{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"本文以氧化石墨烯和钛酸丁酯为原料,利用水热法一步制备了TiO2/石墨烯复合光催化材料,研究了氧化石墨烯用量、反应温度、反应时间对TiO2/石墨烯复合材料光催化活性的影响.采用XRD,SEM,TEM和氮气吸附-脱附实验(BET)对复合光催化材料的物相、颗粒粒径、形貌及比表面积进行了表征.结果表明,本实验最佳条件是:氧化石墨烯1mg,制备温度为180℃,反应时间为16 h.产物中的TiO2为锐钛矿晶型,其平均粒径约为18 nm.复合材料的比表面积为170m./g,平均孔径为12.45 nm.在可见光照射(λ＞420nm)下以TiO2/石墨烯为光催化剂对有机染料罗丹明B(Rhodamine B,RhB)进行光催化降解,其光催化活性明显高于相同条件下制备的TiO2.","authors":[{"authorName":"王昭","id":"e115584c-72bd-47dd-b07d-39394f8c1edd","originalAuthorName":"王昭"},{"authorName":"毛峰","id":"41b9414b-087d-480c-8d47-028006360712","originalAuthorName":"毛峰"},{"authorName":"<span style=\"color:red\">黄</span><span style=\"color:red\">祥</span><span style=\"color:red\">平</span>","id":"3610de90-3e5d-420a-887b-88d4dcb139ef","originalAuthorName":"黄祥平"},{"authorName":"<span style=\"color:red\">黄</span>应<span style=\"color:red\">平</span>","id":"e116b179-0b20-48c6-a2f2-710c8b0d3046","originalAuthorName":"黄应平"},{"authorName":"冯笙琴","id":"746fcfb8-31e5-4ac6-8547-153d57ef2788","originalAuthorName":"冯笙琴"},{"authorName":"易佳","id":"de1b228e-7326-40ca-afcb-697774df2203","originalAuthorName":"易佳"},{"authorName":"张昌远","id":"62915e48-a0ac-481d-b715-3a7a944356b2","originalAuthorName":"张昌远"},{"authorName":"刘栓","id":"96aed4c6-499a-439b-941b-625b0a3b74e7","originalAuthorName":"刘栓"}],"doi":"","fpage":"267","id":"19df698c-0a6c-47b4-a769-bfbfabc63cf1","issue":"2","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":"0e630816-c0fa-433f-8d6b-fca6f76e6004","keyword":"石墨烯","originalKeyword":"石墨烯"},{"id":"f2ba9a7e-c593-42fc-9bb3-cf4e22ea5428","keyword":"水热法","originalKeyword":"水热法"},{"id":"0980f0c4-57ad-4de7-8d0e-55c34a794e7f","keyword":"TiO2/石墨烯","originalKeyword":"TiO2/石墨烯"},{"id":"9120b63e-e78d-4161-bf29-58387609f15f","keyword":"光催化","originalKeyword":"光催化"}],"language":"zh","publisherId":"clkxygc201102023","title":"TiO2/石墨烯复合材料的制备及其光催化性能","volume":"29","year":"2011"},{"abstractinfo":"本文以TiCl3为原料,采用水热法,在150℃下很方便地制备出了纯金红石型二氧化钛纤维.对样品进行的粉末X射线衍射(XRD),扫描电子显微镜(SEM),高分辨透射电子显微镜(HRTEM)表征显示,该纤维由纳米棒自组装而成,纤维的长度约为1～2mm,直径约为15μm,分散性良好.紫外可见光(UV-vis)吸收谱图显示该样品的能隙能量Eg=3.0eV,降解RhB实验表明该样品在可见光下的催化能力优于商用P25.","authors":[{"authorName":"王昭","id":"8b13ee68-860b-4459-8804-8702f76b6f60","originalAuthorName":"王昭"},{"authorName":"毛峰","id":"866a89c4-14ec-44b5-ab5e-65e60ecc3f6e","originalAuthorName":"毛峰"},{"authorName":"<span style=\"color:red\">黄</span><span style=\"color:red\">祥</span><span style=\"color:red\">平</span>","id":"d4c33508-cf35-4c36-b57b-e7aab1894693","originalAuthorName":"黄祥平"},{"authorName":"魏慧丽","id":"c2544f81-613e-4118-912a-4e6a9ac22857","originalAuthorName":"魏慧丽"},{"authorName":"张昌远","id":"d5018944-34cc-4b02-85c2-f6e378fbdb2c","originalAuthorName":"张昌远"},{"authorName":"冯笙琴","id":"d521e919-5906-44c3-a40c-a03b699db5b7","originalAuthorName":"冯笙琴"}],"doi":"","fpage":"96","id":"0f78f3d1-005e-4219-bc21-94735e34282e","issue":"1","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":"950a7be9-d17c-4fe3-98de-86fe9ab15647","keyword":"水热法","originalKeyword":"水热法"},{"id":"94dacb4d-76cb-4872-8014-8151485a38a5","keyword":"二氧化钛","originalKeyword":"二氧化钛"},{"id":"ac80632c-0e41-4d36-af64-b0e874da610a","keyword":"纤维","originalKeyword":"纤维"},{"id":"84db0345-8cc0-4496-94e1-24cdc9a82403","keyword":"光催化","originalKeyword":"光催化"}],"language":"zh","publisherId":"clkxygc200901024","title":"二氧化钛纳米棒自组装纤维的水热一步合成及其光催化性能","volume":"27","year":"2009"},{"abstractinfo":"讨论了高能飞秒激光烧蚀金属金靶材过程中电子热导率对激光烧蚀性质的影响.由于电子热容量,电声耦合系数及电子热导率等热物理参数对能够表征飞秒激光烧蚀性质的电子最高温度,电声耦合时间及电声耦合温度都有一定影响,且这3个热物理参数都为电子温度或电子温度及晶格温度相关的表达式,为了更清楚了解电子热导率对飞秒激光烧蚀性质的影响,将电子热容量及电声耦合系数在合理范围内分别取常数值,而对电子热导率在合理范围内按等差规律分别取3个常系数值,通过在一维双温模型的基础上变化电子热导率常系数值模拟飞秒激光烧蚀金属靶材的热传输演化过程,详细研究了电子热导率对飞秒激光烧蚀金靶材性质的影响.结果表明:电子热导率对金靶材表面电子最高温度,电声耦合时间及电声耦合温度都有不同程度影响.由于电子热导率实质在靶材表面电子达到最高温度后反映的是电子亚系统中电子释放能量速率快慢,因此导致电子热导率对电声耦合温度的影响最为显著.","authors":[{"authorName":"谭新玉","id":"4c389a0d-d37a-4880-a908-a54d58d859ae","originalAuthorName":"谭新玉"},{"authorName":"魏慧丽","id":"2118675e-eb05-4778-a1e0-159767b14499","originalAuthorName":"魏慧丽"},{"authorName":"毛峰","id":"67200ea2-4f57-4335-b2f6-b570669a802d","originalAuthorName":"毛峰"},{"authorName":"徐辉进","id":"2d4da2b6-e344-46c9-a823-561ebc8d84c2","originalAuthorName":"徐辉进"},{"authorName":"<span style=\"color:red\">黄</span><span style=\"color:red\">祥</span><span style=\"color:red\">平</span>","id":"008273e0-ec91-4e96-a3ef-07a747d3a034","originalAuthorName":"黄祥平"},{"authorName":"易佳","id":"dc84f407-8658-45e3-8528-5fe3ee7e8302","originalAuthorName":"易佳"}],"doi":"10.3969/j.issn.0258-7076.2011.05.014","fpage":"704","id":"5141a2bd-04da-4edb-8e64-4d112a16159c","issue":"5","journal":{"abbrevTitle":"XYJS","coverImgSrc":"journal/img/cover/XYJS.jpg","id":"67","issnPpub":"0258-7076","publisherId":"XYJS","title":"稀有金属"},"keywords":[{"id":"44dc6fc0-be44-4d81-a6f0-2c85ce97d80a","keyword":"电子热导率","originalKeyword":"电子热导率"},{"id":"7a864910-73b2-4c8a-abde-af3a13a439e1","keyword":"飞秒激光烧蚀","originalKeyword":"飞秒激光烧蚀"},{"id":"7abb484a-f533-4c2b-9af1-25eaee69b440","keyword":"电声耦合温度","originalKeyword":"电声耦合温度"}],"language":"zh","publisherId":"xyjs201105014","title":"高能飞秒激光烧蚀金靶材的动态热导率影响研究","volume":"35","year":"2011"},{"abstractinfo":"以草酸和乙酸镍为原料,通过低温固相法合成前驱体（NiC2O4.2H2O）粉末。用此前驱体粉末与固态NaOH混合并充分研磨制得纳米Ni（OH）2粉末。经SEM、XRD测试表明,制得的纳米Ni（OH）2粉末是平均粒径约为12nm的β-Ni（OH）2。用循环伏安法、恒流充放电测试和交流阻抗谱研究Ni（OH）2电极的电化学电容特性。结果表明在电流密度为1A.g-1时,其比电容高达2271F.g-1,且经多次循环后表现出较好的循环稳定性能。","authors":[{"authorName":"刘亚威","id":"e692100f-8752-405d-a768-4cdb5245b436","originalAuthorName":"刘亚威"},{"authorName":"赵雯雯","id":"e6c22d1a-3ff9-452c-b51c-61e280840453","originalAuthorName":"赵雯雯"},{"authorName":"张昌远","id":"6320c00d-d358-470f-8346-5e6f60be37c4","originalAuthorName":"张昌远"},{"authorName":"<span style=\"color:red\">黄</span><span style=\"color:red\">祥</span><span style=\"color:red\">平</span>","id":"88c6fd63-79d1-4287-99f7-0aba99d3c690","originalAuthorName":"黄祥平"},{"authorName":"毛峰","id":"7fe8ded3-8c75-42c5-a598-10f34c1aec0b","originalAuthorName":"毛峰"},{"authorName":"杨学林","id":"8bacf16a-c703-4fd4-ab72-0b6b6e86af04","originalAuthorName":"杨学林"}],"doi":"","fpage":"606","id":"76e93ee5-953e-451a-bb7e-ec62183e9347","issue":"4","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":"df7bc841-1e7e-4741-aa75-e5c58b0b8c6b","keyword":"氢氧化镍","originalKeyword":"氢氧化镍"},{"id":"424b5f1c-3b0f-4449-87c8-c12ec1b78fe9","keyword":"低温固相法","originalKeyword":"低温固相法"},{"id":"2c16081e-ec84-4dd3-ace2-d8b6e0637039","keyword":"超级电容器","originalKeyword":"超级电容器"}],"language":"zh","publisherId":"clkxygc201204025","title":"高比容纳米Ni（OH）_2的制备及其电化学电容性能","volume":"30","year":"2012"},{"abstractinfo":"用水热法在180℃一步合成了TiO2纳米棒自组装微米球,并对其光催化性能和形成机理进行了分析.采用X-射线衍射(XRD),扫描电镜(SEM),透射电镜(TEM)和氮气吸附(BET)对催化剂的物相、颗粒粒径及比表面积进行了表征,结果显示产物为金红石型结构,呈纳米棒自组装微米球形貌,微米球中纳米棒的直径约为30纳米.氮气吸附解附实验表明微米球比表面积为31.2m2/g,介孔的尺寸为3.88nm.催化实验显示其在可见光下的催化能力优于P25.","authors":[{"authorName":"<span style=\"color:red\">黄</span><span style=\"color:red\">祥</span><span style=\"color:red\">平</span>","id":"2675e04e-1b2c-489a-845d-26084684eb11","originalAuthorName":"黄祥平"},{"authorName":"王昭","id":"d86a2169-0a82-494f-86e1-ebc55c50db8f","originalAuthorName":"王昭"},{"authorName":"张昌远","id":"7325d12b-e578-460b-806f-b34640f0141e","originalAuthorName":"张昌远"},{"authorName":"毛峰","id":"deac21fa-8dd3-4024-b159-a880f48d2b9a","originalAuthorName":"毛峰"},{"authorName":"魏慧丽","id":"f273c075-cfc0-4a10-a84c-be1396c575e5","originalAuthorName":"魏慧丽"}],"doi":"","fpage":"709","id":"8addd86d-696d-4e28-91ee-18244c9d48b4","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":"eec93163-8c04-447e-bca7-698ff760aa08","keyword":"二氧化钛","originalKeyword":"二氧化钛"},{"id":"86565f3e-7155-4268-b4cb-2cb8d560048d","keyword":"自组装","originalKeyword":"自组装"},{"id":"1e3435c2-fcb7-4bfb-9982-489d5d24368a","keyword":"微米球","originalKeyword":"微米球"},{"id":"6c01a146-700b-456b-a5da-8fcf0209be45","keyword":"生长机理","originalKeyword":"生长机理"},{"id":"aaea894f-c967-42c1-96cd-e3abce8d9203","keyword":"光催化","originalKeyword":"光催化"}],"language":"zh","publisherId":"clkxygc200905015","title":"二氧化钛纳米棒自组装微米球的制备、性能及其生长机理","volume":"27","year":"2009"},{"abstractinfo":"<span style=\"color:red\">黄</span>原胶是一种生物高分子,广泛应用于30多个行业.综述了<span style=\"color:red\">黄</span>原胶的生物化学、发酵工艺、产品后处理及其应用等方面的进展.","authors":[{"authorName":"徐世艾","id":"91842dd8-94a6-407c-bedd-78f111e7449d","originalAuthorName":"徐世艾"}],"doi":"","fpage":"59","id":"657b1742-7072-45a9-8cd4-a4625cbaa87b","issue":"10","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"0cbbf8b0-fff4-417b-a739-97a64cd235e1","keyword":"<span style=\"color:red\">黄</span>原胶","originalKeyword":"黄原胶"},{"id":"ce71eab7-d945-4da6-9131-1a3329fc272f","keyword":"发酵","originalKeyword":"发酵"},{"id":"9d97f4d8-9b74-4670-9ab4-29e2daf505eb","keyword":"工程","originalKeyword":"工程"},{"id":"c66015d8-b360-4cb2-ba59-2bc856f16ca7","keyword":"后处理","originalKeyword":"后处理"},{"id":"c53ce4c0-9082-4abd-9a60-b310c3eca93f","keyword":"应用","originalKeyword":"应用"}],"language":"zh","publisherId":"cldb200010019","title":"<span style=\"color:red\">黄</span>原胶及其应用","volume":"14","year":"2000"},{"abstractinfo":"介绍了自流<span style=\"color:red\">平</span>环氧地面涂料的组成、成膜机理、性能和施工方法,简要介绍了自行研制的自流<span style=\"color:red\">平</span>环氧地面涂料.","authors":[{"authorName":"江洪申","id":"6d7ec617-0596-41d8-a842-3ec1bcf1b730","originalAuthorName":"江洪申"},{"authorName":"陈安仁","id":"45db21d2-44c4-4b76-b9c2-a786f8224042","originalAuthorName":"陈安仁"}],"doi":"10.3969/j.issn.1005-748X.2003.12.009","fpage":"539","id":"133e1883-f0f2-4306-a6e5-5862836a9620","issue":"12","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"a09a5479-0b14-4e9b-9cd4-f20328fe9f76","keyword":"自流<span style=\"color:red\">平</span>","originalKeyword":"自流平"},{"id":"6beb3451-a35a-4b6b-8c5c-155d3cbd6a79","keyword":"环氧地面涂料","originalKeyword":"环氧地面涂料"},{"id":"99cb22a5-f890-4767-ba64-d320670871ec","keyword":"成膜机理","originalKeyword":"成膜机理"},{"id":"06059833-6242-417e-b656-415d156601a4","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"fsyfh200312009","title":"自流<span style=\"color:red\">平</span>环氧地面涂料","volume":"24","year":"2003"},{"abstractinfo":"本文通过选用合适的低聚物和单体组合,使用非<span style=\"color:red\">黄</span>变型光引发剂,对不同类型的塑料应用进行配方设计.分别测试了涂膜的耐<span style=\"color:red\">黄</span>变性、光泽、硬度、耐刮擦性能.","authors":[{"authorName":"陈顺凉","id":"98efce1c-0130-4254-a3c0-6b49dd5393fc","originalAuthorName":"陈顺凉"},{"authorName":"<span style=\"color:red\">黄</span>瑞村","id":"e8f448ac-0fa6-4cf2-a004-acbd856e4c47","originalAuthorName":"黄瑞村"},{"authorName":"薛永富","id":"69b9b6a3-ea58-46fc-899a-5bb1f3487936","originalAuthorName":"薛永富"}],"doi":"10.3969/j.issn.0253-4312.2004.10.009","fpage":"25","id":"4bba03fc-da71-43a5-aeae-3cf25082346d","issue":"10","journal":{"abbrevTitle":"TLGY","coverImgSrc":"journal/img/cover/TLGY.jpg","id":"61","issnPpub":"0253-4312","publisherId":"TLGY","title":"涂料工业   "},"keywords":[{"id":"7f1a4bae-5448-41f4-a6c9-290290af1603","keyword":"紫外光","originalKeyword":"紫外光"},{"id":"5e4ee472-cedc-4100-bf38-2622cded42dd","keyword":"固化","originalKeyword":"固化"},{"id":"4e0da2c0-6270-4d00-adc9-5a4aed931b47","keyword":"塑料涂料","originalKeyword":"塑料涂料"},{"id":"f7a59efa-5692-44ea-a858-83669666e1a8","keyword":"耐<span style=\"color:red\">黄</span>变","originalKeyword":"耐黄变"},{"id":"cce29d66-d288-423b-8428-0c449c21003b","keyword":"研究","originalKeyword":"研究"}],"language":"zh","publisherId":"tlgy200410009","title":"耐<span style=\"color:red\">黄</span>变型UV塑料面漆","volume":"34","year":"2004"},{"abstractinfo":"分析了水性涂料涂膜出现缺陷的原因和不同类型的流<span style=\"color:red\">平</span>剂对改善涂膜外观的效果.","authors":[{"authorName":"","id":"53177b79-3a60-43d8-9f8a-3fa9ddf1fc00","originalAuthorName":""},{"authorName":"","id":"c1c3ee12-96c7-45d0-b086-d86365816e81","originalAuthorName":""},{"authorName":"","id":"d55d4fa4-29b6-45cf-8e37-78c6acb4f7a4","originalAuthorName":""}],"doi":"","fpage":"34","id":"820b240c-7779-4bf5-945d-ae141a5aa3c9","issue":"6","journal":{"abbrevTitle":"TLGY","coverImgSrc":"journal/img/cover/TLGY.jpg","id":"61","issnPpub":"0253-4312","publisherId":"TLGY","title":"涂料工业   "},"keywords":[{"id":"7774db9f-b456-48f1-8c0e-7eb5b714bd0d","keyword":"水性涂料","originalKeyword":"水性涂料"},{"id":"1e26280d-8c34-49f2-826e-0834a4a56576","keyword":"缺陷","originalKeyword":"缺陷"},{"id":"710b772e-4a38-4c10-93ab-92c81219cdc6","keyword":"流<span style=\"color:red\">平</span>剂","originalKeyword":"流平剂"}],"language":"zh","publisherId":"tlgy200206014","title":"水性涂料用流<span style=\"color:red\">平</span>剂","volume":"32","year":"2002"},{"abstractinfo":"综述了<span style=\"color:red\">平</span>焰燃烧技术的现状和发展,介绍了该技术的工作原理、结构特点及其在节能和环保方面的优势以及在武钢热轧厂的应用效果.","authors":[{"authorName":"刘占增","id":"ad97f66b-eee7-45da-863d-c238dfed8fcb","originalAuthorName":"刘占增"},{"authorName":"丁翠娇","id":"214b3169-ae33-4efd-b213-f706a031acf1","originalAuthorName":"丁翠娇"},{"authorName":"郑兆<span 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