Photocatalysis using a Wide Range of the Visible Light Spectrum: Hydrogen Evolution from Doped AgGaS<sub>2</sub>

Yamato, Kohei; Iwase, Akihide; Kudo, Akihiko

doi:10.1002/cssc.201500540

Cited by 18 publications

(5 citation statements)

References 26 publications

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“…With a decrease of the In/(In + Ga) ratio in AIGS nanoparticles from 1.0 to 0.20, their E g values increased linearly from 2.07 to 2.54 eV. This trend agrees with theoretical expectation. − It was reported on the basis of the density functional theory that the conduction band minimum of an AgIn (1‑ y ) Ga y S 2 semiconductor was shifted to a higher level (a more negative potential) with an increase in the ratio of Ga to In, accompanied by an increase in E g , because the orbitals of Ga 4s4p and In 5s5p mainly made the conduction band minimum, in which the Ga orbitals formed higher levels than those of the In orbitals, and because the valence band was composed of S 3p and Ag 4d. AIGS@GaS x nanoparticles exhibited a similar linear relation between the E g and the In content in cores.…”

Section: Resultssupporting

confidence: 87%

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga³⁺ Doping

Kameyama

Kishi

Miyamae

et al. 2018

ACS Appl. Mater. Interfaces

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The nonstoichiometry of I−III−VI semiconductor nanoparticles, especially the ratio of group I to group III elements, has been utilized to control their physicochemical properties. We report the solution-phase synthesis of nonstoichiometric Ag−In−S and Ag−In−Ga−S nanoparticles and results of the investigation of their photoluminescence (PL) properties in relation to their chemical compositions. While stoichiometric AgInS 2 nanoparticles simply exhibited only a broad PL band originating from defect sites in the particles, a narrow band edge PL peak newly appeared with a decrease in the Ag fraction in the nonstoichiometric Ag−In−S nanoparticles. The relative PL intensity of this band edge emission with respect to the defect-site emission was optimal at a Ag/(Ag + In) value of ca. 0.4. The peak wavelength of the band edge emission was tunable from 610 to 500 nm by increased doping with Ga 3+ into Ag−In−S nanoparticles due to an increase of the energy gap. Furthermore, surface coating of Ga 3+ -doped Ag−In−S nanoparticles, that is, Ag−In−Ga−S nanoparticles, with a GaS x shell drastically and selectively suppressed the broad defect-site PL peak and, at the same time, led to an increase in the PL quantum yield (QY) of the band edge emission peak. The optimal PL QY was 28% for Ag−In−Ga−S@GaS x core−shell particles, with green band-edge emission at 530 nm and a full width at half-maximum of 181 meV (41 nm). The observed wavelength tunability of the band-edge PL peak will facilitate possible use of these toxic-element-free I−III−VI-based nanoparticles in a wide area of applications.

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Section: Resultssupporting

confidence: 87%

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga³⁺ Doping

Kameyama

Kishi

Miyamae

et al. 2018

ACS Appl. Mater. Interfaces

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“…With theoretical calculations based on density functional theory for AgInSe 2 and AgGaSe 2 , it was reported that the valence bands of both semiconductors were composed of Se 4p and Ag 4d, while the conduction band minimums of AgInSe 2 and AgGaSe 2 were composed of hybrid orbitals of Se 4s4p with In 5s and with Ga 4s, respectively. Considering that the Ga orbitals formed higher levels than those of the In orbitals, , it is reasonably expected that the CBM of an Ag x In y Ga (1‑ y ) Se 2 semiconductor is shifted to a higher level with an increase in the Ga fraction, that is, with a decrease in the y value, while the VBM is not significantly influenced by the y value. Thus, we conclude that the electronic energy structure and the optical property of AIGSe QDs can be controlled by varying their In/Ga ratio, even without changing the particle size.…”

Section: Results and Discussionmentioning

confidence: 99%

Tailored Photoluminescence Properties of Ag(In,Ga)Se₂ Quantum Dots for Near-Infrared In Vivo Imaging

Kameyama

Yamauchi

Yamamoto

et al. 2020

ACS Appl. Nano Mater.

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Multinary semiconductor quantum dots (QDs) that have less toxicity and show near-infrared light responsivity have attracted much attention for in vivo bioimaging. In this study, we controlled the optical properties of Ag–In–Se QDs by modulating the nonstoichiometry and the degree of Ga3+ doping. Precise tuning of the Ag/In ratio of Ag–In–Se QDs enabled a sharp band-edge emission to emerge without broad defect-site emission. Ga3+ doping into Ag–In–Se (AIGSe) QDs enlarged their energy gap, resulting in a blue shift of the band-edge PL peak from from 890 to 630 nm. The band-edge PL intensity was remarkably enlarged by surface coating with a thin GaS x shell followed by treatment with trioctylphosphine, the highest PL yield being 38% for the PL peak at 800 nm. Thus-obtained QDs were successfully used as near-IR PL probes for three-dimensional in vivo bioimaging in which the wavelengths of excitation and detection lights could be selected in the first biological window, and then the signals were clearly detected from AIGSe@GaS x core–shell QDs injected into biological tissues by ca. 5 mm in depth.

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“…33,34 Because the TTB structure of these catalysts still remains after the substitution, the valence band levels of these catalysts should be similar. 35 The alkali and alkaline-earth metals were found to affect the conduction band levels in NaTaO 3 ; thus, a larger band gap means a larger conduction band level, which directly dictates the water splitting and CO 2 conversion ability of a material.…”

Section: Resultsmentioning

confidence: 99%

“…The enlarged band gap is due to the substitution of K + and Sr 2+ for Na + . Large band gaps in tantalates have been reported to be beneficial for photocatalytic water splitting and CO 2 conversion by H 2 . , Because the TTB structure of these catalysts still remains after the substitution, the valence band levels of these catalysts should be similar . The alkali and alkaline-earth metals were found to affect the conduction band levels in NaTaO 3 ; thus, a larger band gap means a larger conduction band level, which directly dictates the water splitting and CO 2 conversion ability of a material.…”

Section: Resultsmentioning

confidence: 99%

Sodium Cation Substitution in Sr₂KTa₅O₁₅ toward Enhancement of Photocatalytic Conversion of CO₂ Using H₂O as an Electron Donor

et al. 2017

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The K and Sr cations (K + and Sr 2+ ) in a Sr 2 KTa 5 O 15 photocatalyst were found to be easily substituted by Na cations (Na + ) to form Sr x K y Na z Ta 5 O 15 by a facile one-pot flux method using a mixture of potassium chloride (KCl) and sodium chloride (NaCl). Sr x K y Na z Ta 5 O 15 fabricated using a mixture of KCl and NaCl with a Ag cocatalyst showed enhanced photocatalytic activity without apparent change in selectivity toward CO for the photocatalytic conversion of CO 2 using H 2 O. The present study demonstrates that the flux treatment significantly affected the phase, morphology, band gap, and surface Sr composition of the catalyst owing to the substitution of K + and Sr 2+ for Na + . The stability and durability of the catalyst were also enhanced as compared to those of the photocatalyst fabricated using only KCl flux due to more stable Ag on the surface of Sr x K y Na z Ta 5 O 15 .

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Photocatalysis using a Wide Range of the Visible Light Spectrum: Hydrogen Evolution from Doped AgGaS₂

Cited by 18 publications

References 26 publications

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga³⁺ Doping

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga³⁺ Doping

Tailored Photoluminescence Properties of Ag(In,Ga)Se₂ Quantum Dots for Near-Infrared In Vivo Imaging

Sodium Cation Substitution in Sr₂KTa₅O₁₅ toward Enhancement of Photocatalytic Conversion of CO₂ Using H₂O as an Electron Donor

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Photocatalysis using a Wide Range of the Visible Light Spectrum: Hydrogen Evolution from Doped AgGaS2

Cited by 18 publications

References 26 publications

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga3+ Doping

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga3+ Doping

Tailored Photoluminescence Properties of Ag(In,Ga)Se2 Quantum Dots for Near-Infrared In Vivo Imaging

Sodium Cation Substitution in Sr2KTa5O15 toward Enhancement of Photocatalytic Conversion of CO2 Using H2O as an Electron Donor

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Photocatalysis using a Wide Range of the Visible Light Spectrum: Hydrogen Evolution from Doped AgGaS₂

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga³⁺ Doping

Wavelength-Tunable Band-Edge Photoluminescence of Nonstoichiometric Ag–In–S Nanoparticles via Ga³⁺ Doping

Tailored Photoluminescence Properties of Ag(In,Ga)Se₂ Quantum Dots for Near-Infrared In Vivo Imaging

Sodium Cation Substitution in Sr₂KTa₅O₁₅ toward Enhancement of Photocatalytic Conversion of CO₂ Using H₂O as an Electron Donor