SnS2-In2S3 p-n heterostructures with enhanced Cr6+ reduction under visible-light irradiation

“…In S3, the Sn 3d core-level spectra with angular momentum quantum number ( l = 2) undergo spin–orbit ( j–j ) splitting into doublets at binding energies (B.E.) of 495.3 eV (3d 3/2 ) and 486.9 eV (3d 5/2 ) with a peak area ratio of 3:2. , These doublets with a spin–orbit splitting energy of 8.5 eV correspond to the Sn 4+ state (Figure a). These doublets experience a slight downward shift in their B.E.…”

“…Once the carriers are populated over the nanosheet, the built-in electric field at the p–n junction readily drives the electrons and holes away from each other, thereby preventing their recombination . The interfacial carrier separation is better in S10 than in S3 due to a higher built-in potential ( V bi ) in the former. − Once separated, the photogenerated electrons are readily trapped in the V S sites. From the trapped sites, the electrons are transferred to the adsorbed O 2 molecule and generate O 2 · – radicals.…”

Self-Assembled p–n Homojunction in SnS₂ Nanosheets for Enhanced Visible Light-Driven Photocatalysis

“…In S3, the Sn 3d core-level spectra with angular momentum quantum number ( l = 2) undergo spin–orbit ( j–j ) splitting into doublets at binding energies (B.E.) of 495.3 eV (3d 3/2 ) and 486.9 eV (3d 5/2 ) with a peak area ratio of 3:2. , These doublets with a spin–orbit splitting energy of 8.5 eV correspond to the Sn 4+ state (Figure a). These doublets experience a slight downward shift in their B.E.…”

“…Once the carriers are populated over the nanosheet, the built-in electric field at the p–n junction readily drives the electrons and holes away from each other, thereby preventing their recombination . The interfacial carrier separation is better in S10 than in S3 due to a higher built-in potential ( V bi ) in the former. − Once separated, the photogenerated electrons are readily trapped in the V S sites. From the trapped sites, the electrons are transferred to the adsorbed O 2 molecule and generate O 2 · – radicals.…”

Self-Assembled p–n Homojunction in SnS₂ Nanosheets for Enhanced Visible Light-Driven Photocatalysis

“…Photovoltaic power generation is the main form of using solar energy. Photogenerated carriers are produced inside photovoltaic materials upon light irradiation on their surface, which endows the photovoltaic materials with important potential applications in the fields of solar cells, photodetection, photocatalysis, and so on. − Traditional photovoltaic devices are usually obtained through the construction of a p–n junction, and a built-in electric field ( E b ) is formed at the junction. − The photogenerated electrons and holes are separated and form a photocurrent in those devices. However, the preparation of solar cells based on p–n junctions is complicated.…”

Photovoltaic Effect Induced by Self-Polarization in BiFeO₃ Films

“…[ 5–7 ] Photocatalytic Cr 6+ reduction has emerged as an attractive direction due to its potential to be environmental friendly, cheap, and sustainable. [ 1,8 ] Various photocatalysts have been reported for Cr 6+ reduction, including phlo‐@POF, [ 9 ] Cu 2 O/TiO 2 , [ 10 ] Zn(Ce, Mn)‐MOFs, [ 11 ] ZnWO 4 , [ 5 ] SnS 2 –In 2 S 3 , [ 12 ] and Gd(OH) 3 . [ 6 ] However, many of the reported materials show limited photocatalytic efficiency due to their wide bandgaps limiting their light absorption ability and/or inefficient redox ability due to fast recombination of photogenerated electron–hole pairs.…”

Bi₂S₃–In₂S₃ Heterostructures for Efficient Photoreduction of Highly Toxic Cr⁶⁺ Enabled by Facet‐Coupling and Z‐Scheme Structure