Transparent conductors are one of the key elements of today’s electronic and optoelectronic devices such as displays, light emitting diodes, photovoltaic cells, smart phones, etc. Most of the current technology is based on the use of the semiconductor Indium Tin Oxide (ITO) as a transparent conducting material. However, even though ITO presents several exceptional properties, such as a large transmission and low resistance, it still lacks mechanical flexibility, needs to be processed under high temperatures and is expensive to produce.
An intensive effort has been devoted to the search of alternative TC materials that could definitively replace ITO, especially in the search for device flexibility. While the scientific community has investigated materials such as Al-doped ZnO (AZO), carbon nanotubes, metal nanowires, ultrathin metals, conducting polymers and most recently graphene, none of these have been able to present optimal properties that would make them the candidate to replace ITO.
Today ultrathin metal films (UTMFs) have been shown to present very low resistance although their transmission is also low unless antireflection (AR) undercoat and overcoat layers are added to the structure. ICFO researchers Rinu Abraham Maniyara, Vahagn K. Mkhitaryan, Tong Lai Chen, and Dhriti Sundar Ghosh, led by ICREA Prof at ICFO Valerio Pruneri, have developed a room temperature processed multilayer transparent conductor optimizing the antireflection properties to obtain high optical transmissions and low losses, with large mechanical flexibility properties. They have published their results in a recent paper published in Nature Communications.
In their study, ICFO researchers applied an Al doped ZnO overcoat and a TiO2 undercoat layer with precise thicknesses to a highly conductive Ag ultrathin film. By using destructive interference, the researchers showed that the proposed multilayer structure could lead to an optical loss of approximately 1.6% and an optical transmission greater than 98% in the visible. This result represents a record fourfold improvement in figure of merit over ITO and also presents superior mechanical flexibility in comparison to this material.
The results of this study show the potential that this multilayer structure could have in future technologies that aim at more efficient and flexible electronic and optoelectronic devices.
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