{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"以电解钛丝为前驱物,用过氧化氢溶解-改性水热晶化法制备了锐钛型氟掺杂二氧化钛溶胶.应用XRD、TEM、PSD、UV-vis-DRS,FTIR、XPS技术对溶胶粒子的大小、形貌、晶型、氟的存在形式进行了表征;研究了氟的掺杂量及溶液的pH值对溶胶光催化降解4-氯苯酚性能的影响.结果表明,130℃水热反应15h后生成的TiO2溶胶为纯锐钛型结构,平均粒径为11.0nm;氟分别以吸附态、结合态的形式存在于TiO2粒子的表面和晶格中;氟掺杂后溶胶粒子对4-氯苯酚的吸附能力增大并有利于4-氯苯酚深度矿化.","authors":[{"authorName":"黄冬根","id":"0559b2cf-4475-4b96-b18b-b895f6bc5896","originalAuthorName":"黄冬根"},{"authorName":"廖世军","id":"17e0df33-832b-458e-a062-552720f00e34","originalAuthorName":"廖世军"},{"authorName":"周文斌","id":"84859304-0e81-499a-90a4-837870635b12","originalAuthorName":"周文斌"},{"authorName":"全水清","id":"b0bd9061-dd42-42e7-b463-e53abe8baab1","originalAuthorName":"全水清"},{"authorName":"刘雷","id":"ff7c826d-0c8d-4bd3-8eb1-b7fdc0ba23b9","originalAuthorName":"刘雷"}],"doi":"","fpage":"1166","id":"6b487091-ffe7-4f00-b9d3-74e834bbeec2","issue":"7","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"a0627d53-8b73-4ee9-8254-68a66b523853","keyword":"二氧化钛溶胶","originalKeyword":"二氧化钛溶胶"},{"id":"77fc470a-4a63-415a-b9ba-dfa8ba2be5bf","keyword":"光催化剂","originalKeyword":"光催化剂"},{"id":"8359c350-5ed0-4420-be66-3d431190e6af","keyword":"氟掺杂","originalKeyword":"氟掺杂"},{"id":"ec18e799-5969-494e-9922-c57d47faae54","keyword":"降解","originalKeyword":"降解"},{"id":"3fa4f432-d9b5-4af0-b540-a779ede7b0bd","keyword":"4-氯苯酚","originalKeyword":"4-氯苯酚"}],"language":"zh","publisherId":"gncl200807032","title":"锐钛矿型F-TiO2溶胶制备及光催化降解4-氯苯酚的性能","volume":"39","year":"2008"},{"abstractinfo":"为进一步提高固体润滑涂层的耐热性和耐磨性,以改性环氧树脂为主要成分,聚酰胺为固化剂,制备了含MoS2石墨和Sb2O3的粘结固体润滑涂层.参照相关标准测试了涂层的外观、附着力、硬度及摩擦学性能;研究了石墨、MoS2质量比及Sb2O3用量对涂层耐热性、耐磨性的影响.结果表明:50 g改性环氧树脂,15 g聚酰胺,石墨与MoS2质量分数为3∶2,总质量为30 g时,石墨与MoS2的协同效应最好,涂层具有较好的耐热性及耐磨性,经高温灼烧几乎无变化,磨损失重、摩擦系数最小,分别为263 mg和0.28;增强剂Sb2O3的加入使涂层硬度提高,耐磨性增加,对其耐热性影响不明显,用量为3 g时涂层摩擦学性能最佳,摩擦系数降至0.26.","authors":[{"authorName":"吴彦芬","id":"e9540bed-3bca-4870-aa29-e0a7a8488dc2","originalAuthorName":"吴彦芬"},{"authorName":"邱祖民","id":"dae527fa-dfb7-4a61-ab2a-bc1baa42b1e4","originalAuthorName":"邱祖民"},{"authorName":"全水清","id":"97146938-cb97-4d95-b977-6df4c0e12400","originalAuthorName":"全水清"},{"authorName":"肖建军","id":"d9e86f62-4282-4e60-b6c3-0f5415faeac8","originalAuthorName":"肖建军"}],"doi":"","fpage":"51","id":"19bfb896-f4af-4ca8-b57b-af42cfd16729","issue":"9","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"6dd76cfe-e104-407e-8a88-f22ce4707505","keyword":"固体润滑涂层","originalKeyword":"固体润滑涂层"},{"id":"8783bb71-2c2d-4179-a235-a6511874517b","keyword":"石墨","originalKeyword":"石墨"},{"id":"d37fa84a-d342-4dfe-8ca1-3a8e4446b47d","keyword":"MoS2","originalKeyword":"MoS2"},{"id":"3bc6ce3f-170d-483c-8bc8-a4022988f29e","keyword":"Sb2O3","originalKeyword":"Sb2O3"},{"id":"619dbf72-605a-462a-badb-a732e79d6d0c","keyword":"环氧树脂","originalKeyword":"环氧树脂"},{"id":"3d35dc70-9e0e-4701-acc8-366ccadb3cb1","keyword":"耐热性能","originalKeyword":"耐热性能"},{"id":"a57b4f63-3aa2-41dc-86db-4831270a5794","keyword":"摩擦学性能","originalKeyword":"摩擦学性能"}],"language":"zh","publisherId":"clbh201309016","title":"石墨-二硫化钼-三氧化二锑改性环氧树脂复合涂层的制备与性能","volume":"46","year":"2013"},{"abstractinfo":"从化学镀理论出发,建立了Pd-Ag共沉积行为的数学模型,通过验证表明该模型参数计算值与实验值的误差较小,对化学镀共沉积钯银有一定的指导意义.分别考察了在一定的镀液金属总浓度([M]o)、还原剂肼的浓度([N2H4])和pH的条件下,模型参数温度(t)、镀液中Pd/1Ag摩尔比(α)和ED-TA浓度(ρ)对金属沉积速度、镀层银含量和两金属还原电位差的影响.实验结果表明,当[M]0、t、ρ和α分别为5×10-3 mol/L、40℃、40g/L和4:1时,采用化学镀共沉积法可制得陶瓷负载型76.9% Pd-23.1% Ag无机复合膜,且镀层厚度为8.5 μm.在350℃和0.3 MPa下,氢气和氮气通过膜的渗透通量分别为7.9×10-3 m3/(m2·s)和2.1×10-6 m3/(m2·s).","authors":[{"authorName":"蒋柏泉","id":"e917ec09-b425-41f4-9d64-3220336d343e","originalAuthorName":"蒋柏泉"},{"authorName":"肖正强","id":"75d21c64-a5e8-4933-8523-9ab765bea4ab","originalAuthorName":"肖正强"},{"authorName":"顾(马来)","id":"dc434ea9-8cd0-4fe5-9a1e-7a86a353ec36","originalAuthorName":"顾(马来)"},{"authorName":"全水清","id":"2fc48980-9f4f-4e8a-b4c4-4111e861553b","originalAuthorName":"全水清"},{"authorName":"王敏炜","id":"ef97b087-9ec9-4470-9825-ab54bc095a1c","originalAuthorName":"王敏炜"}],"doi":"10.3969/j.issn.1004-227X.2006.05.002","fpage":"4","id":"51044c5a-d6c5-42e9-b2bb-35584d980cab","issue":"5","journal":{"abbrevTitle":"DDYTS","coverImgSrc":"journal/img/cover/DDYTS.jpg","id":"21","issnPpub":"1004-227X","publisherId":"DDYTS","title":"电镀与涂饰 "},"keywords":[{"id":"f253a069-59d4-46e5-892e-1a6b6864ef33","keyword":"化学镀","originalKeyword":"化学镀"},{"id":"ac134117-f444-40cf-97c9-814198502bb1","keyword":"共沉积","originalKeyword":"共沉积"},{"id":"868feabf-a715-48da-a3ad-24d3bbfb3183","keyword":"Pd-Ag","originalKeyword":"Pd-Ag"},{"id":"423ed91e-a42a-48dd-88e8-f5fa3b4c67e5","keyword":"数学模型","originalKeyword":"数学模型"},{"id":"a98a6a7c-aaf9-4b9b-8c19-0b6cbe41d483","keyword":"陶瓷","originalKeyword":"陶瓷"}],"language":"zh","publisherId":"ddyts200605002","title":"化学镀Pd-Ag合金的研究","volume":"25","year":"2006"},{"abstractinfo":"为探索超声辅助下利用紫外光及耦合热还原工艺制备RGO/纳米TiO2复合材料的方法,并对其在缺氧水体中的光催化还原特性进行研究,首先,以鳞片石墨为原料,采用改进的Hummers法制备了氧化石墨烯(GO),进而通过超声/紫外光还原工艺制备了还原氧化石墨烯(RGO);然后,以钛酸丁脂和RGO为前驱物,采用溶胶-凝胶法并在氮气保护下高温加热制备了RGO/纳米TiO2复合光催化材料;接着,利用FTIR、XRD、BET及紫外-可见光谱等对RGO/纳米TiO2复合材料进行了结构性能表征;最后,以2,4-二氯苯氧乙酸(2,4-D)为探针物,研究了RGO/纳米TiO2在缺氧水体中的光催化特性与2,4D降解机制.结果表明:采用低温氧化Hummers法制备的GO六碳环上生成的活性基团较少,采用超声/紫外光还原工艺及耦合高温热还原工艺可使环状结构得到良好的修复;所制备的RGO/纳米TiO2复合材料具有良好的2,4D降解能力,在缺氧状态下,2,4-D主要发生光催化还原反应,脱除苯环上的氯,产生氯酚、邻苯三酚及间苯三酚等中间产物,部分2,4-D被氧化降解生成CO2和H2O.制备的RGO/纳米TiO2复合材料具有良好的光催化还原性能.","authors":[{"authorName":"黄冬根","id":"333d8d4e-eeeb-441d-8ce1-19ba69c92a66","originalAuthorName":"黄冬根"},{"authorName":"莫壮洪","id":"ae047d9a-b7c9-4e86-9316-05855c3a451b","originalAuthorName":"莫壮洪"},{"authorName":"全水清","id":"a71653c6-0a80-46f0-b99f-8b6045a7d276","originalAuthorName":"全水清"},{"authorName":"杨天资","id":"893d6cb6-e118-44d2-b413-e6fe0be62f54","originalAuthorName":"杨天资"},{"authorName":"刘章斌","id":"eb71691f-84cc-47a6-9a0b-2982a5852f02","originalAuthorName":"刘章斌"},{"authorName":"刘苗","id":"49e79528-6c8e-4969-b4b8-af51329d7c5c","originalAuthorName":"刘苗"}],"doi":"10.13801/j.cnki.fhclxb.20150428.003","fpage":"155","id":"05939970-afab-4ffc-b22c-98c1f0362848","issue":"1","journal":{"abbrevTitle":"FHCLXB","coverImgSrc":"journal/img/cover/FHCLXB.jpg","id":"26","issnPpub":"1000-3851","publisherId":"FHCLXB","title":"复合材料学报"},"keywords":[{"id":"d95aba38-c598-4792-bd11-b6cea8cbb7ed","keyword":"石墨烯","originalKeyword":"石墨烯"},{"id":"2a4d6e5b-707a-4e09-8b9e-8b9747ea7278","keyword":"超声/紫外光还原","originalKeyword":"超声/紫外光还原"},{"id":"17e9ab9a-0808-4cb0-b48f-e1eb12c8f133","keyword":"TiO2","originalKeyword":"TiO2"},{"id":"50510eea-7b5a-4b52-9df4-575a0edb7055","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"6fc1cea5-f03b-48e7-a18f-e0c91aca1aae","keyword":"光催化还原","originalKeyword":"光催化还原"}],"language":"zh","publisherId":"fhclxb201601019","title":"石墨烯/纳米TiO2复合材料的制备及光催化还原性能","volume":"33","year":"2016"},{"abstractinfo":"探讨减压抽滤、离心、絮凝等预处理方法对一清复方水提液的溶液环境以及微滤过程中膜通量、过滤阻力分布影响.研究发现,不同预处理方式都能改善膜过滤工艺,离心(5 000 /min)在改善料液环境和膜通量方面优于其他预处理方式.","authors":[{"authorName":"乐康","id":"6e8e1204-f0c3-4d41-977d-4748ec5fef85","originalAuthorName":"乐康"},{"authorName":"付廷明","id":"edc7e055-6ec6-4516-ab20-30756ef0556d","originalAuthorName":"付廷明"},{"authorName":"潘永兰","id":"90f15894-098d-4d2e-a9c3-c36339e9b30a","originalAuthorName":"潘永兰"},{"authorName":"郭立玮","id":"7ffe9b61-a25c-4149-a8d4-12e45332d0f7","originalAuthorName":"郭立玮"}],"doi":"10.3969/j.issn.1007-8924.2010.04.011","fpage":"53","id":"887058f4-e5e0-4a70-9a7a-7b441bc4e8ec","issue":"4","journal":{"abbrevTitle":"MKXYJS","coverImgSrc":"journal/img/cover/MKXYJS.jpg","id":"54","issnPpub":"1007-8924","publisherId":"MKXYJS","title":"膜科学与技术 "},"keywords":[{"id":"6ff36581-300f-477a-bb17-a1d70c4f1a35","keyword":"预处理","originalKeyword":"预处理"},{"id":"a886187e-4439-4647-ab9b-2553514a1bec","keyword":"料液环境","originalKeyword":"料液环境"},{"id":"4205b1a3-291d-4fc7-89d2-83cd10b3763b","keyword":"膜通量","originalKeyword":"膜通量"},{"id":"4f8edaa2-40b7-4d00-bcb1-64001e8ccaf9","keyword":"阻力分布","originalKeyword":"阻力分布"}],"language":"zh","publisherId":"mkxyjs201004011","title":"预处理对一清复方水提液陶瓷膜微滤工艺的影响","volume":"30","year":"2010"},{"abstractinfo":"为了考察水飞蓟全草不同部位的组成特征,采用不同的提取溶剂对水飞蓟的幼草、根、茎、叶、花、种子等不同部位提取后,通过高效液相色谱法(HPLC)进行分析.以Hypersil ODS2色谱柱(250 mm×4.6 mm, 5 μm)为分离柱,以50 mmoL/L磷酸二氢钾溶液和甲醇为流动相,梯度洗脱,检测波长为254 nm.在此条件下,水飞蓟不同部位的样品得到了很好的分离,发现不同部位组成差别很大,得到的组分数从幼草、种子、花、叶、根、茎依次减少.水飞蓟不同部位所含的组分极性有很大差别,不同提取方法得到的样品组成也有较大差别.实验结果可为水飞蓟全草的指纹图谱构建及应用开发提供实验依据.","authors":[{"authorName":"王芸","id":"0f4dc1ff-e9f5-4ae9-8579-da81426b90f0","originalAuthorName":"王芸"},{"authorName":"AZEEM Intisar","id":"3dfd1d6e-1cb3-48d8-b3cd-b78d0f33305f","originalAuthorName":"AZEEM Intisar"},{"authorName":"BOIMA KIAZOLU J","id":"56f5c233-2c7a-432a-a1c8-9854f106e673","originalAuthorName":"BOIMA KIAZOLU J"},{"authorName":"刘海燕","id":"38e884d8-bbcf-47ec-8e52-36d6fd3488cf","originalAuthorName":"刘海燕"},{"authorName":"张维冰","id":"c289d33d-ebce-438e-a3ee-e7cb993743fb","originalAuthorName":"张维冰"}],"doi":"10.3724/SP.J.1123.2010.01192","fpage":"1192","id":"a4688aa8-7b87-480a-b4b0-6c5efba5f6e8","issue":"12","journal":{"abbrevTitle":"SP","coverImgSrc":"journal/img/cover/SP.jpg","id":"58","issnPpub":"1000-8713","publisherId":"SP","title":"色谱 "},"keywords":[{"id":"4d32b167-bc45-4005-b0d1-a82dbdfe7f08","keyword":"高效液相色谱","originalKeyword":"高效液相色谱"},{"id":"2431d57e-1ca1-4c80-b5af-9d146f481b5c","keyword":"组分","originalKeyword":"组分"},{"id":"6d03950d-6540-4a49-9c48-d20cb88032f4","keyword":"水飞蓟","originalKeyword":"水飞蓟"},{"id":"99f8f6ff-b92b-4667-8724-55f2f74e16bc","keyword":"中草药","originalKeyword":"中草药"}],"language":"zh","publisherId":"sp201012017","title":"水飞蓟全草不同部位的组成特征","volume":"28","year":"2010"},{"abstractinfo":"分析了以水为发泡剂的全水聚氨酯发泡成型工艺过程中水的加入量对泡沫塑料性质的影响.研究了异氰酸酯指数为105,聚醚多元醇官能度为4,羟值为480mg KOH/g时,发泡剂水加入量与泡沫塑料开孔率、力学性能、泡沫稳定性等性质的关系.结果表明,聚氨酯泡沫塑料随着水的加入量从1 g增加到10 g,泡沫体拉伸强度降低了30%,压缩强度降低了29%;泡孔直径由50 μm~100 μm增加到300 μm~400 μm;玻璃化转变温度由102℃上升到112℃.","authors":[{"authorName":"梁继才","id":"b84c4a0e-a658-43ed-92e1-39d3ac562dec","originalAuthorName":"梁继才"},{"authorName":"林琳","id":"fc4b446d-7110-4adc-9dc3-f22225407dcd","originalAuthorName":"林琳"},{"authorName":"李义","id":"d3759b7a-74a3-47c6-a31d-0e2da795cf8f","originalAuthorName":"李义"},{"authorName":"马骅","id":"b783a44e-ce51-4284-8b4f-c8126961244b","originalAuthorName":"马骅"},{"authorName":"杨丰","id":"022f9faa-8b00-4f3e-9f98-f605c52155f9","originalAuthorName":"杨丰"},{"authorName":"宋平","id":"33f9cea8-e8c9-45f8-abea-f73d00fc9d7e","originalAuthorName":"宋平"}],"doi":"","fpage":"40","id":"5cae4929-cc73-4eb1-b8d5-c44122edc450","issue":"6","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"ae9900cd-3d5b-4964-be10-815106e2eef9","keyword":"全水聚氨酯发泡","originalKeyword":"全水聚氨酯发泡"},{"id":"dcf4acad-cd6b-44f9-b8da-01cfbda26828","keyword":"水加入量","originalKeyword":"水加入量"},{"id":"9d2cb4cd-1751-4746-9504-357cd8c6b416","keyword":"开孔率","originalKeyword":"开孔率"},{"id":"dc94cd21-8d1e-4d8d-99d8-ab1001f1853c","keyword":"稳定性","originalKeyword":"稳定性"}],"language":"zh","publisherId":"gfzclkxygc201006012","title":"水加入量对全水聚氨酯泡沫塑料性质的影响","volume":"26","year":"2010"},{"abstractinfo":"采用扫描电镜(SEM)和红外光谱(FT-IR)并结合物理力学性能测试,对高水用量(3phr~11phr)所制备的全水发泡低密度聚氨酯泡沫的形态和力学性能进行表征,结果表明,水用量逐渐从3phr增加到11phr,发泡聚氨酯物料的乳白时间、凝胶时间和不粘手时间逐渐延长,泡沫中的取代脲结构含量和氢键化程度逐渐增加,泡沫密度和力学性能逐渐降低,泡孔平均孔径呈先增大、后减小的趋势,然而泡沫的比强度和氨基甲酸酯含量变化不大。","authors":[{"authorName":"陈涛","id":"102c6679-7e5a-413b-b81f-e8b107970f93","originalAuthorName":"陈涛"},{"authorName":"杜海晶","id":"79b98b20-6156-41c5-a2b7-c508db44b85a","originalAuthorName":"杜海晶"},{"authorName":"米岩","id":"7b6b9fb0-2251-4b45-a771-7d4b698e47b3","originalAuthorName":"米岩"},{"authorName":"高振华","id":"b4613403-9aae-4dba-8c6e-b67d334629ae","originalAuthorName":"高振华"}],"doi":"","fpage":"67","id":"b9b458d2-c104-4190-851d-d2741207c7dd","issue":"7","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"7bbee8b9-3b39-4f24-a404-43e838a2a6e7","keyword":"聚氨酯泡沫","originalKeyword":"聚氨酯泡沫"},{"id":"74fd7996-253a-4cb0-bf61-c6fd0a60a73a","keyword":"全水发泡","originalKeyword":"全水发泡"},{"id":"b120a1c3-63bb-4e2e-a0d8-39d9a2254635","keyword":"泡沫形态","originalKeyword":"泡沫形态"},{"id":"eadf58f3-3100-44d9-ad95-467060cd9a93","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"gfzclkxygc201207018","title":"水用量对全水发泡聚氨酯泡沫形态和力学性能的影响","volume":"28","year":"2012"},{"abstractinfo":"将胶清通过中空纤维柱浓缩后,分别用碱性蛋白酶和木瓜蛋白酶进行脱蛋白处理,以得到非橡胶组分少的高级胶清橡胶,并研究其各项性能.结果表明,浓缩胶清经过碱性蛋白酶和木瓜蛋白酶处理后胶清橡胶的氮含量和挥发物含量显著降低;胶清橡胶的硫化速率变慢,改善了胶清橡胶易焦烧的性能;胶清橡胶的力学性能提高,热稳定性降低.","authors":[{"authorName":"张哲","id":"11b85593-f770-4950-953a-a786a583da32","originalAuthorName":"张哲"},{"authorName":"廖双泉","id":"78fd3767-4f91-4b69-814c-67eaf75bc67d","originalAuthorName":"廖双泉"},{"authorName":"郭明万","id":"06e0ad4b-70fb-4671-afda-de27c69d1016","originalAuthorName":"郭明万"},{"authorName":"廖小雪","id":"1d1d6b83-9d96-4b03-8e41-e6559c72899a","originalAuthorName":"廖小雪"},{"authorName":"王丽芝","id":"bea6c016-757b-41b3-8f19-0bb5d24efaf7","originalAuthorName":"王丽芝"}],"doi":"","fpage":"758","id":"de6ad4c0-0c9d-42b8-9856-397498c136ac","issue":"5","journal":{"abbrevTitle":"CLKXYGCXB","coverImgSrc":"journal/img/cover/CLKXYGCXB.jpg","id":"13","issnPpub":"1673-2812","publisherId":"CLKXYGCXB","title":"材料科学与工程学报"},"keywords":[{"id":"cadba9a9-098d-4496-a685-6e4473d19eaa","keyword":"胶清橡胶","originalKeyword":"胶清橡胶"},{"id":"81008d2a-a30b-4265-ae86-42b879646392","keyword":"脱蛋白","originalKeyword":"脱蛋白"},{"id":"7d4ea146-353d-49ca-80ac-22100199765d","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"clkxygc201305028","title":"高级胶清橡胶的性能","volume":"31","year":"2013"},{"abstractinfo":"从半导体光催化剂全分解水反应原理出发,介绍了近年来新开发的无机半导体光催化剂,如钽酸盐半导体,Ge基半导体、Ga基半导体,层状金属氧化物,具有d0、d10电子构型的半导体和Z型反应体系,分析了光催化效率的影响因素,并对未来做出了展望.","authors":[{"authorName":"潘珺怡","id":"4591aa2d-567f-4527-9678-ef8086d9307f","originalAuthorName":"潘珺怡"},{"authorName":"周涵","id":"2ed4a4ae-ca9e-460c-a486-79e530143a57","originalAuthorName":"周涵"}],"doi":"","fpage":"19","id":"0f9517b2-819e-4053-92a2-581dd1360ccd","issue":"15","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"65bd4756-7620-419e-9e87-e3c33cf1c7f6","keyword":"半导体","originalKeyword":"半导体"},{"id":"fbdad7af-9cb2-4a4b-84ed-030460c3e37e","keyword":"全分解水","originalKeyword":"全分解水"},{"id":"8658ee7c-29c2-4b51-8cb1-18100d3b683f","keyword":"Z型反应体系","originalKeyword":"Z型反应体系"},{"id":"b5b552d3-29e9-450b-b588-2e510ebeaea2","keyword":"光催化效率","originalKeyword":"光催化效率"}],"language":"zh","publisherId":"cldb201315004","title":"半导体光催化全分解水的最新研究进展","volume":"27","year":"2013"}],"totalpage":1392,"totalrecord":13920}