Effects of electron charge density and particle size of alkali metal titanate nanotube-supported Pt photocatalysts on production of H sub(2) from neat alcohol

Pt nanoparticles (PtNPs) in the range of 1.0-3.0 nm were deposited on alkali titanate nanotubes (MTNTs = M sub(2-x)H sub(x)Ti sub(3)O sub(7), M = Li super(+), Na super(+), K super(+) and Cs super(+)) by wet impregnation. While most of the physical properties of Pt/MTNTs remained almost constant, the...

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Bibliographic Details
Published in:Physical chemistry chemical physics : PCCP 2014-10, Vol.16 (43), p.23743-23753
Main Authors: Lin, Chiu-Hsun, Chao, Jiunn-Hsing, Tsai, Wei-Je, He, Meng-Jou, Chiang, Ting-Ju
Format: Article
Language:English
Subjects:
Cations
Charge density
Particle size
Photocatalysis
Platinum
Titanates
Valence
X-ray photoelectron spectroscopy
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Summary:Pt nanoparticles (PtNPs) in the range of 1.0-3.0 nm were deposited on alkali titanate nanotubes (MTNTs = M sub(2-x)H sub(x)Ti sub(3)O sub(7), M = Li super(+), Na super(+), K super(+) and Cs super(+)) by wet impregnation. While most of the physical properties of Pt/MTNTs remained almost constant, the oxidation state and size of PtNPs varied systematically with the size of the cations of MTNTs. XPS indicated that the binding energy of Pt in Pt/MTNTs was reduced to a lower value than that of Pt super(0), yielding a Pt super( delta -) oxidation state. Diffuse-reflectance infrared Fourier transform spectroscopy coupling with CO adsorption studies confirmed the formation of the Pt super( delta -) state in Pt/MTNTs. Thus, electrons were transferred from MTNTs to PtNPs establishing an electric double layer at the interface between PtNP and MTNT supports, and the degree of electron transfer increased with the size of the cations in MTNTs. HRTEM revealed that the mean sizes of PtNPs followed the order, Pt/LiTNTs < Pt/NaTNTs < Pt/KTNTs < Pt/CsTNTs. TPR showed that the reducibility of PtO sub(x)/MTNTs determined the order of PtNPs size. In the photocatalytic production of H sub(2) (2H super(+) + 2e super(-) arrow right H sub(2)), since H sub(2) is produced at the interfacial Pt sites, the electron charge density and the particle size of PtNPs are the two competing factors in producing H sub(2). Photoluminescence studies revealed that the initial increase in electron density on PtNPs reduced the recombination of h super(+)-e super(-) pairs and increased H sub(2) yields, but a further increase in charge density enhanced the recombination of h super(+)-e super(-) pairs and lowered the H sub(2) yield. PtNPs in Pt/KTNTs had a moderate charge density and a moderate particle size, and so, produced a maximum amount of H sub(2) among Pt/MTNTs.
ISSN:1463-9076
1463-9084
DOI:10.1039/c4cp03503h