
9.24.	TCF solutions from Panipol
9.24.	Join Well Technology Company Ltd., Taiwan
9.25.	J-Touch, Taiwan
9.25.	Polychem PEDOT Polymer Coating
9.26.	Patterned Sample by the New Technology
9.26.	KAIST, South Korea
9.27.	Komoro, Japan
9.27.	JEFF FITLOW -Yu Zhu, a postdoctoral researcher at Rice University, holds a sample of a transparent electrode that merges graphene and a fine aluminum grid
9.28.	A hybrid material that combines a fine aluminum mesh with a single-atom-thick layer of graphene
9.28.	KPT Shanghai Keyan Phosphor Technology Co. Ltd., China
9.29.	Lee Tat Industrial Development (LTI) Ltd, Hong Kong
9.29.	An electron microscope image of a hybrid electrode developed at Rice University
9.30.	Roll-to-roll CVD production of very large-sized flexible graphene films
9.30.	LG Chem, South Korea
9.31.	Maxfilm, South Koera
9.31.	ITO-on-PET film stack
9.32.	FLECLEAR structure
9.32.	Mianyang Prochema Plastics Co., Ltd., China
9.33.	Mirae/MNTec, South Korea
9.33.	Teijin's ELECLEAR ITO film
9.34.	New metal grid TCF technology developed by Toray
9.34.	Mitsui & Co. (U.S.A.), Inc., Mitsui Ltd., Japan
9.35.	Mutto Optronics, China
9.35.	Etched metal mesh TCF technology developed by Toray
9.36.	CNT TCF technology developed by Toray
9.36.	Nagase Corporation, Japan
9.37.	Nanopyxis, South Korea
9.38.	National Institute of Advanced Industrial Science and Technology (AIST), Japan
9.39.	National University of Singapore (NUS), Singapore
9.40.	Nicanti, Finland
9.41.	Nitto Denko, Japan
9.42.	Oike & CO., Ltd., Japan
9.43.	Oji Paper Group, Japan
9.44.	Panipol Ltd., Finland
9.45.	Perceptive Pixel, USA
9.46.	Polychem UV/EB, Taiwan
9.47.	Power Booster, China
9.48.	Rice University, USA
9.49.	Samsung Electronics, South Korea
9.50.	Sang Bo Corporation (SBK), South Korea
9.51.	Sekisui Nano Coat Technology Ltd., Japan
9.52.	Sheldahl, USA
9.53.	Sigma-Aldrich, USA
9.54.	Sony Corporation, Japan
9.55.	Sumitomo Metal Mining Co., Inc., Japan
9.56.	Suzutora, Japan
9.57.	TDK, Japan
9.58.	Teijin Kasei America, Inc. / Teijin Chemical, USA
9.59.	Top Nanosys, South Korea
9.60.	Toray Advanced Film (TAF), Japan
9.61.	Toyobo, Japan
9.62.	UCLA, USA
9.63.	Unidym, USA
9.64.	University of Michigan, USA
9.65.	VisionTek Systems Ltd., UK
9.66.	Young Fast Optoelectronics, Taiwan
	TABLES
	FIGURES

Frequently Asked Questions

About IDTechEx reports

What are the qualifications of the people conducting IDTechEx research?

Content produced by IDTechEx is researched and written by our technical analysts, each with a PhD or master's degree in their specialist field, and all of whom are employees. All our analysts are well-connected in their fields, intensively covering their sectors, revealing hard-to-find information you can trust.

How does IDTechEx gather data for its reports?

By directly interviewing and profiling companies across the supply chain. IDTechEx analysts interview companies by engaging directly with senior management and technology development executives across the supply chain, leading to revealing insights that may otherwise be inaccessible.

Further, as a global team, we travel extensively to industry events and companies to conduct in-depth, face-to-face interviews. We also engage with industry associations and follow public company filings as secondary sources. We conduct patent analysis and track regulatory changes and incentives. We consistently build on our decades-long research of emerging technologies.

We assess emerging technologies against existing solutions, evaluate market demand and provide data-driven forecasts based on our models. This provides a clear, unbiased outlook on the future of each technology or industry that we cover.

What is your forecast methodology?

We take into account the following information and data points where relevant to create our forecasts:

Historic data, based on our own databases of products, companies' sales data, information from associations, company reports and validation of our prior market figures with companies in the industry.
Current and announced manufacturing capacities
Company production targets
Direct input from companies as we interview them as to their growth expectations, moderated by our analysts
Planned or active government incentives and regulations
Assessment of the capabilities and price of the technology based on our benchmarking over the forecast period, versus that of competitive solutions
Teardown data (e.g. to assess volume of materials used)
From a top-down view: the total addressable market
Forecasts can be based on an s-curve methodology where appropriate, taking into account the above factors
Key assumptions and discussion of what can impact the forecast are covered in the report.

How can I be confident about the quality of work in IDTechEx reports?

Based on our technical analysts and their research methodology, for over 25 years our work has regularly received superb feedback from our global clients. Our research business has grown year-on-year.

Recent customer feedback includes:

"It's my first go-to platform"

- Dr. Didi Xu, Head of Foresight - Future Technologies, Freudenberg Technology Innovation

"Their expertise allows us to make data-driven, strategic decisions and ensures we remain aligned with the latest trends and opportunities in the market."

- Ralf Hug, Global Head of Product Management & Marketing, Marquardt

What differentiates IDTechEx reports?

Our team of in-house technical analysts immerse themselves in industries over many years, building deep expertise and engaging directly with key industry players to uncover hard-to-find insights. We appraise technologies in the landscape of competitive solutions and then assess their market demand based on voice-of-the-customer feedback, all from an impartial point of view. This approach delivers exceptional value to our customers—providing high-quality independent content while saving customers time, resources, and money.

Why should we pick IDTechEx research over AI research?

A crucial value of IDTechEx research is that it provides information, assessments and forecasts based on interviews with key people in the industry, assessed by technical experts. AI is trained only on content publicly available on the web, which may not be reliable, in depth, nor contain the latest insights based on the experience of those actively involved in a technology or industry, despite the confident prose.

How can I justify the ROI of this report?

Consider the cost of the IDTechEx report versus the time and resources required to gather the same quality of insights yourself. IDTechEx analysts have built up an extensive contact network over many years; we invest in attending key events and interviewing companies around the world; and our analysts are trained in appraising technologies and markets.

Each report provides an independent, expert-led technical and market appraisal, giving you access to actionable information immediately, rather than you having to spend months or years on your own market research.

Can I speak to analysts about the report content?

All report purchases include up to 30 minutes of telephone time with an expert analyst who will help you link key findings in the report to the business issues you're addressing. This needs to be used within three months of purchasing the report.

What is the difference between a report and subscription?

A subscription from IDTechEx can include more reports, access to an online information platform with continuously updated information from our analysts, and access to analysts directly.

Before purchasing, I have some questions about the report, can I speak to someone?

Please email research@idtechex.com stating your location and we will quickly respond.

About IDTechEx

Who are IDTechEx's customers?

IDTechEx has served over 35,000 customers globally. These range from large corporations to ambitious start-ups, and from Governments to research centers. Our customers use our work to make informed decisions and save time and resources.

Where is IDTechEx established?

IDTechEx was established in 1999, and is headquartered in Cambridge, UK. Since then, the company has significantly expanded and operates globally, having served customers in over 80 countries. Subsidiary companies are based in the USA, Germany and Japan.

Questions about purchasing a report

How do I pay?

In most locations reports can be purchased by credit card, or else by direct bank payment.

How and when do I receive access to IDTechEx reports?

When paying successfully by credit card, reports can be accessed immediately. For new customers, when paying by bank transfer, reports will usually be released when the payment is received. Report access will be notified by email.

How do I assign additional users to the report?

Users can be assigned in the report ordering process, or at a later time by email.

Can I speak to someone about purchasing a report?

Please email research@idtechex.com stating your location and we will quickly respond.

The transparent conductive film and glass markets will grow to $6.3 billion in 2024

보고서 통계

Pages	285
Tables	7
Figures	199
Companies	97
전망	2024

Customer Testimonial

"The resources provided by IDTechEx, such as their insightful reports and analysis, engaging webinars, and knowledgeable analysts, serve as valuable tools and information sources... Their expertise allows us to make data-driven, strategic decisions and ensures we remain aligned with the latest trends and opportunities in the market."

Global Head of Product Management and Marketing
Marquardt GmbH