Defect-triggered catalysis with multiple reactive species over bismuth oxyhalides in the dark
暂无分享,去创建一个
Yihe Zhang | Xiaolei Zhang | T. Chen | Hongwei Huang | Yan Wang | Na Tian | Hongling Ou | Wen-Song Yu | Qiaoyu Zhang
[1] T. Chen,et al. Recent advances on Bi2WO6-based photocatalysts for environmental and energy applications , 2021 .
[2] Yihe Zhang,et al. Synergistic Polarization Engineering on Bulk and Surface for Boosting CO2 Photoreduction. , 2021, Angewandte Chemie.
[3] V. Pande,et al. Development of novel BiOBr0.75I0.25 nanostructures with remarkably High dark phase bactericidal activities. , 2021, Colloids and surfaces. B, Biointerfaces.
[4] Wen-Jun Zhang,et al. Inside Cover: Mn−O Covalency Governs the Intrinsic Activity of Co‐Mn Spinel Oxides for Boosted Peroxymonosulfate Activation (Angew. Chem. Int. Ed. 1/2021) , 2021 .
[5] Hexing Li,et al. Self-Driven Reactive Oxygen Species Generation via Interfacial Oxygen Vacancies on Carbon-Coated TiO2-x with Versatile Applications. , 2020, ACS applied materials & interfaces.
[6] Yihe Zhang,et al. Inside‐and‐Out Semiconductor Engineering for CO2 Photoreduction: From Recent Advances to New Trends , 2020, Small Structures.
[7] Liqi Bai,et al. BiOI/Bi2O2[BO2(OH)] heterojunction with boosted photocatalytic degradation performance for diverse pollutants under visible light irradiation , 2020 .
[8] Yihe Zhang,et al. External fields enhanced photocatalysis. , 2020, Angewandte Chemie.
[9] Yifan Guo,et al. Excellent antibacterial activities in the dark of ZnO nanoflakes with oxygen vacancies on exposed {21̄1̄0} facets , 2020 .
[10] Yihe Zhang,et al. Cooperation of oxygen vacancies and 2D ultrathin structure promoting CO2 photoreduction performance of Bi4Ti3O12. , 2020, Science bulletin.
[11] Yihe Zhang,et al. Macroscopic Spontaneous Polarization and Surface Oxygen Vacancies Collaboratively Boosting CO2 Photoreduction on BiOIO3 Single Crystals , 2020, Advanced materials.
[12] P. Horcajada,et al. Metal-Organic Frameworks for the Removal of Emerging Organic Contaminants in Water. , 2020, Chemical reviews.
[13] Xubiao Luo,et al. Efficient toxicity elimination of aqueous Cr(VI) by positively-charged BiOClxI1-x, BiOBrxI1-x and BiOClxBr1-x solid solution with internal hole-scavenging capacity via the synergy of adsorption and photocatalytic reduction. , 2020, Journal of hazardous materials.
[14] M. Sagir,et al. Improved photocatalytic performance of Gd and Nd co-doped ZnO nanorods for the degradation of methylene blue , 2020, Ceramics International.
[15] Shiyu Yao,et al. Ultrathin BiOX (X = Cl, Br, I) Nanosheets with Exposed {001} Facets for Photocatalysis , 2020 .
[16] Baoyi Wang,et al. Synergistic effect of internal electric field and oxygen vacancy on the photocatalytic activity of BiOBrxI1-x with isomorphous fluorine substitution. , 2019, Journal of colloid and interface science.
[17] P. Edwards,et al. Rapid synthesis of BiOBrxI1-x photocatalysts: Insights to the visible-light photocatalytic activity and strong deviation from Vegard’s law , 2019, Catalysis Today.
[18] Haiquan Xie,et al. Bismuth-Based Photocatalysts for Solar Photocatalytic Carbon Dioxide Conversion. , 2019, ChemSusChem.
[19] Yibo Feng,et al. Unprecedented Eighteen-Faceted BiOCl with a Ternary Facet Junction Boosting Cascade Charge Flow and Photo-redox. , 2019, Angewandte Chemie.
[20] Yihe Zhang,et al. Surface‐Halogenation‐Induced Atomic‐Site Activation and Local Charge Separation for Superb CO2 Photoreduction , 2019, Advanced materials.
[21] Yihe Zhang,et al. The Role of Polarization in Photocatalysis. , 2019, Angewandte Chemie.
[22] Yihe Zhang,et al. Three-in-One Oxygen Vacancies: Whole Visible-Spectrum Absorption, Efficient Charge Separation, and Surface Site Activation for Robust CO2 Photoreduction. , 2019, Angewandte Chemie.
[23] Jinan Wang,et al. BiOBrxI1−x/BiOBr heterostructure engineering for efficient molecular oxygen activation , 2019, Chemical Engineering Journal.
[24] Min Yang,et al. Ultrathin two-dimensional BiOBrxI1-x solid solution with rich oxygen vacancies for enhanced visible-light-driven photoactivity in environmental remediation , 2018, Applied Catalysis B: Environmental.
[25] Yi Xie,et al. Efficient Visible-Light-Driven CO2 Reduction Mediated by Defect-Engineered BiOBr Atomic Layers. , 2018, Angewandte Chemie.
[26] G. Armatas,et al. Removal of antibiotics, antibiotic-resistant bacteria and their associated genes by graphene-based TiO 2 composite photocatalysts under solar radiation in urban wastewaters , 2018 .
[27] Falong Jia,et al. Oxygen Vacancy-Mediated Photocatalysis of BiOCl: Reactivity, Selectivity, and Perspectives. , 2018, Angewandte Chemie.
[28] Yihe Zhang,et al. Macroscopic Polarization Enhancement Promoting Photo- and Piezoelectric-Induced Charge Separation and Molecular Oxygen Activation. , 2017, Angewandte Chemie.
[29] Ying Dai,et al. Enhancing visible light photocatalytic degradation performance and bactericidal activity of BiOI via ultrathin-layer structure , 2017 .
[30] Ying-hua Liang,et al. Enriched photoelectrocatalytic degradation and photoelectric performance of BiOI photoelectrode by coupling rGO , 2017 .
[31] Melissa L. Kemp,et al. Nanoparticle-induced oxidation of corona proteins initiates an oxidative stress response in cells. , 2017, Nanoscale.
[32] Zachary D. Hood,et al. Hydroxyl-Dependent Evolution of Oxygen Vacancies Enables the Regeneration of BiOCl Photocatalyst. , 2017, ACS applied materials & interfaces.
[33] Yihe Zhang,et al. Rational design on 3D hierarchical bismuth oxyiodides via in situ self-template phase transformation and phase-junction construction for optimizing photocatalysis against diverse contaminants , 2017 .
[34] Jie Ren,et al. Synthesis of {111} Facet-Exposed MgO with Surface Oxygen Vacancies for Reactive Oxygen Species Generation in the Dark. , 2017, ACS applied materials & interfaces.
[35] Lizhi Zhang,et al. Solar Water Splitting and Nitrogen Fixation with Layered Bismuth Oxyhalides. , 2017, Accounts of chemical research.
[36] Yihe Zhang,et al. In situ assembly of BiOI@Bi12O17Cl2 p-n junction: charge induced unique front-lateral surfaces coupling heterostructure with high exposure of BiOI {001} active facets for robust and nonselective photocatalysis , 2016 .
[37] Z. Ning,et al. Investigation on the mechanism of non‐photocatalytically TiO2‐induced reactive oxygen species and its significance on cell cycle and morphology , 2016, Journal of applied toxicology : JAT.
[38] Hanqing Yu,et al. Fabrication of BiOBrxI1−x photocatalysts with tunable visible light catalytic activity by modulating band structures , 2016, Scientific Reports.
[39] Morten H. H. Nørholm,et al. Generation of mutation hotspots in ageing bacterial colonies , 2016, Scientific Reports.
[40] Rajagopalan Vijayaraghavan,et al. Insight into the Mechanism of Antibacterial Activity of ZnO: Surface Defects Mediated Reactive Oxygen Species Even in the Dark. , 2015, Langmuir : the ACS journal of surfaces and colloids.
[41] Yihe Zhang,et al. In situ co-pyrolysis fabrication of CeO2/g-C3N4 n–n type heterojunction for synchronously promoting photo-induced oxidation and reduction properties , 2015 .
[42] Yihe Zhang,et al. In situ crystallization for fabrication of a core-satellite structured BiOBr-CdS heterostructure with excellent visible-light-responsive photoreactivity. , 2015, Nanoscale.
[43] Yihe Zhang,et al. Anionic Group Self-Doping as a Promising Strategy: Band-Gap Engineering and Multi-Functional Applications of High-Performance CO32–-Doped Bi2O2CO3 , 2015 .
[44] J. Shang,et al. Efficient Visible Light Nitrogen Fixation with BiOBr Nanosheets of Oxygen Vacancies on the Exposed {001} Facets. , 2015, Journal of the American Chemical Society.
[45] Yihe Zhang,et al. Fabrication of multiple heterojunctions with tunable visible-light-active photocatalytic reactivity in BiOBr-BiOI full-range composites based on microstructure modulation and band structures. , 2015, ACS applied materials & interfaces.
[46] T. Thongtem,et al. Characterization and antibacterial activity of nanostructured ZnO thin films synthesized through a hydrothermal method , 2014 .
[47] A. Salleo,et al. Multi-phase microstructures drive exciton dissociation in neat semicrystalline polymeric semiconductors , 2013, 1310.8002.
[48] Huacan Song,et al. The Ag–BiOBrxI1−x composite photocatalyst: Preparation, characterization and their novel pollutants removal property , 2013 .
[49] D. Hui,et al. Antimicrobial mechanism based on H2O2 generation at oxygen vacancies in ZnO crystals. , 2013, Langmuir : the ACS journal of surfaces and colloids.
[50] Y. Sasson,et al. Hierarchical Nanostructured 3D Flowerlike BiOClxBr1–x Semiconductors with Exceptional Visible Light Photocatalytic Activity , 2013 .
[51] J. Nan,et al. Efficient adsorption and visible-light photocatalytic degradation of tetracycline hydrochloride using mesoporous BiOI microspheres. , 2012, Journal of hazardous materials.
[52] Jiujun Zhang,et al. The {001} facets-dependent high photoactivity of BiOCl nanosheets. , 2011, Chemical communications.
[53] Fumin Wang,et al. Simple Solvothermal Routes to Synthesize 3D BiOBrxI1-x Microspheres and Their Visible-Light-Induced Photocatalytic Properties , 2011 .
[54] Chuncheng Chen,et al. Semiconductor-mediated photodegradation of pollutants under visible-light irradiation. , 2010, Chemical Society reviews.