Defect configurations in Ge–S chalcogenide glasses studied by Raman scattering and positron annihilation technique

“…The analysis of the WF centers with respect to the nuclear positions allows gaining insight into the chemical bonding involved in systems such as water [50][51][52], amorphous silicon [53], and oxides [54]. This analysis has been extended to germanium selenides g-Ge 2 Se 3 , g-GeSe 2 , g-GeSe 3 , g-GeSe 4 , and g-GeSe 9 where a complex mixture of ionocovalent and purely covalent bonds was found [20,26].…”

“…In some cases, these structures largely differ (in terms of quantity of defects) from those obtained by the common melt-quenching (MQ) technique used for the preparation of bulk glasses. It appears that g-GeS x (with x = 2, 4, 6) films, obtained by pulsed laser deposition from the pristine bulk glasses (obtained by MQ), show a significant content of defects and "wrong bonds" [7][8][9]. In this case, the departure from perfect chemical order is due to the fact that as-deposited g-GeS x films are far away from the equilibrium state [7].…”

Surface of glassyGeS2: A model based on a first-principles approach

“…The analysis of the WF centers with respect to the nuclear positions allows gaining insight into the chemical bonding involved in systems such as water [50][51][52], amorphous silicon [53], and oxides [54]. This analysis has been extended to germanium selenides g-Ge 2 Se 3 , g-GeSe 2 , g-GeSe 3 , g-GeSe 4 , and g-GeSe 9 where a complex mixture of ionocovalent and purely covalent bonds was found [20,26].…”

“…In some cases, these structures largely differ (in terms of quantity of defects) from those obtained by the common melt-quenching (MQ) technique used for the preparation of bulk glasses. It appears that g-GeS x (with x = 2, 4, 6) films, obtained by pulsed laser deposition from the pristine bulk glasses (obtained by MQ), show a significant content of defects and "wrong bonds" [7][8][9]. In this case, the departure from perfect chemical order is due to the fact that as-deposited g-GeS x films are far away from the equilibrium state [7].…”

Surface of glassyGeS2: A model based on a first-principles approach

“…Due to the significant properties such as non-toxicity, good thermal and chemical stabilities and the large optical transmission range extending in the mid-infrared, Ge-S glasses have been widely studied for many years for the potential applications in optics, optoelectronics and electrochemistry [1][2][3][4][5][6]. Great efforts were paid to the structural properties of Ge-S bulk glasses by various techniques such as Raman scattering spectra [1,3,7], neutron diffraction [2,8], EXAFS [9] and positron annihilation technique [4].…”

Structure and optical properties of amorphous GeSx films prepared by PLD

“…In some cases, these structures largely differ (in terms of quantity of defects) from those obtained by common melt-quenching methods used for the preparation of bulk glasses. It appears that glassy GeS x (with x = 2, 4, 6) films, obtained by pulsed laser deposition from the pristine bulk glasses, show a significant content of defects and "wrong bonds" (such as homopolar bonds) [42][43][44]. In this case, the departure from perfect chemical order is due to the fact that as-deposited g-GeS x films are far away from the equilibrium state [42][43][44].…”

“…It appears that glassy GeS x (with x = 2, 4, 6) films, obtained by pulsed laser deposition from the pristine bulk glasses, show a significant content of defects and "wrong bonds" (such as homopolar bonds) [42][43][44]. In this case, the departure from perfect chemical order is due to the fact that as-deposited g-GeS x films are far away from the equilibrium state [42][43][44]. For the case of glassy GeS 2 (g-GeS 2 , g stands hereafter for glass) the perfect chemical order corresponds to the absence of any undercoordinated or overcoordinated Ge atoms or S atoms ( = 4 and = 2 for Ge and S, respectively) [45].…”

Molecular Modeling of Glassy Surfaces