Abstract
AbstractLithography is one of the most widely used methods for cutting‐edge research and industrial applications, mainly owing to its ability to draw patterns in the micro and even nanoscale. However, the fabrication of semiconductor micro/nanostructures via conventional electron or optical lithography technologies often requires a time‐consuming multistep process and the use of expensive facilities. Herein, a low‐cost, high‐resolution, facile, and versatile direct patterning method based on metal–organic molecular precursors is reported. The ink‐based metal–organic precursors are found to operate as negative resists, with the material exposed by different methods (electron‐beam/laser/heat/ultraviolet (UV)) to render them insoluble in the development process. This technical process can deliver metal chalcogenide semiconductors with arbitrary 2D/3D patterns with sub‐50 nm resolution. Electron beam lithography, two‐photon absorption lithography, thermal scanning probe lithography, and UV photolithography are demonstrated for the direct patterning process. Different metal chalcogenide semiconductor nanodevices, such as photoconductive selenium‐doped Sb2S3 nanoribbons, p‐type PbS single‐nanowire field‐effect transistors, and p‐n junction CdS/Cu2S nanowire solar cells, are fabricated by this method. This direct patterning technique is a versatile and simple micro/nanolithography technology with considerable potential for “lab‐on‐a‐chip” preparation of semiconductor devices.
Highlights
The fabrication of microscale and nanoscale structures is vital multiple processing steps
Direct patterning of metal chalcogenide nanostructures via various conventional/unconventional lithography technologies (EBL/two-photon absorption lithography (TPAL)/thermal scanning probe lithography (TSPL)/UV light lithography (UVL)) based on metal–organic precursor solutions has been realized for the first time
Such direct patterning process could apply to a wide range of metal chalcogenide systems
Summary
The fabrication of microscale and nanoscale structures is vital multiple processing steps. Due to charge back scattering and the proximity effect, radiation resists always serve as the primary resolution limitation factor of electron beam lithography (EBL).[3,4]. For many applications, for example, microfluidics, display units, Ideally, one would prefer a resistless direct patterning method small electronics systems, and optoelectronic devices. Among that overcomes the disadvantages of conventional lithography the existing nanopatterning methods, electron beam and optical process. Direct patterning is an efficient method that directly lithography have the advantages of high degree of automation, transfers target materials to the substrates.[5,6,7,8] This method is precisely controlled operation, and nanometer-sized resolu- featured as patterning methodology-based electron beam/UV-.
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