Home > Press > Global Market For Transparent Electronics To Be Worth $123 Billion In 2015
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Abstract:
According to a new technical market research report, TRANSPARENT ELECTRONICS: TECHNOLOGIES AND GLOBAL MARKETS (IFT065A) from BCC Research (www.bccresearch.com), the value of the global transparent electronics industry was nearly $76.4 billion in 2010, but is expected to increase to $123 billion in 2015, for a 5-year compound annual growth rate (CAGR) of 10%.
Global Market For Transparent Electronics To Be Worth $123 Billion In 2015
Wellesley, MA | Posted on October 21st, 2010The largest segment of the market, inorganic material, is projected to increase at a CAGR of 6.7% to nearly $103 billion in 2015, after being valued at $74.2 billion in 2010.
The other segment, organic material, is estimated at $2.1 billion in 2010, but is expected to increase at a CAGR of 56.9% to reach nearly $20.3 billion in 2015.
Most of the hype surrounding transparent electronics is fueled by the exotic usage scenarios that it will engender: The idea of having electronic circuitry that is invisible to the human eye has few parallels in its appeal. There is an overwhelming popular discourse that this technology is being developed from scratch, when the reality is more mundane and humbling. Transparent electronics has been with us for at least 50 years.
The core of transparent electronics, the transparent conductor, is neither a recent discovery nor is it unexplored vis-à-vis applications. Transparent conducting oxides (TCO), in general, and indium tin oxide (ITO), in particular, have a long history of usage in consumer electronics as well as optical devices. They have been used for low-profile applications such as cathode-ray tubes, electromagnetic shielding and other applications. The demand for these requirements was steady but limited and there were seemingly no supply-side constraints.
This report divides the materials used for constructing transparent electronics components into the following categories: Inorganic material - Indium tin oxide and other inorganic material; and Organic material - Conducting polymers and carbon nanotubes (CNTs).
While an in-depth comparison of the pros and cons of organic and inorganic material is presented in the body of the report, there are two broad advantages that organic materials bring to the table: Better flexibility and malleability, and cost-effectiveness in the long run due to substantial supply side stability.
Transparent electronics is not a uniform science. It is rather a collection of several usage patterns and innovations that have often developed independently of each other. The technology and the market are clearly evolving at large; even among themselves, there are different stages of evolution. Transparent electronics has evolved around a set of usage scenarios: Solar/photovoltaic (PV) cells, touch surfaces, mainstream displays, and unconventional substrates.
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Telephone: 866-285-7215
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