Reversible Semimetal-Semiconductor Transition of Unconventional-Phase WS 2 Nanosheets.

Phase transition with band gap modulation of materials has gained intensive research attention due to its various applications, including memories, neuromorphic computing, and transistors. As a powerful strategy to tune the crystal phase of transition-metal dichalcogenides (TMDs), the phase transition of TMDs provides opportunities to prepare new phases of TMDs for exploring their phase-dependent property, function, and application. However, the previously reported phase transition of TMDs is mainly irreversible. Here, we report a reversible phase transition in the semimetallic 1T'-WS 2 driven by proton intercalation and deintercalation, resulting in a newly discovered semiconducting WS 2 with a novel unconventional phase, denoted as the 1T' d phase. Impressively, an on/off ratio of >10 6 has been achieved during the phase transition of WS 2 from the semimetallic 1T' phase to the semiconducting 1T' d phase. Our work not only provides a unique insight into the phase transition of TMDs via proton intercalation but also opens up possibilities to tune their physicochemical properties for various applications.