| 1 - 2 |
Surface analysis and dynamics Preface
Lee J, Eiswirth M, Schlogl R |
| 3 - 7 |
Surface segregation and oxidation of Pt3Ni(111) alloys under oxygen environment.
Lee HC, Kim BM, Jeong CK, Toyoshima R, Kondoh H, Shimada T, Mase K, Mao B, Liu Z, Lee H, Huang CQ, Li WX, Ross PN, Mun BS |
| 8 - 13 |
Controlling the selectivity of CO2 electroreduction on copper: The effect of the electrolyte concentration and the importance of the local pH
Varela AS, Kroschel M, Reier T, Strasser P |
| 14 - 20 |
In situ analysis of catalytically active Pd surfaces for CO oxidation with near ambient pressure XPS
Kondoh H, Toyoshima R, Monya Y, Yoshida M, Mase K, Amemiya K, Mun BS |
| 21 - 31 |
Strong metal-support interaction and alloying in Pd/ZnO catalysts for CO oxidation
Kast P, Friedrich M, Girgsdies F, Krohnert J, Teschner D, Lunkenbein T, Behrens M, Schlogl R |
| 32 - 38 |
Superhydrophobic surfaces with photocatalytic activity under UV and visible light irradiation
Lee JH, Park EJ, Kim DH, Jeong MG, Kim YD |
| 39 - 45 |
In-situ surface analysis of AuPd(110) under elevated pressure of CO
Languille MA, Ehret E, Lee HC, Jeong CK, Toyoshima R, Kondoh H, Mase K, Jugnet Y, Bertolini JC, Aires FJCS, Mun BS |
| 46 - 54 |
Support-shape dependent catalytic activity in Pt/alumina systems using ultra-small (USANS) and small angle neutron scattering (SANS)
Kim SH, Han S, Ha H, Byun JY, Kim MH |
| 55 - 59 |
Facile synthesis of Pd nanoparticles encapsulated into hollow carbon nanospheres with robust catalytic performance
Liu HY, Feng ZB, Wang J, Zhang LY, Su DS |
| 60 - 65 |
Ab initio molecular dynamics simulations of the O-2/Pt(111) interaction
Gross A |
| 66 - 71 |
Probing the electrooxidation of weakly adsorbed formic acid on Pt(100)
Tong YJ, Cai KD, Wolf M, Campen RK |
| 72 - 81 |
The electronic, chemical and electrocatalytic processes and intermediates on iron oxide surfaces during photoelectrochemical water splitting
Braun A, Hu YL, Boudoire F, Bora DK, Sarma DD, Gratzel M, Eggleston CM |
| 82 - 88 |
Effect of transition metal induced pore structure on oxygen reduction reaction of electro spun fibrous carbon
Shin D, An X, Choun M, Lee J |
| 89 - 94 |
Electrostatic spray deposition of transparent tungsten oxide thin-film photoanodes for solar water splitting
Yoon H, Mali MG, Kim MW, Al-Deyab SS, Yoon SS |
| 95 - 99 |
Control of the surface atomic population of Rh0.5Pd0.5 bimetallic nanoparticles supported on CeO2
Bernardi F, Grass ME, Hong YP, Chang R, Jabeen N, Zhang CJ, Eichhorn BW, Seo B, Alayoglu S, Hussain Z, Joo SH, Liu Z |
| 100 - 106 |
Toluene oxidation catalyzed by NiO/SiO2 and NiO/TiO2/SiO2: Towards development of humidity-resistant catalysts
Park EJ, Lee JH, Kim KD, Kim DH, Jeong MG, Kim YD |
| 107 - 111 |
Gold catalyst reactivity for CO2 electro-reduction: From nano particle to layer
Nursanto EB, Jeon HS, Kim C, Jee MS, Koh JH, Hwang YJ, Min BK |
| 112 - 118 |
Synthesis-structure-performance correlation for poly(phenylenediamine)s/iron/carbon non-precious metal catalysts for oxygen reduction reaction
Zhu YS, Zhang BS, Feng ZB, Su DS |
| 119 - 125 |
Controlling Cu2ZnSnS4 photocatalytic ability through alterations in sulfur availability
Turnbull MJ, Khoshmashrab S, Wang ZQ, Harbottle R, Sham TK, Ding ZF |
| 126 - 134 |
Green approach for hierarchical nanostructured Ag-ZnO and their photocatalytic performance under sunlight
Patil SS, Mali MG, Tamboli MS, Patil DR, Kulkarni MV, Yoon H, Kim H, Al-Deyab SS, Yoon SS, Kolekar SS, Kale BB |
| 135 - 139 |
Doping of anodic nanotubular TiO2 electrodes with MnO2 for use as catalysts in water oxidation
Seong M, Kim S, Yoo H, Choi J |
| 140 - 147 |
Cold gas spraying - A promising technique for photoelectrodes The example TiO2
Herrmann-Geppert I, Bogdanoff P, Emmler T, Dittrich T, Radnik J, Klassen T, Gutzmann H, Schieda M |
| 148 - 157 |
Superior pore network retention of carbon derived from naturally dried ginkgo leaves and its enhanced oxygen reduction performance
Razmjooei F, Singh KP, Yu JS |
| 158 - 164 |
Ameliorated performance in a direct carbon fuel cell using Sn mediator on Ni-YSZ anode surface
Jang H, Eom J, Ju H, Lee J |
