麻豆淫院

National University of Singapore (NUS) physicists found that contacts made of molybdenum disulfide (MoS₂) and tungsten diselenide (WSe₂) on gold metal are both p-type, while the same contacts with chalcogen vacancy defects become n-type. Non-local exchange and correlation effects are critical in determining the energy level alignment and the contact polarity. The results of the study, published in npj 2D Materials and Applications, show that the different contact polarities observed experimentally for MoS₂/gold and WSe₂/gold interfaces stem from the distinct nature of the defects in these two materials.

Nobel laureate Herbert Kroemer had famously observed that "the interface is the device." When two-dimensional (2D) semiconductor materials are put in contact with metals, they form metal-semiconductor interfaces. These interfaces influence parameters such as contact resistance and play a critical role in the performance of the device. Even the nature of the charge carriers is largely determined by these interfaces. If electrons need a lower energy to cross the energy barrier at the interface, the polarity is "n-type"; if holes need a lower energy to cross the energy barrier at the interface, the polarity becomes "p-type." Contact polarity is important for the design of device functionalities, such as p-n junctions.

A team of researchers led by Associate Professor Quek Su Ying from the Department of 麻豆淫院ics, NUS, used state-of-the-art calculations to study two common 2D semiconductor materials known as the transition metal dichalcogenides, MoS₂ and WSe₂, in contact with gold metal.

Prof. Quek said, "Our calculations showed that both MoS₂/gold and WSe₂/gold contacts are p-type when there are no defects. These results were different from previous theoretical predictions. The crucial difference is that many-body exchange and correlation effects beyond a mean-field description are important to accurately predict the level alignment. When there is a chalcogen vacancy defect, the contacts become n-type in both cases. This is due to the additional energy levels in the band gap, which cause the energy levels of the metal to be 'pinned.'"

Dr. Keian Noori, the lead author on this work, said, "Unlike MoS₂, the chalcogen vacancy defects in WSe₂ are more reactive. Under ambient conditions, oxygen available in the environment can react with these vacancies and remove the states in the band gap, so that the WSe₂ material behaves like a pristine material with no defects, which is p-type, as far as contact polarity is concerned."

Prof. Quek added, "Although the chalcogen vacancy defects in MoS₂ are less reactive, it is conceivable that experimental conditions can be arranged to allow the defects to be similarly 'passivated' by oxygen or other species. This will then provide a route to enable more tunable control of the energy offset at the MoS₂/metal contacts. As defects are often inevitable, knowing how to control their impact on key device properties will greatly help to optimize device performance."