Simultaneous Optimization of Colloidal Stability and Interfacial Charge Transfer Efficiency in Photocatalytic Pt/CdS Nanocrystals.

Colloidal stability and efficient interfacial charge transfer in semiconductor nanocrystals are of great importance for photocatalytic applications in aqueous solution since they provide long-term functionality and high photocatalytic activity, respectively. However, colloidal stability and interfacial charge transfer efficiency are difficult to optimize simultaneously since the ligand layer often acts as both a shell stabilizing the nanocrystals in colloidal suspension and a barrier reducing the efficiency of interfacial charge transfer. Here, we show that, for cysteine-coated, Pt-decorated CdS nanocrystals and Na2SO3 as hole scavenger, triethanolamine (TEOA) replaces the original cysteine ligands in situ and prolongs the highly efficient and steady H2 evolution period by more than a factor of 10. It is shown that Na2SO3 is consumed during H2 generation while TEOA makes no significant contribution to the H2 generation. An apparent quantum yield of 31.5%, a turnover frequency of 0.11 H2/Pt/s, and an interfacial charge transfer rate faster than 0.3 ps were achieved in the TEOA stabilized system. The short length, branched structure and weak binding of TEOA to CdS as well as sufficient free TEOA in the solution are the keys to enhancing colloidal stability and maintaining efficient interfacial charge transfer at the same time. Additionally, TEOA is commercially available and cheap, and we anticipate that this approach can be widely applied in many photocatalytic applications involving colloidal nanocrystals.

[1]  P. Jain,et al.  The Ligand Shell as an Energy Barrier in Surface Reactions on Transition Metal Nanoparticles. , 2016, Journal of the American Chemical Society.

[2]  Z. Hens,et al.  Colloidal metal oxide nanocrystal catalysis by sustained chemically driven ligand displacement. , 2016, Nature materials.

[3]  Francesco Scotognella,et al.  Optimal metal domain size for photocatalysis with hybrid semiconductor-metal nanorods , 2016, Nature Communications.

[4]  T. J. Whittles,et al.  Colloidal dual-band gap cell for photocatalytic hydrogen generation. , 2015, Nanoscale.

[5]  Eun Seon Cho,et al.  Engineering Synergy: Energy and Mass Transport in Hybrid Nanomaterials , 2015, Advanced materials.

[6]  Katherine L. Orchard,et al.  Ligand removal from CdS quantum dots for enhanced photocatalytic H2 generation in pH neutral water , 2016 .

[7]  C. Chen,et al.  Efficient removal of organic ligands from supported nanocrystals by fast thermal annealing enables catalytic studies on well-defined active phases. , 2015, Journal of the American Chemical Society.

[8]  J. Hutchison,et al.  Removal of thiol ligands from surface-confined nanoparticles without particle growth or desorption. , 2015, ACS nano.

[9]  Tianquan Lian,et al.  Ultrafast exciton dynamics and light-driven H2 evolution in colloidal semiconductor nanorods and Pt-tipped nanorods. , 2015, Accounts of chemical research.

[10]  H. Mattoussi,et al.  UV and sunlight driven photoligation of quantum dots: understanding the photochemical transformation of the ligands. , 2015, Journal of the American Chemical Society.

[11]  David Volbers,et al.  Redox shuttle mechanism enhances photocatalytic H2 generation on Ni-decorated CdS nanorods. , 2014, Nature materials.

[12]  E. Palomares,et al.  Efficient and limiting reactions in aqueous light-induced hydrogen evolution systems using molecular catalysts and quantum dots. , 2014, Journal of the American Chemical Society.

[13]  Tianquan Lian,et al.  Hole removal rate limits photodriven H2 generation efficiency in CdS-Pt and CdSe/CdS-Pt semiconductor nanorod-metal tip heterostructures. , 2014, Journal of the American Chemical Society.

[14]  Prashant V. Kamat,et al.  Recent advances in quantum dot surface chemistry. , 2014, ACS applied materials & interfaces.

[15]  A. Das,et al.  Photogeneration of hydrogen from water using CdSe nanocrystals demonstrating the importance of surface exchange , 2013, Proceedings of the National Academy of Sciences.

[16]  Frank E. Osterloh,et al.  Quantum confinement controls photocatalysis: a free energy analysis for photocatalytic proton reduction at CdSe nanocrystals. , 2013, ACS nano.

[17]  Patrick L. Holland,et al.  Robust Photogeneration of H2 in Water Using Semiconductor Nanocrystals and a Nickel Catalyst , 2012, Science.

[18]  Yuexiang Li,et al.  Photocatalytic hydrogen generation in the presence of ethanolamines over Pt/ZnIn2S4 under visible light irradiation , 2012 .

[19]  Stefan Fischbach,et al.  Hole scavenger redox potentials determine quantum efficiency and stability of Pt-decorated CdS nanorods for photocatalytic hydrogen generation , 2012 .

[20]  Stefan Fischbach,et al.  Delayed photoelectron transfer in Pt-decorated CdS nanorods under hydrogen generation conditions. , 2012, Small.

[21]  P. Reiss,et al.  Aqueous phase transfer of InP/ZnS nanocrystals conserving fluorescence and high colloidal stability. , 2011, ACS nano.

[22]  Andrey L. Rogach,et al.  Colloidal CdS nanorods decorated with subnanometer sized Pt clusters for photocatalytic hydrogen generation , 2010 .

[23]  E. Boldyreva,et al.  Study of the temperature effect on IR spectra of crystalline amino acids, dipeptides, and polyamino acids. IV. L-cysteine and DL-cysteine , 2008 .

[24]  Xiaogang Peng,et al.  Size-dependent dissociation pH of thiolate ligands from cadmium chalcogenide nanocrystals. , 2005, Journal of the American Chemical Society.

[25]  Xiaogang Peng,et al.  Experimental Determination of the Extinction Coefficient of CdTe, CdSe, and CdS Nanocrystals , 2003 .

[26]  Xiaogang Peng,et al.  Formation of high-quality CdS and other II-VI semiconductor nanocrystals in noncoordinating solvents: tunable reactivity of monomers. , 2002, Angewandte Chemie.

[27]  Xiaogang Peng,et al.  Stabilization of inorganic nanocrystals by organic dendrons. , 2002, Journal of the American Chemical Society.

[28]  Xiaogang Peng,et al.  Photochemical instability of CdSe nanocrystals coated by hydrophilic thiols. , 2001, Journal of the American Chemical Society.

[29]  Victor I. Klimov,et al.  Optical Nonlinearities and Ultrafast Carrier Dynamics in Semiconductor Nanocrystals , 2000 .

[30]  G. Humphrey,et al.  Spectra and bonding for copper(II)-aminoalcohol complexes—I: The I.R. spectra of complexes of mono-, di- and triethanolamine☆ , 1971 .

[31]  M. Kovalenko,et al.  Prospects of colloidal nanocrystals for electronic and optoelectronic applications. , 2010, Chemical reviews.

[32]  H. Fleck The detection and determination of triethanolamine , 1935 .