參考文獻

［1］Li W B，Wang J X，Gong H.Catalytic combustion ofVOCs on non-noble metal catalysts.Catalysis Today，2009.148（1-2）：81-87.

［2］Yu D，Wang X，Li D，et al.Catalytic combustion of chlorobenzene over Mn-Ce-La-O mixed oxide catalysts. Journal of Hazardous Materials，2011，188（1-3）：132-139.

［3］Pires J，A Carvalho，M B de Carvalho.Adsorption ofVolatile organic compounds in Y zeolites and pillared clays.Microporous and Mesoporous Materials，2001，43（3）：277-287.

［4］Streger S H，Condee C W，Togna A P，et al.Degradation of hydrohalocarbons and brominated compounds by methane-and propane-oxidizing bacteria.Environmental Science & Technology，1999，33（24）：4477-4482.

［5］Pitk?aho S，Ojal S，Maunul T，et al.Oxidation of dichloromethane and perchloroethylene as single compounds and in mixtures.Applied Catalysis B：Environmental，2011，102（3-4）：395-403.

［6］Li H，Lu G，Dai Q，et al.Efficient low-temperature catalytic combustion of trichloroethylene over flower-like mesoporous Mn-doped CeO₂microspheres.Applied Catalysis B：Environmental，2011，102（3-4）：475-483.

［7］黎維彬，龔浩.催化燃燒去除VOCs污染物的最新進展.物理化學學報，2010（04）：885-894.

［8］Taralunga M，Mijoin J，Magnoux P.Catalytic destruction of chlorinated POPs—Catalytic oxidation of chlorobenzene over PtHFAU catalysts.Applied Catalysis B：Environmental，2005，60（3-4）：163-171.

［9］Giraudon J M，Elhachimi A，Leclercq G，Catalytic oxidation of chlorobenzene over Pd/perovskites.Applied Catalysis B：Environmental，2008，84（1-2）：251-261.

［10］Scirè S，MinicòS，Crisafulli C.Pt catalysts supported on H-type zeolites for the catalytic combustion of chlorobenzene.Applied Catalysis B：Environmental，2003，45（2）：117-125.

［11］李鵬，何熾，程杰等，含鈀類水滑石衍生復合氧化物Pd/M₃AlO（M=Mg，Co，Ni，Cu，Zn）催化劑上氯苯的催化氧化.物理化學學報，2009（11）：2279-2284.

［12］Li D，Zheng Y，Wang X Y.Effect of phosphoric acid on catalytic combustion of trichloroethylene over Pt/P-MCM-41.Applied Catalysis a-General，2008，340（1）：33-41.

［13］Van den Brink R W，Louw R，Mulder P.Increased combustion rate of chlorobenzene on Pt/γ-Al₂O₃in binary mixtures with hydrocarbons and with carbon monoxide.Applied Catalysis B：Environmental，2000，25（4）：229-237.

［14］Dai Q G，Wang X Y，Lu G Z.Low-temperature catalytic combustion of trichloroethylene over cerium oxide and catalyst deactivation.Applied Catalysis B-Environmental，2008，81（3-4）：192-202.

［15］Wang X Y，Kang Q，Li D.Catalytic combustion of chlorobenzene over MnO_x-CeO₂mixed oxide catalysts.Applied Catalysis B：Environmental，2009，86（3-4）：166-175.

［16］de Rivas B.，López-Fonseca R，et al.Impact of induced chlorine-poisoning on the catalytic behaviour of Ce_0.5Zr_0.5O₂and Ce_0.15Zr_0.85O₂in the gas-phase oxidation of chlorinatedVOCs.Applied Catalysis B：Environmental，2011.In Press，Corrected Proof.

［17］黃琴琴，周仁賢.負載型CeO₂催化劑催化降解Cl-VOCs性能的研究.全國環(huán)境催化與環(huán)境材料學術會議，2009.

［18］Gutierrez-Ortiz J I，de Rivas B，López-Fonseca R，et al.Structure of Mn-Zr mixed oxides catalysts and their catalytic performance in the gas-phase oxidation of chlorocarbons.Chemosphere，2007，68（6）：1004-1012.

［19］Abdullah A Z，Abu Bakar M Z，Bhatia S.Combustion of chlorinatedVolatile organic compounds（VOCs）using bimetallic chromium-copper supported on modified H-ZSM-5 catalyst.Journal of Hazardous Materials，2006，129（1-3）：39-49.

［20］吳西寧，龐菊玲，曹武軒等.催化氧化法分解鄰二氯苯.工業(yè)催化，2003（11）：45-48.

［21］Kawi S，Te M.MCM-48 supported chromium catalyst for trichloroethylene oxidation.Catalysis Today，1998，44（1-4）：101-109.

［22］Aranzabal A，Gonzalez-Marcos J A，Romero-S??ez M，et al.Stability of protonic zeolites in the catalytic oxidation of chlorinatedVOCs（1，2-dichloroethane）.Applied Catalysis B-Environmental，2009，88（3-4）：533-541.

［23］Bertinchamps F，Groire C，Gaigneaux E M.Systematic investigation of supported transition metal oxide based formulations for the catalytic oxidative elimination of（chloro）-aromatics：Part I：Identification of the optimal main active phases and supports.Applied Catalysis B：Environmental，2006，66（1-2）：1-9.

［24］de Rivas B，Lopez-Fonseca R，Sampedro C，et al.Catalytic behaviour of thermally aged Ce/Zr mixed oxides for the purification of chlorinatedVOC-containing gas streams.Applied Catalysis B-Environmental，2009，90（3-4）：545-555.

［25］龔浩，黎維彬.1，2-二氯乙烷在擔載鈰鈦復合氧化物的蜂窩陶瓷催化劑上的催化燃燒：催化活性組分顆粒大小對轉化率的影響，2009，威海.

［26］Saleh F S，Rahman M M.Oxidative destruction of o-DCB on supported manganese oxide catalyst.Journal of Hazardous Materials，2009，162（2-3）：1574-1577.

［27］VuV H，Belkouch J，Ould-Dris A，et al.Removal of hazardous chlorinatedVOCs over Mn-Cu mixed oxide based catalyst.Journal of Hazardous Materials，2009，169（1-3）：758-765.

［28］Yim S D，Koh D J，In-Sik Nam.A pilot plant study for catalytic decomposition of PCDDs/PCDFs over supported chromium oxide catalysts.Catalysis Today，2002，75（1-4）：269-276.

［29］Rachapudi R，Chintawar P S，Greene H L.Aging and structure activity characteristics of CR-ZSM-5 catalysts during exposure to chlorinatedVOCs.Journal of Catalysis，1999，185（1）：58-72.

［30］Jones J，Ross J R H.The development of supportedVanadia catalysts for the combined catalytic removal of the oxides of nitrogen and of chlorinated hydrocarbons from flue gases.Catalysis Today，1997，35（1-2）：97-105.

［31］沈柳倩，翁芳蕾，袁鵬軍等.鈣鈦礦型催化劑對VOCs催化燃燒的抗毒性和穩(wěn)定性研究.分子催化，2008（04）：320-324.

［32］Guillemot M，Mijoin J，Mignard S，et al.Volatile organic compounds（VOCs）removal over dual functional adsorbent/catalyst system.Applied Catalysis B：Environmental，2007，75（3-4）：249-255.

［33］López-Fonseca R，et al.Performance of zeolites and product selectivity in the gas-phase oxidation of 1，2-dichloroethane.Catalysis Today，2000，62（4）：367-377.

［34］Huang Q，Xue X，Zhou R.Decomposition of 1，2-dichloroethane over CeO₂modified USY zeolite catalysts：Effect of acidity and redox property on the catalytic behavior.Journal of Hazardous Materials，2010，183（1-3）：694-700.

［35］Krishnamoorthy S，Rivas J A，Amiridis M D.Catalytic Oxidation of 1，2-Dichlorobenzene over Supported Transition Metal Oxides.Journal of Catalysis，2000，193（2）：264-272.

［36］Khaleel A，Al-Nayli A.Supported and mixed oxide catalysts based on iron and titanium for the oxidative decomposition of chlorobenzene.Applied Catalysis B：Environmental，2008，80（1-2）：176-184.

［37］Pu Y Y，F(xiàn)ang J Z，Peng F .Microemulsion Synthesis of Nanosized SiO₂/TiO₂Particles and Their Photocatalytic Activity［J］.Chinese Journal of Catalysis，2007，28（3）：251-256.

［38］Qourzal S，Barka.N，Tamimi M，Assabbane A.Sol-gel synthesis of TiO₂-SiO₂photocatalyst for β-naphthol photodegradation［J］.Materials Science & Engineering，2008，9（15）：1-18.

［39］Jenog S，CHAN S，TAE O.Structural and chemical characterization of SiO₂/TiO₂multicomponent particles during aerosol formationin a coflow diffusion flame［J］.Advanced Powder Technol，2006，5（17）：495-508.

［40］肖奇，邱冠周，胡岳華.納米二氧化鈦的制備及應用新進展［J］.材料導報，2000，14（8）：35-37.

［41］高濂，鄭珊，張青紅.納米氧化鈦光催化材料及應用［M］.北京：化學工業(yè)出版社，2002.

［42］孫麗萍，高山，趙輝等.納米二氧化鈦的晶型轉變及光催化性能研究［J］.功能材料，2005，5（35）：632-634.

［43］符春林，魏稀文.二氧化鈦晶型轉變研究進展［J］.材料導報，1999，13（3）：45-47.

［44］王魯燕.不同結構納米TiO₂-SiO₂復合氧化制備、表征和比較研究［D］.太原理工大學.

［45］趙敬哲，王子悅，王莉瑋.超細多孔TiO₂的制備及機理研究［J］.高等學校化學學報，1999，20：115-118.

［46］Shi L，Weng D.Highly active mixed-phase TiO₂photocatalysts fabricated at low temperature and the correlation between phase composition and photocatalytic activity［J］.Journal of Environmental Sciences.2008：1263-1267.

［47］何都良，王傳海，夏明芳等.納米TiO₂的晶相控制及其光催化活性研究［J］.環(huán)境科學與技術，2004，27（6）：6-9.

［48］劉曙光，魏偉.混晶結構納米 TiO₂粉體的制備與性能表征［J］.硅酸鹽通報，2007，26（6）：1089-1093.

［49］高偉，吳鳳清，羅臻等.TiO₂晶型與光催化活性關系的研究［J］.高等學校化學學報，2001，22（4）：660-662.

［50］Jung K Y，Park S B，Masakazu.An pocphotoluminescence and photoactivity of titania particles prepared by the sol-gel technique：effect of calcination temperature［J］.Journal of Photochemistry and Photobiology A：Chemistry.2005，170：247-252.

［51］Cooper Ian L，Egerton Terry A，F(xiàn)ulian Q.A model of growth of titanium dioxide crystals with simultaneous transformation from anatase to rutile［J］.Journal of the European Ceramic Society，2009，29：637-646.

［52］Chen Y F，Lee C Y，Yeng M Y，et al.The effect of calcinations te-mperature on the crystallinity of TiO₂nanopowders［J］.Journal of Crystal Growth，2003，247：363-370.

［53］肖鋒，葉健東，王秀鵬等.干燥方法對化學沉淀法合成HA粉體團聚的影響［J］.硅酸鹽通報.2006，1：3-5.

［54］林發(fā)蓉，何代平，蔡鐸昌等.超臨界干燥法制備的銳鈦礦TiO₂納米晶的性能研究［J］.西華師范大學學報，2007，28（1）：49-52.

［55］何代平.干燥法對納米TiO₂晶相及其光催化活性的影響［J］.應用化學，2007，8：751-754.

［56］Colmenares J C，Aramendia A，Marina Synthesis.M，et al.Characterization and photo catalytic activity of different metal-doped titania systems［J］.Applied Catalysis A：General，2006，3（7）：120-127.

［57］Xu J P，Shi S.B，Li L，Wang J F，et.al.Effect of manganese ions concentration on the anatase-rutile phase transformation of TiO₂films［J］.Journal of Physics and Chemistry of Solids，2009，6：1-4.

［58］Diamandescus L，Vasiliua F，Tarabasanuu-Mihaila D，et al.Structural and photocatalytic properties of iron-and europium-doped TiO₂nanoparticles obtained under hydrothermal conditions［J］.Materials Chemistry and Physics，2008，112：146-153.

［59］Jung Y S，Kim D W，Kim Y-S，et al.Synthesis of alumina-titania solid solution by sol-gel method［J］. Journal of Physics and Chemistry of Solids，2008，69：1464-1467.

［60］井立強，孫曉君，辛柏福等.摻雜鑭和鈰的TiO₂納米粒子的結構相變［J］.材料科學與工藝，2004，2：148-152.

［61］王志義，史獻峰，崔作林.ZnO異質復合對納米TiO₂晶型轉變和晶粒生長的影響［J］.硅酸鹽通報，2006，34（9）：1078-1083.

［62］Kobayashi M，Kuam R，Masaki.TiO₂-SiO₂andV₂O₅/TiO₂-SiO₂catalyst：Physico-chemical characteristics and catalytic behavior in selective catalytic reduction of NO by NH₃［J］.Applied Catalysis B：Environ，2005，60：173-179.

［63］Periyat P，Baiju KV，Mukundan P，et al.High temperature stable mesoporous anatase TiO₂photocatalyst achieved by silica addition［J］.Applied Catalysis A：General，2008，349：13-19.

［64］Ida J，Yoshikawa T，Matsuyama T.TiO₂coating on silica particles by of deposition sol-gel-derived nanoparticles［J］. Advanced Powder Technol，2007，18（3）：329-348.

［65］姚超，高國生，林西平等.SiO₂對金紅石相納米TiO₂熱穩(wěn)定性的影響［J］.江蘇工業(yè)學院學報，2003，15（4）：1-4.

［66］陳前林，吳建青，王龍現(xiàn).SiO₂的加入方法對高溫穩(wěn)定型納米TiO₂光催化活性的影響［J］.中國陶瓷，2006，42（6）：12-14.

［67］封娜，鄭治祥，徐光青等.TiO₂/SiO₂復合粉體的制備及催化性能的研究［J］.合肥工業(yè)大學學報，2006，29（6）：651-654.

［68］李凡修，陸曉華，梅平.金屬離子摻雜對納米TiO₂晶型轉變影響作用機制的研究進展［J］.材料導報，2006，20（9）：13-16.

［69］劉暢，暴寧鐘，楊祝紅等.過渡金屬離子摻雜改性TiO₂的光催化性能研究進展［J］.催化學報，2001，22（2）：215-218.

［70］熊建裕，喬學亮，陳建國.銀摻雜對二氧化鈦晶型轉變的影響［J］.陶瓷報，2005，26（2）：84-86.

［71］SubramanianV，Zheng Ni，Seebauer E G，et al.Synthesis of High-Temperature Titania-Alumina Supports［J］. Industrial and Engingeering Chemistry Researcher，2006，45：3815-3820.

［72］趙春，鐘順和.V₂O₅-TiO₂復合半導體光催化材料結構及光響應性能研究［J］.無機化學學報，2006，22（2）：238-242.

［73］王艷芹，張莉，程虎民等.摻雜過渡金屬離子的TiO₂復合納米粒子光催化劑-羅丹明B的光催化降解［J］.高等學校化學學報，2000，21（6）：958-960.

［74］Gomathi d L，Girrish K S，Narasimh M B，et al.Influence of Mn²⁺ and Mo⁶⁺ dopants on the phase transformations of TiO₂lattice and its photo catalytic activity under solar illumination［J］.Catalysis Communications，2009，10：794-798.

［75］岳林海，水淼，徐鑄德.稀土摻雜二氧化鈦的相變和光催化活性［J］.浙江大學學報（理學版），2000，27（1）：69-74.

［76］陳代榮，孟祥建，李博等.偏鈦酸作前軀體水熱合成TiO₂微粉［J］.無機材料學報.1997，12（1）：110-114.

［77］Yu J G，Yu J C，Cheng B，et al.The effect of F-doping and temperature on the structural and textural evolution of mesoporous TiO₂powders［J］.Journal of Solid State Chemistry，2003，147：372-380.

［78］Liu J，Qina W L，Zuo S L，et al.Solvothermal-induced phase transition andVisible photocatalytic activity of nitrogen-doped titania［J］.Journal of Hazardous Materials，2009，163：273-278.

［79］Tian H，Ma J，Li K，et al.Hydrothermal synthesis of S-doped TiO₂nanoparticles and their photocatalytic ability for degradation of methyl orang［J］.Ceramics International，2009，35：1289-1292.

［80］周利民，王一平，黃群武等.Ag/S/C共摻雜納米TiO₂的制備與光催化活性［J］.半導體光電，2008，29（1）：365-369.

［81］周亮，鄧健，廖力夫等.氮鈰共摻雜納米TiO₂的制備和光催化活性研究［J］.應用化工，2008，37（8）：857-861.

［82］Ashir，Morikawa T，Ohwaki T，et al.Visible-light photocatalysis in nitrogen-doped titanium oxide［J］.Science，2001，293：269-271.

［83］陳琦麗，唐超群.過渡金屬摻雜金紅石相TiO₂能帶結構的第一性原理計算［J］.材料科學與工程學報，2006，24（4）：514-516.

［84］Rahman M M，Ahammad A J S，Jin J-H，et al.A Comprehensive Review of Glucose Biosensors Based on Nanostructured Metal-Oxides［J］.Sensors，2010，10：4855-4886.

［85］Clark L C，Lyons C.Electrode systems for continuous monitoring in cardiovascular surgery［J］.Annals of the New York Academy of Sciences，1962，102：29-45.

［86］Tsujimura S，Kojima S，Kano K，et al.Novel FAD-dependent glucose dehydrogenase for a dioxygen-insensitive glucose biosensor［J］.Bioscience，biotechnology，and biochemistry，2006，70：654-659.

［87］Toghill K E，Compton R G.Electrochemical non-enzymatic glucose sensors：a perspective and an evaluation［J］. Int J Electrochem Sci，2010，5：1246-1301.

［88］Lau K T，de Fortescu S A，Murphy L J，et al.Disposable Glucose Sensors for Flow Injection Analysis Using Substituted 1，4‐Benzoquinone Mediators［J］.Electroanalysis，2003，15：975-981.

［89］Nien P C，Wang J Y，Chen P Y，et al.Encapsulating benzoquinone and glucose oxidase with a PEDOT film：application to oxygen-independent glucose sensors and glucose/O₂biofuel cells［J］.Bioresource technology，2010，101：5480-5486.

［90］Park H J，Won K，Lee S Y，et al.Fabrication of CNT/ferrocene/glucose oxidase/chitosan-layered bioanode for glucose/oxygen biofuel cells［J］.Molecular Crystals and Liquid Crystals，2011，539：238-246.

［91］Si P，Huang Y J，Wang T H，et al.Nanomaterials for electrochemical non-enzymatic glucose biosensors［J］.Rsc Advances，2013，3：3487-3502.

［92］Zhou Y G，Yang S，Qian Q Y，et al.Gold nanoparticles integrated in a nanotube array for electrochemical detection of glucose［J］.Electrochemistry Communications，2009，11：216-219.

［93］Song Y Y，Zhang D，Gao W，et al.Nonenzymatic glucose detection by using a three‐dimensionally ordered，macroporous platinum template［J］.Chemistry-a European Journal，2005，11：2177-2182.

［94］Chen X m，Lin Z j，Chen D J，et al.Nonenzymatic amperometric sensing of glucose by using palladium nanoparticles supported on functional carbon nanotubes［J］.Biosensors and Bioelectronics，2010，25：1803-1808.

［95］Lu L M，Zhang L，Qu F L，et al.A nano-Ni based ultrasensitive nonenzymatic electrochemical sensor for glucose：enhancing sensitivity through a nanowire array strategy［J］.Biosensors and Bioelectronics，2009，25：218-223.

［96］Xu Q，Zhao Y，Xu J Z，et al.Preparation of functionalized copper nanoparticles and fabrication of a glucose sensor［J］.Sensors and Actuators B-Chemical.2006，114：379-386.

［97］Kung C W，Lin C Y，Lai Y H，et al.Cobalt oxide acicular nanorods with high sensitivity for the non-enzymatic detection of glucose［J］.Biosensors and Bioelectronics，2011，27：125-131.

［98］Ding Y，Wang Y，Su L，et al.Electrospun Co₃O₄nanofibers for sensitive and selective glucose detection［J］. Biosensors and Bioelectronics，2010，26：542-548.

［99］Li M，Han C，Zhang Y，et al.Facile synthesis of ultrafine Co₃O₄nanocrystals embedded carbon matrices with specific skeletal structures as efficient non-enzymatic glucose sensors［J］.Analytica Chimica Acta，2015，861：25-35.

［100］Khun K，Ibupoto Z H，Liu X，et al.The ethylene glycol template assisted hydrothermal synthesis of Co₃O₄nanowires； structural characterization and their application as glucose non-enzymatic sensor［J］.Materials Science and Engineering B-Advanced Functional Solid-State Materials，2015，194：94-100.

［101］Wang L，F(xiàn)u J Y，Hou H Q，et al.A Facile Strategy to Prepare Cu₂O/Cu Electrode as a Sensitive Enzyme-free Glucose Sensor［J］.International Journal of Electrochemical Science，2012，7：12587-12600.

［102］Sun S D，Zhang X Z，Sun Y X，et al.Hierarchical CuO nanoflowers：water-required synthesis and their application in a nonenzymatic glucose biosensor［J］.Physical Chemistry Chemical Physics，2013，15：10904-10913.

［103］Li C L，Su Y，Zhang S W，et al.An improved sensitivity nonenzymatic glucose biosensor based on a Cu_xO modified electrode［J］.Biosensors & Bioelectronics，2010，26：903-907.

［104］Mu Y，Jia D，He Y，et al.Nano nickel oxide modified non-enzymatic glucose sensors with enhanced sensitivity through an electrochemical process strategy at high potential［J］.Biosensors & Bioelectronics，2011，26：2948-2952.

［105］Li C，Liu Y，Li L，et al.A novel amperometric biosensor based on NiO hollow nanospheres for biosensing glucose［J］.Talanta，2008，77：455-459.

［106］Zhang W D，Chen J，Jiang L C，et al.A highly sensitive nonenzymatic glucose sensor based on NiO-modified multi-walled carbon nanotubes［J］.Microchimica Acta，2010，168：259-265.

［107］Chen J，Zhang W D，Ye J S.Nonenzymatic electrochemical glucose sensor based on MnO₂/MWNTs nanocomposite［J］.Electrochemistry Communications，2008，10：1268-1271.

［108］Li L，Du Z，Liu S，et al.A novel nonenzymatic hydrogen peroxide sensor based on MnO₂/graphene oxide nanocomposite［J］.Talanta，2010，82：1637-1641.

［109］Tarlani A，F(xiàn)allah M，Lotfi B，et al.New ZnO nanostructures as non-enzymatic glucose biosensors［J］. Biosensors & Bioelectronics，2015，67：601-607.

［110］EI Khatib K M，Abdel Hameed R M.Development of Cu₂O/CarbonVulcan XC-72 as non-enzymatic sensor for glucose determination［J］.Biosensors and Bioelectronics，2011，26：3542-3548.

［111］Bai Y，Sun Y，Sun C.Pt-Pb nanowire array electrode for enzyme-free glucose detection［J］.Biosensors & Bioelectronics，2008，24：579-585.

［112］Guo M Q，Wang R，Xu X H.Electrosynthesis of pinecone-shaped Pt-Pb nanostructures based on the application in glucose detection［J］.Materials Science & Engineering C-Materials for Biological Applications，2011，31：1700-1705.

［113］Guo M，F(xiàn)ang H，Wang R，et al.Electrodeposition of chitosan-glucose oxidase biocomposite onto Pt-Pb nanoparticles modified stainless steel needle electrode for amperometric glucose biosensor［J］.Journal of Materials Science-Materials in Medicine，2011，22：1985-1992.

［114］Cui H F，Ye J S，Liu X，et al.Pt-Pb alloy nanoparticle/carbon nanotube nanocomposite：a strong electrocatalyst for glucose oxidation［J］.Nanotechnology，2006，17：2334-2339.

［115］Hu Y J，Du W J，Chen C Y.Fabrication of Flower-shaped Pt-Au-graphene Nanostructure and its Application in Electrochemical Detection of Glucose［J］.Chinese Journal of Analytical Chemistry，2014，42：1240-1244.

［116］Zhu X，Li C，Zhu X，et al.Nonenzymatic Glucose Sensor Based on Pt-Au-SWCNTs Nanocomposites［J］. International Journal of Electrochemical Science，2012，7：8522-8532.

［117］Liu Y，Ding Y，Zhang Y，et al.Pt-Au nanocorals，Pt nanofibers and Au microparticles prepared by electrospinning and calcination for nonenzymatic glucose sensing in neutral and alkaline environment［J］.Sensors and Actuators B-Chemical.2012，171：954-961.

［118］Li Y，Niu X，Tang J，et al.A Comparative Study of Nonenzymatic Electrochemical Glucose Sensors Based on Pt-Pd Nanotube and Nanowire Arrays［J］.Electrochimica Acta，2014，130：1-8.

［119］Niu X，Lan M，Chen C，et al.Nonenzymatic electrochemical glucose sensor based on novel Pt-Pd nanoflakes［J］. Talanta，2012，99：1062-1067.

［120］Niu X，Chen C，Zhao H，et al.Novel snowflake-like Pt-Pd bimetallic clusters on screen-printed gold nanofilm electrode for H₂O₂and glucose sensing［J］.Biosensors & Bioelectronics，2012，36：262-266.

［121］Hu Y，He F，Ben A，et al.Synthesis of hollow Pt-Ni-graphene nanostructures for nonenzymatic glucose detection［J］.Journal of Electroanalytical Chemistry，2014，726：55-61.

［122］Mahshid S S，Mahshid S，Dolati A，et al.Electrodeposition and electrocatalytic properties of Pt/Ni-Co nanowires for non-enzymatic glucose detection［J］.Journal of Alloys and Compounds，2013，554：169-176.

［123］Mahshid S S，Luo S，Yang L，et al.A Well-Dispersed Pt/Ni/TiO₂Nanotubes Modified Electrode as an Amperometric Non-Enzymatic Glucose Biosensor［J］.Sensor Letters，2011，9：1598-1605.

［124］Yu H，He Y.Seed-assisted synthesis of dendritic Au-Ag bimetallic nanoparticles with chemiluminescence activity and their application in glucose detection［J］.Sensors and Actuators B-Chemical，2015，209：877-882.

［125］Shi Q，Diao G，Mu S.The electrocatalytic oxidation of glucose on the bimetallic Au-Ag particles-modified reduced graphene oxide electrodes in alkaline solutions［J］.Electrochemica Acta，2014，133：335-346.

［126］Lin K-C，Lin Y-C，Chen S-M.A highly sensitive nonenzymatic glucose sensor based on multi-walled carbon nanotubes decorated with nickel and copper nanoparticles［J］.Electrochemica Acta，2013，96：164-172.

［127］Li X，Yao J，Liu F，et al.Nickel/Copper nanoparticles modified TiO₂nanotubes for non-enzymatic glucose biosensors［J］.Sensors and Actuators B-Chemical，2013，181：501-508.

［128］Ding R，Liu J，Jiang J，et al.Mixed Ni-Cu-oxide nanowire array on conductive substrate and its application as enzyme-free glucose sensor［J］.Analytical Methods，2012，4：4003-4008.

［129］Song J，Xu L，Xing R，et al.Ag nanoparticles coated NiO nanowires hierarchical nanocomposites electrode for nonenzymatic glucose biosensing［J］.Sensors and Actuators B-Chemical，2013，182：675-681.

［130］Ding Y，Wang Y，Su L，et al.Preparation and characterization of NiO-Ag nanofibers，NiO nanofibers，and porous Ag：towards the development of a highly sensitive and selective non-enzymatic glucose sensor［J］.Journal of Materials Chemistry，2010，20：9918-9926.

［131］Wang L，Lu X，Wen C，et al.One-step synthesis of Pt-NiO nanoplate array/reduced graphene oxide nanocomposites for nonenzymatic glucose sensing［J］.Journal of Materials Chemistry A，2015，3：608-616.

［132］Li M，Bo X，Mu Z，et al.Electrodeposition of nickel oxide and platinum nanoparticles on electrochemically reduced graphene oxide film as a nonenzymatic glucose sensor［J］.Sensors and Actuators B-Chemical，2014，192：261-268.

［133］Ding Y，Liu Y，Zhang L，et al.Sensitive and selective nonenzymatic glucose detection using functional NiO-Pt hybrid nanofibers［J］.Electrochimica Acta，2011，58：209-214.

［134］Zhang X，Gu A，Wang G，et al.Porous Cu-NiO modified glass carbon electrode enhanced nonenzymatic glucose electrochemical sensors［J］.Analyst，2011，136：5175-5180.

［135］Li C，Kurniawan M，Sun D，et al.Nanoporous CuO layer modified Cu electrode for high performance enzymatic and non-enzymatic glucose sensing［J］.Nanotechnology，2015，26.

［136］Dong J，Ren L，Zhang Y，et al.Direct electrodeposition of cable-like CuO@Cu nanowires array for non-enzymatic sensing［J］.Talanta，2015，132：719-726.

［137］Zhang J，Xiao X，He Q，et al.A Nonenzymatic Glucose Sensor Based on a Copper Nanoparticle-Zinc Oxide Nanorod Array［J］.Analytical Letters，2014，47：1147-1161.

［138］SoYoon S，Ramadoss A，Saravanakumar B，et al.Novel Cu/CuO/ZnO hybrid hierarchical nanostructures for non-enzymatic glucose sensor application［J］.Journal of Electroanalytical Chemistry，2014，717：90-95.

［139］Cai B，Zhou Y，Zhao M，et al.Synthesis of ZnO-CuO porous core-shell spheres and their application for non-enzymatic glucose sensor［J］.Applied Physics a-Materials Science & Processing，2015，118：989-996.

［140］Zhou C，Xu L，Song J，et al.Ultrasensitive non-enzymatic glucose sensor based on three-dimensional network of ZnO-CuO hierarchical nanocomposites by electrospinning［J］.Scientific Reports，2014，4.

［141］Ding Y，Wang Y，Zhang L，et al.Preparation，characterization and application of novel conductive NiO-CdO nanofibers with dislocation feature［J］.Journal of Materials Chemistry，2012，22：980-986.

［142］Zhang X J，Wang G F，Zhang W，et al.Fixure-reduce method for the synthesis of Cu₂O/MWCNTs nanocomposites and its application as enzyme-free glucose sensor［J］.Biosensors & Bioelectronics，2009，24：3395-3398.

［143］Zor E，Oztekin Y，Ramanaviciene A，et al.Amperometric Glucose Biosensor Based on Glucose Oxidase，1，10-Phenanthroline-5，6-dione and Carbon Nanotubes［J］.Journal of the Electrochemical Society，2014，161：H3064-H3069.

［144］Li M，Liu L，Xiong Y，et al.Bimetallic MCo（M=Cu，F(xiàn)e，Ni，and Mn）nanoparticles doped-carbon nanofibers synthetized by electrospinning for nonenzymatic glucose detection［J］.Sensors and Actuators B-Chemical，2015，207：614-622.

［145］Adabi M，Saber R，F(xiàn)aridi-Majidi R，et al.Performance of electrodes synthesized with polyacrylonitrile-based carbon nanofibers for application in electrochemical sensors and biosensors［J］.Materials Science & Engineering C-Materials for Biological Applications，2015，48：673-678.

［146］Nia P M，Meng W P，Lorestani F，et al.Electrodeposition of copper oxide/polypyrrole/reduced graphene oxide as a nonenzymatic glucose biosensor［J］.Sensors and Actuators B-Chemical，2015，209：100-108.

［147］Wang Y，Wei W，Zeng J，et al.Fabrication of a copper nanoparticle/chitosan/carbon nanotube-modified glassy carbon electrode for electrochemical sensing of hydrogen peroxide and glucose［J］.Microchimica Acta，2008，160：253-260.

［148］Kang X H，Mai Z B，Zou X Y，et al.A sensitive nonenzymatic glucose sensor in alkaline media with a copper nanocluster/multiwall carbon nano tube-modified glassy carbon electrode［J］.Analytical Biochemistry，2007，363：143-150.

［149］Niu X，Li Y，Tang J，et al.Electrochemical sensing interfaces with tunable porosity for nonenzymatic glucose detection：A Cu foam case［J］.Biosensors & Bioelectronics，2014，51：22-28.

［150］Welch C M，Compton R G.The use of nanoparticles in electroanalysis：a review［J］.Analytical and bioanalytical chemistry，2006，384：601-619.

［151］Akhavan O，Ghaderi E.Copper oxide nanoflakes as highly sensitive and fast response self-sterilizing biosensors［J］. J Mater Chem，2011，21：12935-12940.

［152］Li K，F(xiàn)an G，Yang L，et al.Novel ultrasensitive non-enzymatic glucose sensors based on controlled flower-like CuO hierarchical films［J］.Sensors and Actuators B：Chemical，2014，199：175-182.

［153］Song J，Xu L，Zhou C，et al.Synthesis of Graphene Oxide Based CuO Nanoparticles Composite Electrode for Highly Enhanced Nonenzymatic Glucose Detection［J］.Acs Applied Materials & Interfaces，2013，5：12928-12934.

［154］Liu M，Liu R，Chen W.Graphene wrapped Cu₂O nanocubes：Non-enzymatic electrochemical sensors for the detection of glucose and hydrogen peroxide with enhanced stability［J］.Biosensors and Bioelectronics，2013，45：206-212.

［155］Hassan H B，Hamid Z A.Electrodeposited Cu-CuO Composite Films for Electrochemical Detection of Glucose［J］. International Journal of Electrochemical Science，2011，6：5741-5758.

［156］Zhang X，Wang G，Zhang W，et al.Seed-mediated growth method for epitaxial array of CuO nanowires on surface of Cu nanostructures and its application as a glucose sensor［J］.Journal of Physical Chemistry C，2008，112：8856-8862.

［157］Huo H，Guo C，Li G，et al.Reticular-vein-like Cu@Cu₂O/reduced graphene oxide nanocomposites for a non-enzymatic glucose sensor［J］.Rsc Advances，2014，4：20459-20465.

［158］Wang A J，F(xiàn)eng J J，Li Z H，et al.Solvothermal synthesis of Cu/Cu₂O hollow microspheres for non-enzymatic amperometric glucose sensing［J］.Crystengcomm，2012，14：1289-1295.

［159］Chou C S，Yang R Y，Yeh C K，et al.Preparation of TiO₂/Nano-metal composite particles and their applications in dye-sensitized solar cells［J］.Powder Technology，2009，194：95-105.

［160］Nagaoka S，Arinaga K，Kubo H，et al.Cellulose/TiO₂hybrid spherical microbeads prepared by aViscose phase separation method：Control of the distribution of TiO₂particles in a sphering system［J］.Polymer Journal，2005，37：186-191.

［161］Liu Y，Cheng K，Weng W，et al.Influence of rod-surface structure on biological interactions between TiO₂nanorod films and proteins/cells［J］.Thin Solid Films，2013，544：285-290.

［162］Su Y-F，Lee M-C，Wang G-B，et al.An innovative method to quickly and simply prepare TiO₂nanorod arrays and improve their performance in photo water splitting［J］.Chemical Engineering Journal，2014，253：274-280.

［163］Yoriya S，Mor G K，Sharma S，et al.Synthesis of ordered arrays of discrete，partially crystalline titania nanotubes by Ti anodization using diethylene glycol electrolytes［J］.J Mater Chem，2008，18：3332-3336.

［164］Lee J H，Leu I C，Hsu M C，et al.Fabrication of aligned TiO₂nanostructured arrays using a one-step templating solution approach［J］.Journal of Physical Chemistry B，2005，109：13056-13059.

［165］Nakahira A，Kubo T，Numako C.Formation mechanism of TiO₂-derived titanate nanotubes prepared by the hydrothermal process［J］.Inorganic chemistry，2010，49：5845-5852.

［166］Nakahira A，Kubo T，Numako C.TiO₂-derived titanate nanotubes by hydrothermal process with acid treatments and their microstructural evaluation［J］.Acs Applied Materials & Interfaces，2010，2：2611-2616.

［167］Bavykin DV，F(xiàn)riedrich J M，Walsh F C.Protonated Titanates and TiO₂Nanostructured Materials：Synthesis，Properties，and Applications［J］.Advanced Materials，2006，18：2807-2824.

［168］Kobayashi S，Hamasaki N，Suzuki M，et al.Preparation of helical transition-metal oxide tubes using organogelators as structure-directing agents［J］.Journal of the American Chemical Society，2002，124：6550-6551.

［169］Lee C H，Rhee S W，Choi H W.Preparation of TiO₂nanotube/nanoparticle composite particles and their applications in dye-sensitized solar cells［J］.Nanoscale Research Letters，2012，7：1-5.

［170］ZwillingV，Darque-Ceretti E，Boutry-Forveille A，et al.Structure and physicochemistry of anodic oxide films on titanium and TA6V alloy［J］.Surface and Interface Analysis，1999，27：629-637.

［171］Gong D，Grimes C A，Varghese O K，et al.Titanium oxide nanotube arrays prepared by anodic oxidation［J］. Journal of Materials Research，2001，16：3331-3334.

［172］Huang J Y，Zhang K Q，Lai Y K.Fabrication，Modification，and Emerging Applications of TiO₂Nanotube Arrays by Electrochemical Synthesis：A Review［J］.International Journal of Photoenergy，2013.

［173］Mor G K，Varghese O K，Paulose M，et al.Fabrication of tapered，conical-shaped titania nanotubes［J］.Journal of Materials Research，2003，18：2588-2593.

［174］Cai Q，Paulose M，Varghese O K，et al.The Effect of Electrolyte Composition on the Fabrication of Self-Organized Titanium Oxide Nanotube Arrays by Anodic Oxidation［J］.Journal of Materials Research，2005，20：230-236.

［175］Paulose M，Shankar K，Yoriya S，et al.Anodic growth of highly ordered TiO₂nanotube arrays to 134μm in length［J］.The Journal of Physical Chemistry B，2006，110：16179-16184.

［176］Ruan C M，Paulose M，Varghese O K，et al.Fabrication of highly ordered TiO₂nanotube arrays using an organic electrolyte［J］.Journal of Physical Chemistry B，2005，109：15754-15759.

［177］Prakasam H E，Shankar K，Paulose M，et al.A new benchmark for TiO₂nanotube array growth by anodization［J］.The Journal of Physical Chemistry C，2007，111：7235-7241.

［178］Nakayama K，Kubo T，Tsubokura A，et al.Anodic formation of high-aspect-ratio titania nanotubes.　Meeting Abstracts：The Electrochemical Society，2006：819-819.

［179］Richter C，Wu Z，Panaitescu E，et al.Ultra‐High‐Aspect‐Ratio Titania Nanotubes［J］.Advanced Materials，2007，19：946-948.

［180］Chen X，Schriver M，Suen T，et al.Fabrication of 10nm diameter TiO₂nanotube arrays by titanium anodization［J］.Thin Solid Films，2007，515：8511-8514.

［181］Roy P，Berger S，Schmuki P.TiO₂nanotubes：synthesis and applications［J］.Angewandte Chemie International Edition，2011，50：2904-2939.

［182］Mohapatra S K，Kondamudi N，Banerjee S，et al.Functionalization of self-organized TiO₂nanotubes with Pd nanoparticles for photocatalytic decomposition of dyes under solar light illumination［J］.Langmuir，2008，24：11276-11281.

［183］Park J H，Kim S，Bard A J.Novel carbon-doped TiO₂nanotube arrays with high aspect ratios for efficient solar water splitting［J］.Nano letters，2006，6：24-28.

［184］Zhu K，Neale N R，Miedaner A，et al.Enhanced Charge-Collection Efficiencies and Light Scattering in Dye-Sensitized Solar Cells Using Oriented TiO₂Nanotubes Arrays［J］.Nano letters，2007，7：69-74.

［185］Sun L，Zhang S，Wang X，et al.A novel parallel configuration of dye-sensitized solar cells with double-sided anodic nanotube arrays［J］.Energy & Environmental Science，2011，4：2240-2248.

［186］Baker D R，Kamat PV.Photosensitization of TiO₂nanostructures with CdS quantum dots：particulateVersus tubular support architectures［J］.Advanced Functional Materials，2009，19：805-811.

［187］Elias C N，Lima J H C，Valiev R，et al.Biomedical applications of titanium and its alloys［J］.JOM，2008，60：46-49.

［188］Huo K F，Gao B，F(xiàn)u J J，et al.Fabrication，modification，and biomedical applications of anodized TiO₂nanotube arrays［J］.Rsc Advances，2014，4：17300-17324.

［189］Popat K C，Eltgroth M，LaTempa T J，et al.Decreased Staphylococcus epidermis adhesion and increased osteoblast functionality on antibiotic-loaded titania nanotubes［J］.Biomaterials，2007，28：4880-4888.

［190］Popat K C，Eltgroth M，LaTempa T J，et al.Titania Nanotubes：A Novel Platform for Drug‐Eluting Coatings for Medical Implants？［J］.Small，2007，3：1878-1881.

［191］Peng L，Eltgroth M L，LaTempa T J，et al.The effect of TiO₂nanotubes on endothelial function and smooth muscle proliferation［J］.Biomaterials，2009，30：1268-1272.

［192］Gao Z D，Han Y Y，Li Y C，et al.Photocatalytic synthesis and synergistic effect of Prussian blue-decorated Au nanoparticles/TiO₂nanotube arrays for H₂O₂amperometric sensing［J］.Electrochimica Acta，2014，125：530-535.

［193］Liu J，Ruan L，Xu G，et al.Galvanostatic deposition of Pt nanoparticles on TiO₂nanotube arrays for amperometric detection of hydrogen peroxide at low overpotentials.In：Zhao GM，Chen L，Tang Y，Long B，Nie Z，He L，et al.，editors.Eighth China National Conference on Functional Materials and Applications，2014.174-182.

［194］Luo S L，Su F，Liu C B，et al.A new method for fabricating a CuO/TiO₂nanotube arrays electrode and its application as a sensitive nonenzymatic glucose sensor［J］.Talanta，2011，86：157-163.

［195］Wang W，Xie Y，Wang Y，et al.Glucose biosensor based on glucose oxidase immobilized on unhybridized titanium dioxide nanotube arrays［J］.Microchimica Acta，2014，181：381-387.

［196］Mor G K，Carvalho M A，Varghese O K，et al.A room-temperature TiO₂-nanotube hydrogen sensor able to self-clean photoactively from environmental contamination［J］.Journal of Materials Research，2004，19：628-634.

［197］Huang L，Zhang S，Peng F，et al.Electrodeposition preparation of octahedral-Cu₂O-loaded TiO₂nanotube arrays forVisible light-driven photocatalysis［J］.Scripta Materialia，2010，63：159-161.

［198］Zhang S，Peng B，Yang S，et al.The influence of the electrodeposition potential on the morphology of Cu₂O/TiO₂nanotube arrays and theirVisible-light-driven photocatalytic activity for hydrogen evolution［J］.International Journal of Hydrogen Energy，2013，38：13866-13871.

［199］Jin Z，F(xiàn)ei G T，Hu X Y，et al.Synthesis and photocatalytic activity of Cu₂O/TiO₂double wall nanotube arrays［J］.Journal of Nanoengineering and Nanomanufacturing，2012，2：49-53.

［200］Zhang J，Wang Y，Yu C，et al.EnhancedVisible-light photoelectrochemical behaviour of heterojunction composite with Cu₂O nanoparticles-decorated TiO₂nanotube arrays［J］.New Journal of Chemistry，2014，38：4975-4984.

［201］Zhao L，Dong W，Zheng F G，et al.Interrupted growth and photoelectrochemistry of Cu₂O and Cu particles on TiO₂［J］.Electrochimica Acta，2012，80：354-361.

［202］Liu Y B，Zhou H B，Li J H，et al.Enhanced Photoelectrochemical Properties of Cu₂O-loaded Short TiO₂Nanotube Array Electrode Prepared by Sonoelectrochemical Deposition［J］.Nano-Micro Letters，2010，2：277-284.

［203］Luo S L，Li Y，Yang L X，et al.Low-temperature，facile fabrication of ultrafine Cu₂O networks by anodization on TiO₂nanotube arrays［J］.Semiconductor Science and Technology，2012，27.

［204］Hou Y，Li X Y，Zhao Q D，et al.Fabrication of Cu₂O/TiO₂nanotube heterojunction arrays and investigation of its photoelectrochemical behavior［J］.Applied Physics Letters，2009，95.

［205］范冬波.化學浴沉積制備金屬硫族化合物光電功能薄膜［碩士論文］：北京：北京工業(yè)大學，2004.

［206］Yang M，Xu J，Wei J，et al.Fabrication of double-walled carbon nanotube film/Cu₂O nanoparticle film/TiO₂nanotube array heterojunctions for photosensors［J］.Applied Physics Letters，2012，100.

［207］Wang M，Sun L，Lin Z，et al.p-n Heterojunction photoelectrodes composed of Cu₂O-loaded TiO₂nanotube arrays with enhanced photoelectrochemical and photoelectrocatalytic activities［J］.Energy & Environmental Science，2013，6：1211-1220.