Amorphous semiconductors, which lack this order and have randomly distributed atoms, are more cost-effective, simple and uniformly manufactured, according to the team of researchers.
However the traditional amorphous hydrogenated silicon used in such applications “falls short in electrical properties, necessitating the exploration of new materials”, they wrote in a paper published as an accelerated preview in the peer-reviewed journal Nature on Wednesday.
The paper has undergone peer review but requires further proofing.
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However, challenges to developing suitable amorphous semiconductors have held back the development of new generation devices.
The development of “thin-film transistors”, the technology that led to liquid crystal screen displays, has been propelled forward by the creation of high-mobility amorphous n-type semiconductors, the team said.
N-type semiconductors have an excess of electrons and fewer “holes”, which are when electrons in an atom move from the valence shell – where they normally reside – into the conduction band, where they can easily escape from an atom, creating a vacancy.
P-type semiconductors, on the other hand, have an excess of holes due to introduced impurities – which modifies their electrical properties.
Developing p-type semiconductors for CMOS has proved to be a major challenge, as the compounds used can only perform optimally in crystalline forms, the researchers said.
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Crystalline forms have “low stability, complex synthesis processes, large-area non-uniformity, and a lack of industrial compatibility”, compared to amorphous forms, according to their paper.
Their proposed strategy “exhibits superiority over reported emerging amorphous p-type semiconductors, exhibiting outstanding electrical performance, cost-effectiveness, high-stability, scalability” and processing potential, their paper says.
“This study represents a crucial stride towards establishing commercially viable” amorphous p-type semiconductors in a “low-cost and industry-compatible manner”, the team wrote.