[1] H AI Z, W HO, S LEE et al. Efficient photocatalytic removal of NO in indoor air with hierarchical bismuth oxybromide nanoplate microspheres under visible light. Environmental Science Technology, 43, 4143-4150(2009).
[2] HUA WANG, YAN SU, XIN ZHAO HUA et al. Photocatalytic oxidation of aqueous ammonia using atomic single layer graphitic- C3N4. Environmental Science and Technology, 48, 11984-11990(2014).
[3] J LASEK, YI-HUI YU, S WU J C. Removal of NO
x by photocatalytic processes. Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 14, 29-52(2013).
[4] R ASAHI, T MORIKAWA, H IRIE et al. Nitrogen-doped titanium dioxide as visible-light-sensitive photocatalyst: designs, developments, and prospects. Chemical Reviews, 114, 9824-9852(2014).
[5] M KAPILASHRAMI, YAN-FENG ZHANG, YI-SHENG LIU et al. Probing the optical property and electronic structure of TiO2 nanomaterials for renewable energy applications. Chemical Reviews, 114, 9662-9707(2014).
[6] YANG LIU, SHAN YU, KAI-WEN ZHENG et al. NO photo- oxidation and in-situ DRIFTS studies on N-doped Bi2O2CO3/CdSe quantum dot composite. Journal of Inorganic Materials, 34, 425-432(2019).
[7] ZI-LIN NI, YAN-JUAN SUN, YU-XIN ZHANG et al. Fabrication, modification and application of (BiO)2CO3-based photocatalysts: a review. Applied Surface Science, 365, 314-335(2016).
[8] YUAN-YUAN LIU, ZE-YAN WANG, BAI-BIAO HUANG et al. Preparation, electronic structure, and photocatalytic properties of Bi2O2CO3 nanosheet. Applied Surface Science, 257, 172-175(2010).
[9] I NAKAMURA, N NEGISHI, S KUTSUNA et al. Role of oxygen vacancy in the plasma-treated TiO2 photocatalyst with visible light activity for NO removal. Journal of Molecular Catalysis A: Chemical, 161, 205-212(2000).
[10] KANG-RONG LAI, WEI WEI, YING-TAO ZHU et al. Effects of oxygen vacancy and N-doping on the electronic and photocatalytic properties of Bi2MO6(
M=Mo, W). Journal of Solid State Chemistry, 187, 103-108(2012).
[11] A BILMES S, P MANDELBAUM. Surface and electronic structure of titanium dioxide photocatalysts. Journal of Physical Chemistry B, 104, 9851-9858(2000).
[12] LI-QIANG JING, BAI-FU XIN, FU-LONG YUAN et al. Effects of surface oxygen vacancies on photophysical and photochemical processes of Zn-doped TiO2 nanoparticles and their relationships. Journal of Physical Chemistry B, 110, 17860-17865(2006).
[13] J NOWPTNY. Titanium dioxide-based semiconductors for solar- driven environmentally friendly applications: impact of point defects on performance. Energy Environmental Science, 1, 565-572(2008).
[14] K NOWOTNY M, R SHEPPARD L, T BAK et al. Defect chemistry of titanium dioxide. application of defect engineering in processing of TiO2-based photocatalysts. Journal of Physical Chemistry C, 112, 5275-5300(2008).
[15] JIAN-CHUN WANG, PING LIU, XIAN-ZHI FU et al. Relationship between oxygen defects and the photocatalytic property of ZnO nanocrystals in nafion membranes. Langmuir, 25, 1218-1223(2009).
[16] R SCHAUB, P THOSTRUP, et al. Oxygen vacancies as active sites for water dissociation on rutile TiO2(
110). Physical Review Letters, 87, 266104-266107(2001).
[17] XIAO-BO CHEN, LEI LIU, Y YU P et al. Increasing solar absorption for photocatalysis with black hydrogenated titanium dioxide nanocrystals. Science, 331, 746-750(2011).
[18] S ERIKSEN, G EGDELL R. Electronic excitations at oxygen deficient TiO2(110) surfaces: a study by EELS. Surface Science, 180, 263-278(1987).
[19] L KNOTEK M, J FEIBELMAN P. Ion desorption by core-hole auger decay. Physical Review Letters, 14, 964-967(1978).
[20] A PANAYOTOV D, R MORRIS J. Thermal decomposition of a chemical warfare agent simulant (DMMP) on TiO2: adsorbate reactions with lattice oxygen as studied by infrared spectroscopy. Journal of Physical Chemistry C, 113, 15684-15691(2009).
[21] E WACHS I, M JEHNG J, W UEDA. Determination of the chemical nature of active surface sites present on bulk mixed metal oxide catalysts. Journal of Physical Chemistry, 109, 2275-2284(2005).
[22] ZI-YAN ZHAO, YING ZHOU, FANG WANG et al. Polyaniline- decorated {001} facets of Bi2O2CO3 nanosheets: in situ oxygen vacancy formation and enhanced visible light photocatalytic activity. ACS Applied Materials Interfaces, 7, 730-737(2015).
[23] WEI ZHAO, YUN WANG, JIAN WANG AI et al. Novel Bi2O2CO3/polypyrrole/g-C3N4 nanocomposites with efficient photocatalytic and nonlinear optical properties. RSC Advances, 7, 7658-7670(2017).
[24] H ULLAH, A TAHIR A, K MALLICKT. Polypyrrole/TiO2 composites for the application of photocatalysis. Sensors and Actuators B, 241, 1161-1169(2017).
[25] Z MOHD TARMIZI E, H BAQIAH, A TALIB Z. Facile synthesis and characterizations of polypyrrole/BiOCl hybrid composites. Journal of Solid State Electrochemistry, 21, 3247-3255(2017).
[26] ZI-YAN ZHAO, YUE-HAN CAO, FAN DONG et al. The activation of oxygen through oxygen vacancy on BiOCl/PPy to inhibit toxic intermediates and enhance the activity of photocatalytic NO removal. Nanoscale, 11, 6360-6367(2019).
[27] QIAN ZHANG, YING ZHOU, FANG WANG et al. From semiconductors to semimetals: bismuth as photocatalyst for NO oxidation in air. Journal of Materials Chemistry A, 2, 11065-11072(2014).
[28] FANG CHEN XUE, YING HUANG, CHUANG ZHANG KAI et al. Synthesis and high-performance of carbonaceous polypyrrole nanotubes coated with SnS2 nanosheets anode materials for lithium ion batteries. Chemical Engineering Journal, 330, 470-479(2017).
[29] YI-XIN LIU, HONG-MA MA, YONG ZHANG et al. Visible light photoelectrochemical aptasensor for adenosine detection based on CdS/PPy/g-C3N4 nanocomposites. Biosens and Bioelectronics, 86, 439-445(2016).
[30] FAN DONG, AN-MIN ZHENG, YAN-JUAN SUN et al. One-pot template-free synthesis, growth mechanism and enhanced photocatalytic activity of monodisperse (BiO)2CO3 hierarchical hollow microspheres self-assembled with single-crystalline nanosheets. CrystEngComm, 14, 3534-3544(2012).
[31] FAN DENG, LU-JUAN MIN, XU-BIAO LUO et al. Visible-light photocatalytic degradation performances and thermal stability due to the synergetic effect of TiO2 with conductive copolymers of polyaniline and polypyrrole. Nanoscale, 5, 8703-8710(2013).
[32] P MADHUSUDAN, JING-RAN RAN, JUN ZHANG et al. Novel urea assisted hydrothermal synthesis of hierarchical BiVO4/Bi2O2CO3 nanocomposites with enhanced visible-light photocatalytic activity. Applied Catalysis B: Environmental, 110, 286-295(2011).
[33] FAN DONG, YAN-JUAN SUN, MIN FU et al. Novel in situ N-Doped (BiO)2CO3 hierarchical microspheres self-assembled by nanosheets as efficient and durable visible light driven photocatalyst. Langmuir, 28, 766-773(2012).
[34] LI-QUN YE, KE-JIAN DENG, FENG XU et al. Increasing visible- light absorption for photocatalysis with black BiOCl. Physical Chemistry Chemical Physics, 14, 82-85(2012).
[35] XIAO-YANG PAN, MIN-QUAN YANG, XIAN-ZHI FU et al. Defective TiO2 with oxygen vacancies: synthesis, properties and photocatalytic applications. Nanoscale, 5, 3601-3614(2013).
[36] FENG-CAI LEI, YONG-FU SUN, KA-TONG LIU et al. Oxygen vacancies confined in ultrathin indium oxide porous sheets for promoted visible-light water splitting. Journal of American Chemical Society, 136, 6826-6829(2014).
[37] YING ZHOU, QIAN ZHANG, YUAN-HUA LIN et al. One-step hydrothermal synthesis of hierarchical Ag/Bi2WO6 composites: in situ growth monitoring and photocatalytic activity studies. Science China Chemistry, 56, 435-442(2013).
[38] NIAN TANG, YUE LIU, HAI-QIANG WANG et al. Mechanism study of NO catalytic oxidation over MnOx/TiO2 catalysts. Journal of Physical of Chemistry C, 115, 8214-8220(2011).
[39] M KANTCHEVA. Identification, stability, and reactivity of NO
x species adsorbed on titania-supported manganese catalysts. Journal of Catalysis, 204, 479-494(2001).
[40] K HADJIIVANOV, V AVREYSKA, D KLISSURSKI et al. Surface species formed after NO adsorption and NO+O2 coadsorption on ZrO2 and Sulfated ZrO2: an FTIR spectroscopic study. Langmuir, 18, 1619-1625(2002).
[41] J LAANE, R OHLSEN J. Characterization of Nitrogen Oxides by Vibrational Spectroscopy. John Wiley & Sons,
Inc., 27, 465-513(1980).
[42] MEI CHEN, ZHI-HUA WANG, DONG-MEI HAN et al. Porous ZnO polygonal nanoflakes: synthesis, use in high-sensitivity NO2 gas sensor, and proposed mechanism of gas sensing. Journal of Physical Chemistry C, 115, 12763-12773(2011).
[43] YANG LIU, SHAN YU, ZI-YANG ZHAO et al. N-doped Bi2O2CO3/graphene quantum dot composite photocatalyst: enhanced visible-light photocatalytic NO oxidation and in situ DRIFTS studies. Journal of Physical Chemistry C, 121, 12168-12177(2017).
[44] CAI LI, HUI JIANG, LU-XI WANG. Enhanced photo-stability and photocatalytic activity of Ag3PO4. via modification with BiPO4 and polypyrrole. Applied Surface Science, 420, 43-52(2017).
[45] ZHEN-YU WANG, WEI GUAN, YAN-JUAN SUN et al. Water- assisted production of honeycomb-like g-C3N4 with ultralong carrier lifetime and outstanding photocatalytic activity. Nanoscale, 7, 2471-2479(2015).