Global Organic Field-effect Transistor (OFET) Market 2017-2021

  • ID: 4435081
  • Report
  • Region: Global
  • 64 pages
  • TechNavio
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FEATURED COMPANIES

  • Santa Barbara
  • University of California
  • MORE
About Organic Field-effect Transistor (OFET)

Field-effect transistors (FETs) are a class of transistors used for signal amplification. An FET consists of two electrodes, a source, and a drain, which are connected by a channel. An electric charge is passed between the two electrodes via the channel. The conductivity of the FET will depend on how wide the electrical diameter or gate is. A small variation in the current will create a high variation in the voltage, thereby changing the amplitude of the signal created by the device. An organic FET (OFET) includes a source, a drain, a layer of organic semiconductor, and gate electrodes. OFETs incorporate an organic semiconductor as a channel. An insulator layer, such as SiO2, is placed between the organic semiconductor and gate electrode. OFETs are extensively researched for their use in flexible displays as well as their applicability with other IC chipsets. Unlike silicon-based FETs, OFETs can be printed on plastic, flexible substrates at a lower temperature using solution-based techniques. This is an added advantage that enables the wider application of OFETs across a variety of flexible displays.

The analysts forecast the global organic field-effect transistor (OFET) market to grow at a CAGR of 7.37% during the period 2017-2021.

Covered in this report

The report covers the present scenario and the growth prospects of the global organic field-effect transistor (OFET) market for 2017-2021. To calculate the market size, the report considers the investments by independent labs and universities and grants from government bodies that aim at exploring and enhancing the applicability of the technology in the future.

The market is divided into the following segments based on geography:
  • Americas
  • APAC
  • EMEA
The report, Global Organic Field-effect Transistor (OFET) Market 2017-2021, has been prepared based on an in-depth market analysis with inputs from industry experts. The report covers the market landscape and its growth prospects over the coming years. The report also includes a discussion of the key vendors operating in this market.

Key vendors
  • University of California, Santa Barbara
  • Catalan Institute of Nanoscience and Nanotechnology
  • Graphenea and Chalmers University of Technology
  • National Institute of Material Sciences
Market drivers
  • Emergence of 4G standards
  • For a full, detailed list, view the full report
Market challenges
  • Availability of diverse inorganic low-cost alternative technologies
  • For a full, detailed list, view the full report
Market trends
  • Growing adoption of OLED displays in automotive applications
  • For a full, detailed list, view the full report
Key questions answered in this report
  • What will the market size be in 2021 and what will the growth rate be?
  • What are the key market trends?
  • What is driving this market?
  • What are the challenges to market growth?
  • Who are the key vendors in this market space?
You can request one free hour of the analyst’s time when you purchase this market report. Details are provided within the report.
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FEATURED COMPANIES

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  • University of California
  • MORE
PART 01: EXECUTIVE SUMMARY

PART 02: SCOPE OF THE REPORT

PART 03: RESEARCH METHODOLOGY

PART 04: INTRODUCTION
  • Market outline
PART 05: MARKET LANDSCAPE
  • Market overview
  • Market size and forecast
  • Five forces analysis
PART 06: MARKET SEGMENTATION BY APPLICATION
  • Global OFET market by application
  • Global OFET market by flexible OLED displays
  • Global OFET market by smart cards
  • Global OFET market by tags
PART 07: REGIONAL LANDSCAPE
  • Geographical segmentation
  • Regional comparison
  • APAC - Market size and forecast
  • Americas - Market size and forecast
  • EMEA - Market size and forecast
  • Key leading countries
  • Market opportunity
PART 08: DRIVERS AND CHALLENGES
  • Market drivers
  • Market challenges
PART 09: MARKET TRENDS
  • Growing adoption of OLED displays in automotive applications
  • Increasing demand for energy-efficient products
  • Growing number of card transactions
PART 10: DEVELOPMENT LANDSCAPE
  • Development scenario
PART 11: APPENDIX
  • List of abbreviations
List of Exhibits
Exhibit 01: Printing technologies
Exhibit 02: Global OFET market
Exhibit 03: Global OFET market 2016-2021 ($ mn)
Exhibit 04: Five forces analysis
Exhibit 05: Global OFET market by application 2016 (% revenue share)
Exhibit 06: Global OFET market by application 2016-2021 (% revenue share)
Exhibit 07: Global OFET market by flexible OLED displays 2016-2021 ($ mn)
Exhibit 08: Global OFET market by smart cards 2016-2021 ($ mn)
Exhibit 09: Global OFET market by tags 2016-2021 ($ mn)
Exhibit 10: Global - Market share 2016-2021 (%)
Exhibit 11: Regional comparison
Exhibit 12: APAC - Market size and forecast 2016-2021 ($ mn)
Exhibit 13: APAC - Year-over-year growth 2017-2021 (%)
Exhibit 14: Top 3 countries in APAC
Exhibit 15: Americas - Market size and forecast 2016-2021 ($ mn)
Exhibit 16: Americas - Year-over-year growth 2017-2021 (%)
Exhibit 17: Top 2 countries in Americas
Exhibit 18: EMEA - Market size and forecast 2016-2021 ($ mn)
Exhibit 19: EMEA - Year-over-year growth 2017-2021 (%)
Exhibit 20: Top 3 countries in EMEA
Exhibit 21: Key leading countries
Exhibit 22: Global OFET market: Key developments
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FEATURED COMPANIES

  • Santa Barbara
  • University of California
  • MORE
New Report Released: - Global Organic Field-effect Transistor (OFET) Market 2017-2021

The author of the report recognizes the following companies as the key players in the global organic field-effect transistor (OFET) market: University of California, Santa Barbara, Catalan Institute of Nanoscience and Nanotechnology, Graphenea and Chalmers University of Technology, and National Institute of Material Sciences

Commenting on the report, an analyst from the research team said: “The latest trend gaining momentum in the market is Growing adoption of OLED displays in automotive applications. Car OEMs are exploring the use of OLED displays in infotainment systems. Some vendors have introduced infotainment projects. However, the commercial availability of such displays is very low at present. The application of passive matrix OLED (PMOLED) displays for display gauges and meters would be a better substitute for analog meters and gauges. OLED displays consume less energy and provide wider viewing angles, which make them ideal for automotive applications.”

According to the report, one of the major drivers for this market is Emergence of 4G standards. LTE allows consumers to enjoy faster data speeds. It can deliver more data at a relatively high speed and provides a better experience compared with 3G. According to the Global Mobile Suppliers Association (GSA), 4G LTE is the fastest developing mobile system technology ever. In 2015, about 285 operators in 93 countries invested in LTE and 119 commercial LTE networks in 53 countries worldwide. To retain customers that are already using 2G or 3G services, cellular operators are upgrading their wireless networks to LTE.

Further, the report states that one of the major factors hindering the growth of this market is Availability of diverse inorganic low-cost alternative technologies. Several technologies, including TFT-LCD, LCD with LED backlight, plasma, and LED displays, are available at a lower cost compared with OLED. Vendors are manufacturing displays with these technologies on a large scale. In addition, these displays are less expensive and help in keeping the cost of end products low. OLED and flexible OLED displays could increase the cost of electronic devices in the near future. The oversupply in the LCD display market has enabled end-users to procure display panels at a low cost. This has made it possible for small and medium enterprises to provide end products at low average selling prices (ASPs).

The study was conducted using an objective combination of primary and secondary information including inputs from key participants in the industry. The report contains a comprehensive market and vendor landscape in addition to a SWOT analysis of the key vendors.
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  • University of California
  • Santa Barbara
  • Catalan Institute of Nanoscience and Nanotechnology
  • Graphenea and Chalmers University of Technology
  • National Institute of Material Sciences
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