| 1 - 1 |
Preface
Subramanian V, Bahnemann D, Madras G |
| 2 - 11 |
Improved photocatalytic ozone abatement over transition metal-grafted titanium dioxide
Patzsch J, Bloh JZ |
| 12 - 17 |
Anatase and rutile in evonik aeroxide P25: Heterojunctioned or individual nanoparticles?
Jiang XZ, Manawan M, Feng T, Qian RF, Zhao T, Zhou GD, Kong FT, Wang Q, Dai SY, Pan JH |
| 18 - 27 |
The influence of low irradiance and electrolytes on the mineralization efficiency of organic pollutants using the Vis-active photocatalytic tandem CuInS2/TiO2/SnO2
Duta A, Andronic L, Enesca A |
| 28 - 38 |
Novel synthesis approaches for WO3-TiO2/MWCNT composite photocatalysts-problematic issues of photoactivity enhancement factors
Bardos E, Kovacs G, Gyulavari T, Nemeth K, Kecsenovity E, Berki P, Baia L, Pap Z, Hernadi K |
| 39 - 49 |
TiO2-MgO mixed oxide nanomaterials for solar energy conversion
Selvaratnam B, Koodali RT |
| 50 - 57 |
Synthesis of ultrasound assisted nanostuctured photocatalyst (NiO supported over CeO2) and its application for photocatalyticas as well as sonocatalytic dye degradation
Sancheti SV, Saini C, Ambati R, Gogate PR |
| 58 - 70 |
Interparticle double charge transfer mechanism of heterojunction alpha-Fe2O3/Cu2O mixed oxide catalysts and its visible light photocatalytic activity
Lakhera SK, Watts A, Hafeez HY, Neppolian B |
| 71 - 80 |
Ag and CuO impregnated on Fe doped ZnO for bacterial inactivation under visible light
Gupta R, Eswar NK, Modak JM, Madras G |
| 81 - 88 |
Insights into the photoactivity of iron modified bismuth titanate (Fe_BTO) nanoparticles
Khanal V, Ragsdale W, Gupta S, Subramanian VR |
| 89 - 98 |
A green approach for degradation of organic pollutants using rare earth metal doped bismuth oxide
Raza W, Bahnemann D, Muneer M |
| 99 - 111 |
Mechanism of formation, structural characteristics and photocatalytic activities of hierarchical-structured bismuth-tungstate particles
Hori H, Takase M, Takashima M, Amano F, Shibayama T, Ohtani B |
| 112 - 123 |
Novel synthesis of PbBiO2Cl/BiOCl nanocomposite with enhanced visible-driven-light photocatalytic activity
Liu FY, Jiang YR, Chen CC, Lee WW |
| 124 - 135 |
Transfiguring UV light active "metal oxides" to visible light active photocatayst by reduced graphene oxide hypostatization
Samal A, Das DP |
| 136 - 144 |
On the measured optical bandgap values of inorganic oxide semiconductors for solar fuels generation
Roy D, Samu GF, Hossain MK, Janaky C, Rajeshwar K |
| 145 - 151 |
Enhanced photoelectrochemical CO2-reduction system based on mixed Cu2O - nonstoichiometric TiO2 photocathode
Szaniawska E, Bienkowski K, Rutkowska IA, Kulesza PJ, Solarska R |
| 152 - 159 |
Strontium titanates with perovskite structure as photo catalysts for reduction of CO2 by water: Influence of co-doping with N, S & Fe
Jeyalakshmi V, Mahalakshmy R, Krishnamurthy KR, Viswanathan B |
| 160 - 172 |
g-C3N4 based composite photocatalysts for photocatalytic CO2 reduction
Sun ZX, Wang HQ, Wu ZBA, Wang LZ |
| 173 - 182 |
Flux method fabrication of potassium rare-earth tantalates for CO2 photoreduction using H2O as an electron donor
Huang ZA, Teramura K, Asakura H, Hosokawa S, Tanaka T |
