Lu Wenbo, Li Zongbao, Feng Mingjie, Zheng Lirong, Liu Shunchang, Yan Bin, Hu Jin-Song, Xue Ding-Jiang
Beijing National Laboratory for Molecular Sciences (BNLMS), CAS Key Laboratory of Molecular Nanostructure and Nanotechnology, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, China.
University of Chinese Academy of Sciences,Beijing 100049,China.
J Am Chem Soc. 2024 Mar 6;146(9):6345-6351. doi: 10.1021/jacs.4c00219. Epub 2024 Feb 20.
Selenium (Se) discovered in 1817 belongs to the family of chalcogens. Surprisingly, despite the long history of over two centuries and the chemical simplicity of Se, the structure of amorphous Se (a-Se) remains controversial to date regarding the dominance of chains versus rings. Here, we find that vapor-deposited a-Se is composed of disordered rings rather than chains in melt-quenched a-Se. We further reveal that the main origin of this controversy is the facile transition of rings to chains arising from the inherent instability of rings. This transition can be inadvertently triggered by certain characterization techniques themselves containing above-bandgap illumination (above 2.1 eV) or heating (above 50 °C). We finally build a roadmap for obtaining accurate Raman spectra by using above-bandgap excitation lasers with low photon flux (below 10 phs m s) and below-bandgap excitation lasers measured at low temperatures (below -40 °C) to minimize the photoexcitation- and heat-induced ring-to-chain transitions.
1817年发现的硒(Se)属于硫族元素。令人惊讶的是,尽管有两个多世纪的悠久历史且硒的化学性质简单,但非晶态硒(a-Se)的结构在链与环何者占主导方面至今仍存在争议。在这里,我们发现气相沉积的a-Se由无序的环组成,而非熔融淬火a-Se中的链。我们进一步揭示,这一争议的主要根源是环由于其固有的不稳定性而容易转变为链。这种转变可能会被某些本身包含带隙以上光照(高于2.1 eV)或加热(高于50°C)的表征技术无意中触发。我们最终制定了一个路线图,通过使用低光子通量(低于10 phs m s)的带隙以上激发激光和在低温(低于-40°C)下测量的带隙以下激发激光来获得准确的拉曼光谱,以尽量减少光激发和热诱导的环到链的转变。
