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The Graphene Box Conductive Films, the most recent series of graphene conductive films, are designed specifically to address a broad range of market applications, including EMI shielding, flexible touch screens, rollable OLEDs, and less costly and contaminating alternatives to the previous ITO OLEDs.
Graphene is regarded as an electrically transparent conductive electrode due to its great optical transmittance. Graphene films are less expensive than conventional electrodes constructed of ITO or FTO and also possess greater mechanical strength, flexibility, and chemical stability.
The Global Graphene Conductive Film market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
The graphene conductive sheet was recently introduced by XMKN. Having a high degree of transparency, the transparent conductive film is conductive. ITO (tin-doped indium oxide), etc., is a popularly used transparent conductive film on the market.
Flexible technology for the future market is needed for the production of this sort of film, along with pricey vacuum coating equipment. For such films, there is a severe lack of development space. A new class of transparent, flexible conductive film materials, graphene has just been introduced.
As a raw material, graphite oxide has been successfully used by XMKN to create a process for producing transparent conductive film made of graphene.
This technology’s creation of transparent graphene has a straightforward manufacturing process, is inexpensive, and has a wide range of potential uses, including touch screens for mobile phones, LED displays, and thin-film solar cells.
This method creates graphene films that are 10–20 nm thick, have a visual light transmittance of more than 85%, and have an electrical conductivity of 455 S/cm.
Using this process, a smooth, continuous graphene layer can be created; This method can create graphene films across enormous areas.
This technique is low-cost and easy to use. Due to its unique structure, superior electrical, mechanical, and thermal conductivities, large specific surface area, superior barrier properties, and other unique characteristics, graphene material excels in many areas where conventional materials fail, including many.
