Nano-sized manganese oxides as biomimetic catalysts for water oxidation in artificial photosynthesis: a review

Najafpour, Mohammad Mahdi; Rahimi, Fahimeh; Aro, Eva‐Mari; Lee, Choon Hwan; Allakhverdiev, Suleyman I.

doi:10.1098/rsif.2012.0412

Cited by 127 publications

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“…For particle sizes below 100 nm, these differences affect the free energies of phase transitions and of oxidation-reduction reactions, shifting the latter by as much as several log(fO 2 ) units at a given temperature. This thermodynamic effect on redox equilibria is significant when one considers electrochemical potentials for water splitting or other catalytic reactions involving nanoparticles (14). In a chargecompensated layered structure, the Mn(III)/Mn(IV) equilibrium will be different from that of binary Mn-oxide phase assemblages, namely, Mn 3 O 4 (hausmannite), Mn 2 O 3 (bixbyite), and MnO 2 (pyrolusite).…”

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“…Because the capability for efficient water oxidation is unique to photosystem II among all biological photosystems (6, 7), these CaMnO materials that mimic the elemental composition, manganese oxidation state, and particle size of the photosynthetic water oxidation center are of special interest (8)(9)(10)(11)(12). Although a number of other metal compounds function as water-oxidizing catalysts (13), many contain rare and expensive metals like iridium and ruthenium; the advantage of manganese oxides (Mn-oxides) is that they are earth-abundant, inexpensive, and environmentally friendly (1)(2)(3)(4)(5)14).CaMnO phases have short-range order structure and lamellar morphology (12), which are hallmarks of phyllomanganates (classically known as hydrous Mn-oxides), and they possess a layered structure (15)(16)(17)(18)(19)(20). In this family of structures, manganese octahedra (and vacancies) form the layers, and charge-balancing cations (i.e., alkali and alkaline earth ions, protons) and water occupy the interlayer space.…”

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Energetic basis of catalytic activity of layered nanophase calcium manganese oxides for water oxidation

Birkner

Nayeri²,

Pashaei³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Previous measurements show that calcium manganese oxide nanoparticles are better water oxidation catalysts than binary manganese oxides (Mn 3 O 4 , Mn 2 O 3 , and MnO 2 ). The probable reasons for such enhancement involve a combination of factors: The calcium manganese oxide materials have a layered structure with considerable thermodynamic stability and a high surface area, their low surface energy suggests relatively loose binding of H 2 O on the internal and external surfaces, and they possess mixed-valent manganese with internal oxidation enthalpy independent of the Mn 3+ / Mn 4+ ratio and much smaller in magnitude than the Mn 2 O 3 -MnO 2 couple. These factors enhance catalytic ability by providing easy access for solutes and water to active sites and facile electron transfer between manganese in different oxidation states.nanomaterials | thermochemistry R esearch on calcium manganese oxides (CaMnOs) has been inspired by the water-oxidation centers in photosystem II (1-5), which is a manganese-calcium cluster Mn 4 CaO 5 (H 2 O) 4 supported by a protein environment. Because the capability for efficient water oxidation is unique to photosystem II among all biological photosystems (6, 7), these CaMnO materials that mimic the elemental composition, manganese oxidation state, and particle size of the photosynthetic water oxidation center are of special interest (8)(9)(10)(11)(12). Although a number of other metal compounds function as water-oxidizing catalysts (13), many contain rare and expensive metals like iridium and ruthenium; the advantage of manganese oxides (Mn-oxides) is that they are earth-abundant, inexpensive, and environmentally friendly (1)(2)(3)(4)(5)14).CaMnO phases have short-range order structure and lamellar morphology (12), which are hallmarks of phyllomanganates (classically known as hydrous Mn-oxides), and they possess a layered structure (15)(16)(17)(18)(19)(20). In this family of structures, manganese octahedra (and vacancies) form the layers, and charge-balancing cations (i.e., alkali and alkaline earth ions, protons) and water occupy the interlayer space.Our previous calorimetric studies of various oxide nanoparticles, including those of manganese, iron, and cobalt (21), show that different polymorphs and phases with different oxidation states have significantly different surface energies. For particle sizes below 100 nm, these differences affect the free energies of phase transitions and of oxidation-reduction reactions, shifting the latter by as much as several log(fO 2 ) units at a given temperature. This thermodynamic effect on redox equilibria is significant when one considers electrochemical potentials for water splitting or other catalytic reactions involving nanoparticles (14). In a chargecompensated layered structure, the Mn(III)/Mn(IV) equilibrium will be different from that of binary Mn-oxide phase assemblages, namely, Mn 3 O 4 (hausmannite), Mn 2 O 3 (bixbyite), and MnO 2 (pyrolusite). Thus, particle size, morphology, crystal structure, and mixed valence in the more complex ...

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Energetic basis of catalytic activity of layered nanophase calcium manganese oxides for water oxidation

Birkner

Nayeri²,

Pashaei³

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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“…Em função de sua estabilidade química, de seu baixo custo e de ser ambientalmente benigna, a família dos óxidos de manganês tem recebido grande atenção atualmente [9,[11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30], e esses óxidos têm se destacado por suas potenciais aplicações na área de materiais para aplicação em energia, por exemplo, como catalisadores na oxidação da água, em sistemas de fotossíntese artificial [23][24][25][26][27], ou como catalisadores na reação de redução de oxigênio molecular (RRO) em pilhas a combustível alcalinas [27][28][29][30]. Recentemente, vários artigos vêm estudando a atividade catalítica dos óxidos de manganês na reação de redução de oxigênio molecular [11][12][13][14][15][16][17][27][28][29][30].…”

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Síntese de óxidos mistos SiO2 /Mn xOy para aplicação na reação de redução de O2

et al. 2013

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RESUMOOs óxidos mistos SiO 2 /M x O y obtidos pelo processo sol-gel, designados de compósitos, normalmente aliam as propriedades mecânicas e químicas da sílica gel com as propriedades químicas do óxido metálico (M x O y ), apresentando propriedades tais como: elevado grau de dispersão e homogeneidade das partículas do óxido metálico na matriz de sílica, assim como elevada resistência mecânica e química. O objetivo deste trabalho foi o de preparar e caracterizar materiais do sistema SiO 2 /Mn x O y , obtidos pelo processo sol-gel, utilizando diferentes concentrações dos precursores de Mn (II), acetato ou nitrato. A técnica de fluorescência de raios X (FRX) mostrou que a concentração do óxido metálico nos materiais é dependente do precursor utilizado e da sua concentração no meio reacional, variando de 9,4% até 20,9% em massa. A maior concentração de óxido de manganês foi obtida quando se utilizou como precursor o (CH 3 CO 2 ) 2 Mn.4H 2 O. Os espectros de infravermelho indicam que a rede de SiO 2 é pouco perturbada pelo aumento da quantidade de óxido de manganês, sugerindo que o Mn x O y está disperso na superfície da matriz de sílica. Os difratogramas de raiosX (DRX) mostram que os materiais apresentam baixa cristalinidade. No entanto, observa-se uma mudança no DRX em 2θ = 35,7 o quando o material é aquecido a 400 0 C, provavelmente devido à formação de cristalitos de Mn 3 O 4 . O método de síntese proposto para os materiais SiO 2 /Mn x O y é reprodutível. A aplicação destes materiais como eletrodos para a redução de O 2 foi avaliada e observou-se que a atividade eletrocatalítica desses materiais pode ser aumentada através do seu aquecimento a 400 0 C. Palavras-chave:Sol-Gel, óxidos mistos, sílica gel, óxido de manganês, compósito. ABSTRACTThe mixed oxides SiO 2 /M x O y obtained by the sol-gel process, designated as composites, usually combine both mechanical and chemical properties of silica gel with the chemical properties of metal oxide (M x O y ), showing properties such as: high degree of dispersion and homogeneity of metal oxide particles in the silica matrix, as well as high mechanical and chemical resistance. The goal of this work was to prepare and characterize materials in the system SiO 2 /Mn x Oy obtained by the sol-gel process, using different concentrations of Mn (II) precursors (acetate or nitrate). The technique of X-ray fluorescence showed that the concentration of metal oxide in the materials is dependent on the precursor used and its concentration, ranging from 9.4% up to 20.9% by mass. The highest concentration of manganese oxide was obtained when (CH 3 CO 2 ) 2 Mn.4H 2 O was used as precursor. The infrared spectra indicate that the network of SiO 2 is not disturbed by the increase in the quantity of manganese oxide, suggesting that the Mn x O y is dispersed on the surface of the silica matrix. The X-ray diffraction showed the low crystallinity of these materials. However, there is a change in the XRD on 2θ = 35.7 0 when the material is heated to 400 0 C, probably due to the formation of Mn 3...

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“…201 A variety of Mn oxides have been found to exhibit significant activity toward water oxidation, and particular oxidation states and structures seem to be favored over others. [202][203][204] What is often disregarded is that under OER testing these materials dynamically change their structure and oxidation state, converting often to hydroxides. In addition, the structure of the material is much less important than that of the surface, which has been characterized by Doyle as an octhedrally coordinated surface structure of metal complexes.…”

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Titania Nanotubes by Electrochemical Anodization for Solar Energy Conversion

Tsui

Zangari

2014

J. Electrochem. Soc.

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TiO 2 nanotube arrays (NTs) are a promising platform for the conversion of sunlight to electricity in photovoltaic systems or to fuels in photoelectrochemical solar cells. We overview the properties and functionality of the various components of TiO 2 NT-based devices, discuss their integration in the energy conversion system and summarize recent advances in the field. In particular, we discuss the electronic and charge transport properties of TiO 2 NTs that govern the device performance and efficiency. Since the main challenge for the practical use of TiO 2 is the inability to absorb visible light, particular attention is paid to available techniques for TiO 2 sensitization, extending absorption beyond the UV portion of the solar spectrum. These techniques include doping to alter the bandgap and pairing TiO 2 with dyes, inorganic narrow band-gap semiconductors, or metal nanoparticles that exhibit plasmonic behavior. Various catalysts have been successfully paired with TiO 2 to accelerate the photocatalytic reactions of interest; materials, synthesis methods and catalytic mechanisms will also be discussed. Finally, we give a prospective outlook on the future of TiO 2 nanotubes for photoelectrochemical applications and identify areas for future research.

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Nano-sized manganese oxides as biomimetic catalysts for water oxidation in artificial photosynthesis: a review

Cited by 127 publications

References 90 publications

Energetic basis of catalytic activity of layered nanophase calcium manganese oxides for water oxidation

Energetic basis of catalytic activity of layered nanophase calcium manganese oxides for water oxidation

Síntese de óxidos mistos SiO2 /Mn xOy para aplicação na reação de redução de O2

Titania Nanotubes by Electrochemical Anodization for Solar Energy Conversion

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