在本論文中,我們在超高真空的環境下,透過固態電化學的方式產生硫分子(S2)氣體,使其吸附於金(100)表面上,並利用X光光電子能譜術、低能量電子繞射、掃描穿隧顯微鏡來研究硫在金(100)上隨溫度的結構變化。當硫在室溫下的覆蓋率達到飽和時,由低能量電子繞射觀察到c(4x2)的重構,同時由X光光電子能譜術量測到三種不同硫的電子態。經過加熱至不同溫度後,除了電子態的變化外,隨著覆蓋率的降低,也依序觀察到c(4x4)與(6x6)的共存態、(6x6)、c(2x2)與(2x2)共存態、(2x2)等重構,直到加熱至550℃時可觀察到乾淨金(100)表面(5x20)之重構,顯示硫已從表面完全脫附(desorption)。硫在不同溫度下的重構,也經由掃描穿隧顯微鏡得到其原子排列情形,而S 2p和Au 4f電子能譜也被量測及分析。根據這些結果,我們提出了各個重構可能的原子模型。 The temperature-dependent adsorption of S on a clean Au(100)- (5x20) surface has been studied with X-ray photoelectron spectroscopy (XPS), low energy electron diffraction (LEED), and scanning tunneling microscopy (STM), using a beam of S2 molecules generated by electrochemical decomposition of Ag2S. For the S adsorption at room temperature, a c(4x2) surface reconstruction is observed with LEED for saturation coverage, and the XPS study of S 2p from the S adlayer reveals the presence of three components. As the S coverage decreases during annealing, the surface undergoes a series of transformations, in the order of the coexistence of c(4x4) and (6x6), (6x6), coexistence of c(2x2) and (2x2) ,(2x2) the S adlayer desorbs completely at 550℃. Each reconstruction structure was investigated with STM, and the corresponding photoemission spectra of the S and Au core levels were measured and analyzed. Combining these results, the atomic models for the varied reconstructions were proposed.