{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"在综合分析无机模板法和有机模板法的基础上,提出矿物模板法和复合模板法是制备中孔炭的有效方法.矿物模板法原料价格低廉、来源广泛.复合模板法综合了软模板和硬模板的优点,能够拓展中孔炭的结构、性能和应用领域.以矿物模板制备的炭材料具有良好的电学、医学性能等,有望获得良好性价比的中孔炭材料.","authors":[{"authorName":"传秀云","id":"64817d02-8c7e-488e-87a2-13638ef43e25","originalAuthorName":"传秀云"},{"authorName":"周述慧","id":"09a1a90f-11ef-453e-8958-9a6d9037df7a","originalAuthorName":"周述慧"}],"doi":"","fpage":"151","id":"0c170fa8-2e54-44f4-ab3f-d2b7345b054f","issue":"2","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"2614c304-9928-4a0b-b553-7569611cec9b","keyword":"中孔炭材料","originalKeyword":"中孔炭材料"},{"id":"e11ee947-71db-4436-ab86-f934378a43ee","keyword":"模板法","originalKeyword":"模板法"},{"id":"c5748767-4b3d-4929-b873-4a3ed28b9eff","keyword":"矿物模板法","originalKeyword":"矿物模板法"},{"id":"1480e37c-2477-4a72-94bb-d8bf99527792","keyword":"复合模板法","originalKeyword":"复合模板法"},{"id":"dba63b99-66fc-4918-87b6-2ebb2be2d1ef","keyword":"合成","originalKeyword":"合成"}],"language":"zh","publisherId":"xxtcl201102012","title":"模板法合成中孔炭材料","volume":"26","year":"2011"},{"abstractinfo":"综述了国内外在中孔活性炭材料开发方面的研究进展.着重介绍了催化活化、界面活化、混合聚合物炭化、有机凝胶炭化、铸型炭化等孔径调控方法及其中孔形成机理.为控制活性炭材料孔径大小和分布,提高其中孔容积和吸附性能提供了参考.","authors":[{"authorName":"常俊玲","id":"c029d37e-1f5e-434f-9f2f-47319533fa14","originalAuthorName":"常俊玲"},{"authorName":"刘洪波","id":"a0b8c24c-6994-4130-a4bf-ffd837ec3a2f","originalAuthorName":"刘洪波"},{"authorName":"唐冬汉","id":"77d78d52-a871-4788-aebf-e01dd39dd58f","originalAuthorName":"唐冬汉"},{"authorName":"张红波","id":"b011a956-4875-469c-bc3c-2ff1f37db606","originalAuthorName":"张红波"}],"doi":"","fpage":"49","id":"4e2fa1d3-6de8-4056-9ffc-25b24ff4ad4e","issue":"3","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"af8d153c-e564-4c9a-ab2d-528dcd3753a4","keyword":"活性炭","originalKeyword":"活性炭"},{"id":"e951218c-d19c-4edf-bbb7-b5367d3a482c","keyword":"吸附性能","originalKeyword":"吸附性能"},{"id":"1a73530a-22ad-48c5-b244-2b7520fbf2d4","keyword":"中孔","originalKeyword":"中孔"}],"language":"zh","publisherId":"cldb200203016","title":"中孔活性炭材料的研究进展","volume":"16","year":"2002"},{"abstractinfo":"以钛酸正丁酯为钛源、蔗糖为炭源,采用溶胶-凝胶法制得有机-无机复合干凝胶,后经高温炭热反应、氯气化学刻蚀分别得到中孔碳化钛及碳化物基炭材料(CDCS).通过XRD、Raman、SEM、TEM和氮气吸附等表征,考察了钛酸正丁酯/蔗糖摩尔比例(R)对所制碳化钛和CDCS的孔结构和物理特性的影响.结果表明:在碳热过程所形成的中孔和大孔孔隙能够在氯气刻蚀过程中保持并传递给最终的炭材料.所制CDCS具有三种不同层次的孔隙结构,分别为氯气刻蚀碳化钛品体所产生的微孔、源自蔗糖残留炭中所含的3nm~4nm中孔以及炭颗粒间相互叠加和连接所形成的大孔.通过改变R比值,所制CDCS的BET比表面积和孔容分别在1479m2/g~1640m2/g和1.06cm3/g~2.03cm3/g之间可调.","authors":[{"authorName":"成果","id":"dca691c1-94b6-4f9d-b63b-fbbd58bd4d00","originalAuthorName":"成果"},{"authorName":"龙东辉","id":"7cbde3cf-f9af-450a-b36b-f5057cfd4367","originalAuthorName":"龙东辉"},{"authorName":"刘小军","id":"e4e0668f-7dfd-4773-a448-cf59cd739871","originalAuthorName":"刘小军"},{"authorName":"凌立成","id":"f3a75bdf-c5f7-4c4f-8279-92586acb137c","originalAuthorName":"凌立成"}],"doi":"10.1016/S1872-5805(08)60050-5","fpage":"243","id":"6bcd7905-85ab-4924-b806-35a9227cd1d4","issue":"3","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"c6d5aea6-9621-4dc6-afa6-9ac69d7c156b","keyword":"分等级孔结构","originalKeyword":"分等级孔结构"},{"id":"0947ad6c-db39-4dd8-b844-7055ca68f572","keyword":"中孔碳化钛","originalKeyword":"中孔碳化钛"},{"id":"4bc72f6c-533c-4012-a996-7495c1b1b877","keyword":"氯气刻蚀","originalKeyword":"氯气刻蚀"},{"id":"e13f47b5-0d4d-4dd0-bb27-90df14439cdc","keyword":"孔隙结构","originalKeyword":"孔隙结构"}],"language":"zh","publisherId":"xxtcl200903005","title":"氯气刻蚀中孔碳化钛制备分等级孔结构炭材料","volume":"24","year":"2009"},{"abstractinfo":"利用溶剂挥发自组装的方法制备了2种不同孔结构中孔炭材料。低温N2吸脱附、SAXS、HRSEM和TEM测试表明,所制备的材料分别具有柱状结构和墨水瓶状的中孔结构。考察了不同炭化温度对2种结构中孔炭的影响,结果表明柱状结构的中孔炭材料具有较好的热稳定性。","authors":[{"authorName":"李鹏","id":"c1435493-761b-460e-b43f-8276fcf6c02e","originalAuthorName":"李鹏"},{"authorName":"宋燕","id":"58368667-67e5-4567-bcb5-5e39b3b00f2c","originalAuthorName":"宋燕"},{"authorName":"钟明","id":"49ff7c7c-14f7-44bc-8284-a152ae0fd70a","originalAuthorName":"钟明"},{"authorName":"耿煜","id":"3c628f61-9dba-4179-8617-f7bc8c2dd797","originalAuthorName":"耿煜"},{"authorName":"史景利","id":"cadf1c7f-bd2e-44cc-898e-b70a590f45e1","originalAuthorName":"史景利"},{"authorName":"刘朗","id":"55c1981b-3b7f-4622-bf7a-3aa40c030638","originalAuthorName":"刘朗"},{"authorName":"郭全贵","id":"cb157b24-7c5a-42cd-ac20-05b23a1b72a6","originalAuthorName":"郭全贵"}],"doi":"","fpage":"2440","id":"dd094af8-813d-4158-8a4d-7b9893e1227a","issue":"18","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"50f4af32-6ea8-484e-bbdc-3bbf29f1350f","keyword":"中孔炭","originalKeyword":"中孔炭"},{"id":"fd94be2f-832d-4538-bd35-39a0ad6f50c0","keyword":"孔结构","originalKeyword":"孔结构"},{"id":"7ccab07f-ef49-4ea4-be57-d2ff0b94976f","keyword":"热稳定性","originalKeyword":"热稳定性"}],"language":"zh","publisherId":"gncl201218004","title":"不同结构中孔炭材料的制备和热稳定性研究","volume":"43","year":"2012"},{"abstractinfo":"以乙酸镁和柠檬酸镁为模板(MgO)镁源,沥青为碳前驱体,在氮气氛中950℃一步炭化制得高表面积中孔炭材料.采用1 mol/L的HCl去模,并将炭材料洗涤至中性.采用低温N2吸附测得炭材料的比表面积和孔径分布,透射电镜观察炭材料的内部结构特征.结果表明:尽管未经活化,所得炭材料中的孔大多为中孔,BET比表而积达到1295 m2/g,当以柠檬酸镁为MgO前驱体时,所得炭材料的收率可高达50%.","authors":[{"authorName":"王艳素","id":"25b348e0-238c-471d-8fa2-3a179b27de32","originalAuthorName":"王艳素"},{"authorName":"王成扬","id":"f2fc6d4f-a90f-4d1c-aa8f-879b9bd52175","originalAuthorName":"王成扬"},{"authorName":"陈明鸣","id":"e4179320-2805-4653-b547-eacee1e9a6ae","originalAuthorName":"陈明鸣"}],"doi":"10.1016/S1872-5805(08)60047-5","fpage":"187","id":"c84785c1-dddb-4f78-886b-feca79bc3922","issue":"2","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"45e5a8df-9c51-41be-a2ac-3c3820e5e4f9","keyword":"沥青","originalKeyword":"沥青"},{"id":"172c0e63-23e4-473a-a225-995a5e9713d3","keyword":"MgO","originalKeyword":"MgO"},{"id":"c8e84d4e-2393-49ee-97fb-789768b4dc25","keyword":"模板炭化法","originalKeyword":"模板炭化法"},{"id":"58f7a120-c5dc-486e-8461-b2c0c523a1d5","keyword":"中孔炭","originalKeyword":"中孔炭"}],"language":"zh","publisherId":"xxtcl200902017","title":"一步模板炭化法制备新型沥青基中孔炭材料","volume":"24","year":"2009"},{"abstractinfo":"采用微湿含浸法制备了一系列具有不同比表面积和孔径分布的超级电容器有序中孔炭材料.采用液氮吸附脱附等温线、小角XRD以及TEM表征了有序中孔炭的孔结构,在1 M Et_4NBF_4 IPC电解液中测试了其电化学性能.结果表明,所制得的有序中孔炭的BET比表面积随糠醇加入量的增加先增加后减小,糠醇加入量少制得具有CMK-5结构的有序中孔炭,加入量多制得的CMK-3结构.电化学性能测试结果表明,在1mA·cm~(-2)的充放电电流密度下各有序中孔炭材料比电容的大小顺序与其BET比表面积的大小顺序基本一致,具有CMK-3结构的有序中孔炭的倍率性能最好,并且也好于无序中孔炭的.","authors":[{"authorName":"赵家昌","id":"a02c88ef-a47b-4871-bfb5-1782d9c7d6a1","originalAuthorName":"赵家昌"},{"authorName":"张熙贵","id":"bbdaa02e-cb2c-4616-b287-e25a19854a0a","originalAuthorName":"张熙贵"},{"authorName":"郑静","id":"d9ddf17c-efba-4b27-9c04-161811fb42cb","originalAuthorName":"郑静"},{"authorName":"孙锦晶","id":"21b1f280-2ba5-4452-a742-87c4126e8b59","originalAuthorName":"孙锦晶"},{"authorName":"徐菁利","id":"e734bbaa-55cc-4bd8-816c-a72954bbaf84","originalAuthorName":"徐菁利"}],"doi":"10.3969/j.issn.1007-4252.2009.05.011","fpage":"477","id":"90fca1a1-1eb8-49a5-b1fa-5fd14269904a","issue":"5","journal":{"abbrevTitle":"GNCLYQJXB","coverImgSrc":"journal/img/cover/GNCLYQJXB.jpg","id":"34","issnPpub":"1007-4252","publisherId":"GNCLYQJXB","title":"功能材料与器件学报 "},"keywords":[{"id":"ff12200a-8dca-44eb-9a2b-86d0e831d5dc","keyword":"超级电容器","originalKeyword":"超级电容器"},{"id":"1f78c385-0a2f-4a4c-ba26-f91ace046c6e","keyword":"有序中孔炭","originalKeyword":"有序中孔炭"},{"id":"f63a3b21-35b3-4861-9e7d-e75948fb86f9","keyword":"糠醇","originalKeyword":"糠醇"},{"id":"66c51a22-4046-4f77-b9d0-4d430ab562bf","keyword":"电化学性能","originalKeyword":"电化学性能"}],"language":"zh","publisherId":"gnclyqjxb200905011","title":"高性能超级电容器有序中孔炭材料的研制","volume":"15","year":"2009"},{"abstractinfo":"采用纳米涂层技术,以介孔分子筛SBA-15为模板,在其纳米孔道内引入糠醇/草酸溶液,经原位聚合,炭化后制得炭/SBA-15复合物.采用化学法脱除模板后制得具有规则结构的中孔炭.高分辨TEM表征结果显示该中孔炭是由纳米炭管相互联接、堆积而成,且具有六方对称结构.氮吸附结果显示其比表面积高达2 000 m2/g,孔径呈双峰分布.孔径相对较大的孔隙来源于SBA-15孔道经纳米涂层后所保留的孔隙;孔径相对较小的孔隙来源于SiO2移除后遗留的纳米孔空间.该方法可应用于以其他多孔氧化硅为模板制备新型纳米复合物的研究过程.","authors":[{"authorName":"陆安慧","id":"377f99f4-fcbd-44f7-a485-0d87fde9e6c2","originalAuthorName":"陆安慧"},{"authorName":"","id":"fd5a1fed-140c-4fa2-9314-eda8adac746d","originalAuthorName":""},{"authorName":"","id":"c83e7710-2d41-42c0-9e87-939ddd9b4e70","originalAuthorName":""}],"doi":"10.3969/j.issn.1007-8827.2003.03.003","fpage":"181","id":"baedff7a-6e41-441d-9ea9-498b3f3048df","issue":"3","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"d6ec1848-45f8-4cf0-92c9-3553fa4905a6","keyword":"中孔炭","originalKeyword":"中孔炭"},{"id":"9ba3588f-71b2-4c5f-9ed2-5aeb33bfd82f","keyword":"模板","originalKeyword":"模板"},{"id":"fe08dee0-5c1f-49d6-aa34-b820f97f24ac","keyword":"孔径分布","originalKeyword":"孔径分布"}],"language":"zh","publisherId":"xxtcl200303003","title":"结构有序、双重孔隙中孔炭材料的合成与表征","volume":"18","year":"2003"},{"abstractinfo":"以间苯二酚-甲醛为前驱体、喷雾干燥法可规模制备出中孔炭微球,进一步采用聚乙烯醇对其进行表面致密化处理,再与酚醛树脂热压成型得到中孔炭微球/酚醛树脂复合材料,系统研究了复合材料的力学性能及介电性能.结果表明,所制炭微球具有较窄的粒径分布(1~10 μm)、发达的中孔孔隙(孔容>3.0 cm3/g).经表面包覆后,中孔炭微球表面致密,形成类“蛋壳”结构.当用于复合材料填料(0~10%)时,能有效的降低复合材料的密度(1.36 g/cm3至1.12 g/cm3),并显著提升复合材料的力学性能(压缩强度由106 MPa增加至168 MPa);在102 ~ 107 Hz频率下,复合材料的介电常数随着炭微球添加量的增加逐渐提高,由4.0~3.6提高至10.4 ~9.1.结果表明,中孔炭微球可作为新一类多功能填料,在降低复合材料密度的同时增加力学性能,并在较宽频率下具备高的介电性能,具有优异的低密度吸波基体材料的应用潜力.","authors":[{"authorName":"周建国","id":"29b7436c-ecbc-403f-bc91-702cfe8ef658","originalAuthorName":"周建国"},{"authorName":"朱小磊","id":"78d9ce93-eb4f-4f4b-8195-c9fd724efa1c","originalAuthorName":"朱小磊"},{"authorName":"张利","id":"cc75c392-11eb-401e-a406-2d196db4152c","originalAuthorName":"张利"},{"authorName":"乔文明","id":"4ff07fbb-9763-4b3f-a691-0b943e99bf70","originalAuthorName":"乔文明"},{"authorName":"龙东辉","id":"7d145379-63f4-469f-91a8-c15a87ca7774","originalAuthorName":"龙东辉"},{"authorName":"凌立成","id":"12b559e5-d3b1-410c-a779-d17808247247","originalAuthorName":"凌立成"}],"doi":"","fpage":"301","id":"6b6f6007-634e-4b0b-a3ff-57c082ccd5cd","issue":"3","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"a3d839a8-833a-41bf-8223-673ba859cbf3","keyword":"中孔炭微球","originalKeyword":"中孔炭微球"},{"id":"7e096a51-9924-4354-bd5a-662f7652f17c","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"4269668f-8a6b-4eee-be79-a4de64a7203a","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"9542a6c7-8195-4d29-a8ea-ff14758b7193","keyword":"介电性能","originalKeyword":"介电性能"}],"language":"zh","publisherId":"xxtcl201603010","title":"中孔炭微球/酚醛树脂复合材料的力学及介电性能","volume":"31","year":"2016"},{"abstractinfo":"以正硅酸乙酯为模板硅源,间苯二酚-甲醛凝胶为炭前驱体,采用同步合成模板炭化(SSTCM)法制备了具有可控结构的中孔炭材料.炭材料的比表面积可达1 500 m2/g,平均孔径在3 nm~10 nm之间.经过酸催化水解预处理的二氧化硅模板前驱体溶液与间苯二酚-甲醛溶液混合,碱性条件下使两者的溶胶凝胶反应同步发生,得到有机/无机凝胶混合物.再经炭化、HF去模,制得SSTCM炭材料.N2等温吸脱附研究表明,与炭前驱体聚合物同步合成的结构可调的二氧化硅模板,导致了SSTCM炭材料可控中孔结构的形成.循环伏安研究表明,采用这种同步合成模板炭化法制备的SSTCM炭材料质量比容量达270 F/g,炭材料具有的典型中孔结构使其可能成为一种理想的双电层电容器电极材料.","authors":[{"authorName":"侯朝辉","id":"6272b75a-76fd-4bca-89be-94e90c7de8bb","originalAuthorName":"侯朝辉"},{"authorName":"李新海","id":"24e323c6-fc04-4bbd-bca3-3983d16d5f35","originalAuthorName":"李新海"},{"authorName":"刘恩辉","id":"a2fc1d92-1e3e-4c4e-bc72-4b0ab3efe98e","originalAuthorName":"刘恩辉"},{"authorName":"何则强","id":"0065680c-ed10-45bd-a93f-457c31f6df56","originalAuthorName":"何则强"},{"authorName":"邓凌峰","id":"e1404d06-e934-4a05-8033-1d72ff7f8871","originalAuthorName":"邓凌峰"}],"doi":"10.3969/j.issn.1007-8827.2004.01.003","fpage":"11","id":"fcb2cae5-0dd1-4fee-bf98-ccb3e5ddcdb7","issue":"1","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"8a8f3d98-8603-44b1-bf63-fbb447e144c0","keyword":"中孔炭","originalKeyword":"中孔炭"},{"id":"3671cf42-8f37-4fa6-a3dc-18565a9789a9","keyword":"溶胶凝胶反应","originalKeyword":"溶胶凝胶反应"},{"id":"f7b8db82-911c-454d-be6d-6f1939c96de2","keyword":"同步合成模板炭化法","originalKeyword":"同步合成模板炭化法"},{"id":"761bd82c-5062-4f74-8f89-4f1aec7abc5a","keyword":"双电层电容器","originalKeyword":"双电层电容器"}],"language":"zh","publisherId":"xxtcl200401003","title":"同步合成模板炭化法制备双电层电容器电极用中孔炭材料的研究","volume":"19","year":"2004"},{"abstractinfo":"以石油焦为原料,运用化学活化法制备了超级电容器用高比表面积中孔活性炭.利用XRD、SEM和BET对实验制备的中孔炭进行了分析和表征.以实验制备的活性炭为超级电容器电极材料,利用恒流充放电测试对其电容特性进行了研究.结果表明,实验研制的活性炭的比表面积为1733m2/g,中孔含量达到60.6%,在150mA/g的电流密度下其比容达到180F/g,而且基于实验研制的活性炭的超级电容器具有低内阻和良好的功率特性.","authors":[{"authorName":"方勤","id":"37536ba5-17a1-432e-8eaf-d89c3946bbb9","originalAuthorName":"方勤"},{"authorName":"杨邦朝","id":"09e39695-4b86-4dab-a77d-2da2c24621ed","originalAuthorName":"杨邦朝"}],"doi":"","fpage":"1889","id":"635ed373-4f87-49f2-abbd-f7cac89151f8","issue":"12","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"ba52e7d5-2055-404f-b46b-9257133b69d8","keyword":"超级电容器","originalKeyword":"超级电容器"},{"id":"de788c1b-ea8b-4326-98d8-6b5a9a4999f4","keyword":"中孔炭","originalKeyword":"中孔炭"},{"id":"d504a364-d546-43c3-8626-78870f56d26a","keyword":"比容","originalKeyword":"比容"}],"language":"zh","publisherId":"gncl200512023","title":"超级电容器用中孔炭的研究","volume":"36","year":"2005"}],"totalpage":13032,"totalrecord":130311}