{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"采用流变仪研究了固化反应温度、时间以及增韧剂和增稠剂加入量对酚醛树脂流变特性的影响,并测试了玻璃纤维增强酚醛预浸料与Nomex蜂窝芯共固化成型后玻璃纤维/酚醛-Nomex蜂窝夹层结构复合材料的板-芯黏接性能.结果表明:改性后酚醛树脂在高温时的黏度提高较多,流动性得到了有效改善,所得预浸料与Nomex蜂窝芯的界面黏接明显增强,并且当增韧剂和增稠剂的加入量与纯酚醛树脂的质量比分别为5％和3％时,所制备出的夹层板的滚筒剥离强度达到15 N·mm/mm以上,改性后酚醛树脂及其预浸料具有了一定程度的<span style=\"color:red\">自</span><span style=\"color:red\">黏附</span>特性.此外,在共固化工艺中采用合适的升温制度,可以进一步提高玻璃纤维/酚醛-Nomex蜂窝夹层结构复合材料的板-芯黏接强度.","authors":[{"authorName":"王伟","id":"93fac267-de0f-4ebc-a349-c934b33d776f","originalAuthorName":"王伟"},{"authorName":"左小彪","id":"06591665-8662-43fa-923a-7e630d174f95","originalAuthorName":"左小彪"},{"authorName":"冯志海","id":"8ac42bdc-13e3-45dc-9cf1-0bd8aa75b49b","originalAuthorName":"冯志海"},{"authorName":"颜雪","id":"18a707c2-079e-41f6-a6ed-8f7a90749511","originalAuthorName":"颜雪"},{"authorName":"胡宏林","id":"e20aa088-9072-48b3-a311-8eb67e6c1c4c","originalAuthorName":"胡宏林"},{"authorName":"李昊","id":"f781d768-bdbf-4149-afaf-09a5feefe25f","originalAuthorName":"李昊"}],"doi":"10.13801/j.cnki.fhclxb.20150616.001","fpage":"510","id":"7705353b-6054-4fb1-943b-de761951f376","issue":"3","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":"8c98ffcf-9ec4-4d66-8fa4-61410032a427","keyword":"<span style=\"color:red\">自</span><span style=\"color:red\">黏附</span>","originalKeyword":"自黏附"},{"id":"b119bbb0-e516-49f6-9b6c-6c47e01cb358","keyword":"流变","originalKeyword":"流变"},{"id":"b0690259-8fc4-4001-a7d2-37a023960bd2","keyword":"酚醛树脂","originalKeyword":"酚醛树脂"},{"id":"f3d3f1fa-b5c3-4fc6-badf-2e2cfd18d62d","keyword":"预浸料","originalKeyword":"预浸料"},{"id":"bd261b4f-c8d7-47a4-880c-42fc327015ab","keyword":"黏接","originalKeyword":"黏接"},{"id":"3cb01a9f-fdce-4b6e-9695-108febeebea4","keyword":"Nomex蜂窝夹层结构","originalKeyword":"Nomex蜂窝夹层结构"},{"id":"34503668-878b-4b6e-832d-d6351121fd12","keyword":"复合材料","originalKeyword":"复合材料"}],"language":"zh","publisherId":"fhclxb201603009","title":"<span style=\"color:red\">自</span><span style=\"color:red\">黏附</span>型酚醛树脂流变特性及其预浸料与Nomex蜂窝芯共固化黏接性能","volume":"33","year":"2016"},{"abstractinfo":"自然界中很多动物,如壁虎、甲虫和树蛙等,主要利用可逆的<span style=\"color:red\">黏附</span>力在各种表面爬行.研究发现这些动物脚趾上的特殊微纳柱状结构(刚毛、平滑结构等)起到了至关重要的作用.一方面,这些微纳柱状结构及其精细亚结构保证了动物脚趾能与接触表面形成很多有效接触点,从而形成足够强的<span style=\"color:red\">黏附</span>力.产生的<span style=\"color:red\">黏附</span>力甚至可达动物体重的200倍.另一方面,这些微纳结构又可以保证动物能从<span style=\"color:red\">黏附</span>的表面迅速脱离.这种<span style=\"color:red\">黏附</span>能力依赖于结构而非接触材料的表面化学组成的特性,具有极高的科研价值和应用前景.","authors":[{"authorName":"汪鑫","id":"460719df-9bc6-42ec-a92e-598f11e9d532","originalAuthorName":"汪鑫"},{"authorName":"李倩","id":"b493ea53-9585-4656-b288-2ca2816e3906","originalAuthorName":"李倩"},{"authorName":"薛龙建","id":"4d8619c3-38aa-4e15-bac3-dca931ebc53a","originalAuthorName":"薛龙建"}],"doi":"10.7502/j.issn.1674-3962.2017.01.07","fpage":"48","id":"a6783610-c711-404d-9c5c-40b5235ef582","issue":"1","journal":{"abbrevTitle":"ZGCLJZ","coverImgSrc":"journal/img/cover/中国材料进展.jpg","id":"80","issnPpub":"1674-3962","publisherId":"ZGCLJZ","title":"中国材料进展"},"keywords":[{"id":"964a6765-fbd9-4dbb-824f-208d9cee0622","keyword":"仿生材料","originalKeyword":"仿生材料"},{"id":"ea986889-6ab8-4b4d-b6f4-ab9a01ade988","keyword":"干态<span style=\"color:red\">黏附</span>","originalKeyword":"干态黏附"},{"id":"66fdd4e0-3e40-4692-8ce7-e501ffe67c4a","keyword":"湿态<span style=\"color:red\">黏附</span>","originalKeyword":"湿态黏附"},{"id":"f7533d7e-c677-4824-89de-25c49e1383b6","keyword":"摩擦","originalKeyword":"摩擦"},{"id":"6cefa5ad-6569-432b-8a54-ae98b76de01f","keyword":"柱状阵列","originalKeyword":"柱状阵列"},{"id":"44c2f90d-1e10-4d0c-8023-92d2253896e8","keyword":"聚合物","originalKeyword":"聚合物"},{"id":"9d511aed-065c-43a9-9545-d602358b5776","keyword":"壁虎","originalKeyword":"壁虎"}],"language":"zh","publisherId":"zgcljz201701007","title":"仿生柱状<span style=\"color:red\">黏附</span>材料","volume":"36","year":"2017"},{"abstractinfo":"以三丁醇铝为前驱体,采用溶胶凝胶法和浸涂法制备得到氧化铝凝胶薄膜.再通过沸水处理、热处理和表面接枝聚乙烯亚胺和硬脂酸等工艺,获得了一种既具有超疏水特性又呈现出强<span style=\"color:red\">黏附</span>力的氧化铝薄膜.利用傅里叶变换红外光谱(FTIR)、场发射扫描电子显微镜(FE-SEM)、X射线衍射(XRD)和接触角测试等技术对薄膜表面的化学组成、形貌、结构和润湿性能及其<span style=\"color:red\">黏附</span>性等进行了考察.结果表明:所研制的氧化铝表面由多孔的花瓣状粗糙结构和独特的疏水长链单分子层构成.水滴可以润湿粗糙表面上较大尺度的凹槽,而不能浸润较小尺度的凹槽,从而使得这种氧化铝表面既呈现出很高的接触角,又具有较强的<span style=\"color:red\">黏附</span>特性.","authors":[{"authorName":"强小虎","id":"a2f3c49c-92fd-44f0-b0a5-79d531565f3a","originalAuthorName":"强小虎"},{"authorName":"张红霞","id":"33ac5906-b05c-413f-996e-0e5c27ab9b19","originalAuthorName":"张红霞"},{"authorName":"王彦平","id":"233c51aa-b9f4-4d03-953f-fd730ed46873","originalAuthorName":"王彦平"},{"authorName":"冯利邦","id":"cf1338ef-5e0e-46cf-bf65-76d65bb040d1","originalAuthorName":"冯利邦"}],"doi":"10.3969/j.issn.1001-4381.2013.03.011","fpage":"55","id":"4f96cc45-20ab-4d9e-b43b-06356df8d0e2","issue":"3","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"8e1ac205-951f-4a99-9ce9-0126fc02c891","keyword":"氧化铝","originalKeyword":"氧化铝"},{"id":"ae8b3f02-059f-449d-ab4e-b223fbe92dbd","keyword":"超疏水","originalKeyword":"超疏水"},{"id":"bd787d35-74ae-4b19-a0db-d571918bcea0","keyword":"花瓣状结构","originalKeyword":"花瓣状结构"},{"id":"8e5ceb4d-885f-42eb-a806-a8640ce88d29","keyword":"强<span style=\"color:red\">黏附</span>力","originalKeyword":"强黏附力"}],"language":"zh","publisherId":"clgc201303011","title":"强<span style=\"color:red\">黏附</span>性超疏水氧化铝的表面结构和<span style=\"color:red\">黏附</span>机理","volume":"","year":"2013"},{"abstractinfo":"对比分析了不同类型碳纤维与环氧树脂的接触角的变化规律,并利用Young-Dupre法和Wu法,分析了<span style=\"color:red\">黏附</span>功随温度的变化规律,以及树脂固化对纤维/树脂润湿、<span style=\"color:red\">黏附</span>作用的影响。结果表明：升高温度有利于T300、CCF、T700纤维和环氧AG80树脂的润湿,去除纤维表面上浆剂后其表面能极性分量下降,与AG80树脂的润湿和<span style=\"color:red\">黏附</span>性能变差;在树脂体系未发生化学反应前,AG80/DDS树脂体系比AG80纯树脂与T700纤维的润湿性能好,<span style=\"color:red\">黏附</span>性能差;110℃恒温条件下随固化时间延长,AG80/DDS和E51/DDS树脂体系与T700纤维的浸润和<span style=\"color:red\">黏附</span>性能均改善。","authors":[{"authorName":"曹芳维","id":"16863fe6-0a46-4151-9baa-1593f5f3d250","originalAuthorName":"曹芳维"},{"authorName":"李敏","id":"f13fff61-816d-40f2-9876-44f801c2c6f3","originalAuthorName":"李敏"},{"authorName":"王绍凯","id":"86610284-2b2b-4986-ae17-973ac570809d","originalAuthorName":"王绍凯"},{"authorName":"顾轶卓","id":"282cbcd6-0be6-4b0a-ad75-a3c729d022c4","originalAuthorName":"顾轶卓"},{"authorName":"张佐光","id":"83df6c4e-2a38-49d7-bd5d-d6825ebedfe6","originalAuthorName":"张佐光"}],"doi":"","fpage":"23","id":"7aebf9de-e8f1-4667-b35d-9b66804cdcb2","issue":"4","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":"e549fde3-1e10-4aa8-95cf-2b26a5613d8c","keyword":"接触角","originalKeyword":"接触角"},{"id":"80f82d0b-f823-475d-afee-31b29785c540","keyword":"<span style=\"color:red\">黏附</span>功","originalKeyword":"黏附功"},{"id":"2e38bd78-bdb9-4f3a-a714-9d9e93c82daa","keyword":"表面能","originalKeyword":"表面能"},{"id":"77af7751-716d-400b-bc4c-ac9996dc46fc","keyword":"碳纤维","originalKeyword":"碳纤维"},{"id":"42f55c13-92d8-4ec4-b6d5-f2f6f068969a","keyword":"环氧树脂","originalKeyword":"环氧树脂"}],"language":"zh","publisherId":"fhclxb201104005","title":"碳纤维与环氧树脂润湿和<span style=\"color:red\">黏附</span>作用","volume":"28","year":"2011"},{"abstractinfo":"磷石膏热分解制硫酸联产水泥过程中在回转窑部分很容易由于颗粒的团聚和壁面<span style=\"color:red\">黏附</span>,造成管道堵塞,这样会严重影响磷石膏热分解制硫酸联产水泥的工艺运行.经过对比流态化分解磷石膏后的结垢物和流化粉末的X射线荧光光谱、X射线衍射和扫描式电子显微镜分析研究磷石膏热分解过程中的<span style=\"color:red\">黏附</span>变化.结果表明,结垢物中的Si、Al等矿物质元素明显高于流化粉末,说明主要的黏土性矿物质杂质在壁面<span style=\"color:red\">黏附</span>富集;随着反应的进行,CaO的含量的增加会较为明显的降低颗粒的<span style=\"color:red\">黏附</span>程度.因此对于磷石膏粉体,SiO2、Al2O3等杂质不仅影响磷石膏的分解效率,还严重影响其流化过程中的团聚<span style=\"color:red\">黏附</span>.","authors":[{"authorName":"王荣谋","id":"c54770ca-e590-4899-bf42-4c65a9cbc7c4","originalAuthorName":"王荣谋"},{"authorName":"马丽萍","id":"93746928-43d1-4ff7-bb47-ea4972aadc21","originalAuthorName":"马丽萍"},{"authorName":"郑大龙","id":"1c90f60c-b920-45a2-ab32-1e1557a1c65b","originalAuthorName":"郑大龙"},{"authorName":"王倩倩","id":"302b4241-e1e9-4b60-b632-e1b93580d82a","originalAuthorName":"王倩倩"},{"authorName":"唐剑骁","id":"1d30100d-d587-4bad-a262-37423b6338c6","originalAuthorName":"唐剑骁"}],"doi":"","fpage":"791","id":"62f5f888-102e-49bf-9925-e484dc11eab8","issue":"3","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"764410ca-fc14-4e5d-9a20-47a3fa39d1d9","keyword":"磷石膏","originalKeyword":"磷石膏"},{"id":"97ca7926-e8fd-4ef2-a912-754e61bdac43","keyword":"流态化","originalKeyword":"流态化"},{"id":"79137a9b-d553-400e-8576-df4ebba977fa","keyword":"<span style=\"color:red\">黏附</span>","originalKeyword":"黏附"},{"id":"e944a342-76c7-4f6d-a3ed-c6c03d9a8867","keyword":"团聚","originalKeyword":"团聚"}],"language":"zh","publisherId":"gsytb201703006","title":"磷石膏流化分解过程颗粒的<span style=\"color:red\">黏附</span>特性","volume":"36","year":"2017"},{"abstractinfo":"海洋贻贝类生物通过足丝分泌的<span style=\"color:red\">黏附</span>蛋白,具有高强度、高韧性、防水性以及极强<span style=\"color:red\">黏附</span>性等特点,可以使其<span style=\"color:red\">黏附</span>在几乎所有基底材料上.大量研究表明,3,4-二羟基-L-苯基丙氨酸(多巴,DOPA)是海洋贻贝类生物分泌的相关<span style=\"color:red\">黏附</span>蛋白中的重要组成部分.而且,贻贝<span style=\"color:red\">黏附</span>蛋白所具有的这种超强<span style=\"color:red\">黏附</span>能力,主要与多巴中特有的分子结构以及其与基底材料的相互作用方式等相关.多巴胺作为多巴衍生物的重要成员,具有与多巴相似的结构和性质,同样可以实现对基材表面的<span style=\"color:red\">黏附</span>,因而引起了研究人员的极大关注.本文综述了多巴胺的结构、性质、聚合机理以及它们在材料学、仿生学、生物医学等不同领域的应用现状.","authors":[{"authorName":"李珍妮","id":"433fc71b-b281-4909-95d6-458099a2211d","originalAuthorName":"李珍妮"},{"authorName":"邓字巍","id":"f6c80b4e-d3d4-4395-86bd-3088b1cd8882","originalAuthorName":"邓字巍"}],"doi":"","fpage":"185","id":"6c1bbe0c-7e45-4082-ba11-fb473597af41","issue":"1","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":"18bea80e-64ec-46b8-9250-dbd8aa292122","keyword":"多巴胺","originalKeyword":"多巴胺"},{"id":"ba9c350b-703d-47f8-bfca-f6a8077c4081","keyword":"<span style=\"color:red\">黏附</span>性","originalKeyword":"黏附性"},{"id":"0ae329de-95cc-4ab5-b39d-97165e2efa4d","keyword":"表面修饰","originalKeyword":"表面修饰"},{"id":"87a88ef1-c313-4aff-ab28-06c2b9e40cf0","keyword":"生物矿化","originalKeyword":"生物矿化"},{"id":"1d956426-5ddc-4032-b832-1dc574bcc50e","keyword":"应用","originalKeyword":"应用"}],"language":"zh","publisherId":"gfzclkxygc201501035","title":"仿贻贝<span style=\"color:red\">黏附</span>性多巴胺的研究与应用进展","volume":"31","year":"2015"},{"abstractinfo":"<span style=\"color:red\">黏附</span>性是超疏水表面的一个重要特性,随着对超疏水表面研究的深入,具有响应特性的智能超疏水表面引起了人们的极大兴趣,而能够作为“机械手”抓取液滴的具有高<span style=\"color:red\">黏附</span>性的超疏水表面自然成为关注对象.本文讨论了表面形貌和表面化学组成对超疏水表面<span style=\"color:red\">黏附</span>性的影响,综述了近年来高<span style=\"color:red\">黏附</span>性超疏水表面制备方面的研究进展,并对高<span style=\"color:red\">黏附</span>性超疏水表面未来的研究方向做出了展望.","authors":[{"authorName":"刘金秋","id":"deb05c2c-6030-43c7-89c4-6c124dd35cab","originalAuthorName":"刘金秋"},{"authorName":"柏冲","id":"1d24f493-c97c-4274-973a-e99405cbe6bc","originalAuthorName":"柏冲"},{"authorName":"徐文华","id":"e47c2091-15cc-48a5-a000-6b62e248ae8a","originalAuthorName":"徐文华"},{"authorName":"张献","id":"07cd821a-60d5-40d9-bd87-181331de550c","originalAuthorName":"张献"},{"authorName":"刘迎凯","id":"f4833760-4c77-4bff-8a00-470a120caa3a","originalAuthorName":"刘迎凯"},{"authorName":"姚金水","id":"db457d29-895b-4776-ad7d-357fe3087b17","originalAuthorName":"姚金水"},{"authorName":"刘伟良","id":"10fdc939-21dd-4b6f-97c4-30de40ab49ab","originalAuthorName":"刘伟良"}],"doi":"10.3724/SP.J.1095.2013.20548","fpage":"733","id":"e1574dcd-c7f7-4e2b-95c9-31399037124d","issue":"7","journal":{"abbrevTitle":"YYHX","coverImgSrc":"journal/img/cover/YYHX.jpg","id":"73","issnPpub":"1000-0518","publisherId":"YYHX","title":"应用化学"},"keywords":[{"id":"93d1ea1e-851f-450c-874c-7cb8a6398172","keyword":"超疏水","originalKeyword":"超疏水"},{"id":"5dbfbcca-96a0-4d9f-86ff-78553fba7074","keyword":"<span style=\"color:red\">黏附</span>性","originalKeyword":"黏附性"},{"id":"840d2c0c-377b-4b3d-9143-b847cc66ab86","keyword":"表面形貌","originalKeyword":"表面形貌"},{"id":"398c6d62-8ae1-4c1b-8b09-d72ce269bc9c","keyword":"化学组成","originalKeyword":"化学组成"}],"language":"zh","publisherId":"yyhx201307001","title":"高<span style=\"color:red\">黏附</span>性超疏水表面的研究进展","volume":"30","year":"2013"},{"abstractinfo":"将儿茶酚(catechol)接枝到聚乙烯醇(PVA)侧基上，得到改性聚乙烯醇(m-PVA)，以模拟贻贝类分泌的<span style=\"color:red\">黏附</span>蛋白液。通过(UV-spectra)、(FT-IR)及(H 1 NMR)证实了 m-PVA 的大分子结构，并计算出接枝率大约为10％。此外，通过热失重分析(TG)表征了 m-PVA 的热稳定性能。对于模拟贻贝类<span style=\"color:red\">黏附</span>凝胶的形成机理，通过 UV-spectra 研究了 m-PVA 在不同pH 值条件下对三价铁离子(Fe3＋)的络合作用及所形成的<span style=\"color:red\">黏附</span>凝胶，以及在高碘酸钠(NaIO 4)的氧化下，通过化学交联得到的具有<span style=\"color:red\">黏附</span>性质的凝胶。通过本文的初步研究，最终合成出具有一定<span style=\"color:red\">黏附</span>性质的 m-PVA凝胶，在一定程度上对贻贝类<span style=\"color:red\">黏附</span>凝胶进行了仿生。","authors":[{"authorName":"杨潇","id":"fe616c3d-9f46-49fb-b451-cbf9f803d255","originalAuthorName":"杨潇"},{"authorName":"贾二鹏","id":"49e26220-b26f-4c79-b400-0a8e4a2031d2","originalAuthorName":"贾二鹏"},{"authorName":"易世雄","id":"d20f8f4f-7992-4018-a374-a1c202153a27","originalAuthorName":"易世雄"},{"authorName":"冉小琪","id":"b85d07ec-9d7b-4c65-ab7b-c4b6ce167858","originalAuthorName":"冉小琪"}],"doi":"10.3969/j.issn.1001-9731.2015.15.004","fpage":"15016","id":"caac6c73-7f8f-4471-acc1-03e8ba30b922","issue":"15","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"32d7a673-52c2-42a6-a681-be5361826a31","keyword":"贻贝","originalKeyword":"贻贝"},{"id":"483b7faf-152d-443a-98f3-f6a02985dccd","keyword":"仿生","originalKeyword":"仿生"},{"id":"07f4e04c-23ad-4ce3-991e-2c067974a637","keyword":"<span style=\"color:red\">黏附</span>","originalKeyword":"黏附"},{"id":"fa285db9-4602-4902-9e15-fb153a2095f9","keyword":"聚乙烯醇","originalKeyword":"聚乙烯醇"}],"language":"zh","publisherId":"gncl201515004","title":"仿贻贝类含儿茶酚改性聚乙烯醇<span style=\"color:red\">黏附</span>凝胶的合成","volume":"","year":"2015"},{"abstractinfo":"通过硬脂酸的醇水溶液一步浸泡法成功获得超疏水铝合金表面,其水接触角可达156.2°,滚动角小于5°.利用接触角测试、扫描电镜、红外光谱观测、结冰实验与防<span style=\"color:red\">黏附</span>实验分别对超疏水铝合金表面的润湿性能、表面微结构、化学结构以及防覆冰和防<span style=\"color:red\">黏附</span>行为进行了研究.结果表明:所制得的超疏水表面是由微-纳“多孔”结构和疏水烃基长链所共同赋予的.正是由于其特殊的粗糙结构和化学组成,使得该超疏水表面表现出良好的防覆冰和防<span style=\"color:red\">黏附</span>行为.","authors":[{"authorName":"晏忠钠","id":"8f3be682-e871-421e-9b35-262c40f26bfe","originalAuthorName":"晏忠钠"},{"authorName":"车彦慧","id":"15796df2-e67f-4ede-b04b-824438fde6de","originalAuthorName":"车彦慧"},{"authorName":"冯利邦","id":"15c7a428-1308-43eb-828b-5f5cca096522","originalAuthorName":"冯利邦"},{"authorName":"强小虎","id":"e98464d7-f07b-4e08-b605-2f1b35809b58","originalAuthorName":"强小虎"},{"authorName":"刘艳花","id":"bd2a00f9-c2fe-42fc-9a63-6972d94184d0","originalAuthorName":"刘艳花"}],"doi":"10.11868/j.issn.1001-4381.2015.09.005","fpage":"25","id":"931c0c46-0e91-4877-95ed-ed7a643a7bb2","issue":"9","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"7efdec0c-21a7-419d-91a6-cc02e8e6f163","keyword":"一步浸泡","originalKeyword":"一步浸泡"},{"id":"9867221b-1a48-42ee-ad97-ceebb24af567","keyword":"铝合金","originalKeyword":"铝合金"},{"id":"fc1f47d5-c4a4-4bd6-a5c4-b63ca418d7f5","keyword":"超疏水","originalKeyword":"超疏水"},{"id":"1f71e09a-8099-445e-9024-ef6bffec1306","keyword":"防覆冰","originalKeyword":"防覆冰"},{"id":"58e1348b-3091-46f9-b5ed-8554e9c493db","keyword":"防<span style=\"color:red\">黏附</span>","originalKeyword":"防黏附"}],"language":"zh","publisherId":"clgc201509005","title":"超疏水铝合金表面的防覆冰和防<span style=\"color:red\">黏附</span>行为","volume":"43","year":"2015"},{"abstractinfo":"主要探讨血管支架材料--NiTi合金不同表面形貌对牛主动脉血管内皮细胞及血小板<span style=\"color:red\">黏附</span>的影响.采用机械抛光、机械刻蚀和化学浸蚀的方法制备微孔、微凹槽等微结构特征的NiTi合金表面.利用扫描电镜、粗糙度轮廓仪等对材料表面微观形貌和平均粗糙度进行表征,并测定微孔和微凹槽的材料表面对血小板及血管内皮细胞<span style=\"color:red\">黏附</span>的影响.结果表明:NiTi合金基体表面制备纳米级粗糙度的微孔和微凹槽等不同微观形貌对血小板<span style=\"color:red\">黏附</span>的影响不显著,但可明显促进内皮细胞的<span style=\"color:red\">黏附</span>;具有微孔结构的材料表面<span style=\"color:red\">黏附</span>的细胞数量最多,且细胞生长状态良好;材料表面微凹槽结构对细胞的早期<span style=\"color:red\">黏附</span>具有接触诱导效应.微粗糙化的各种不同材料表面形貌对血小板<span style=\"color:red\">黏附</span>的影响不显著.","authors":[{"authorName":"沈阳","id":"526f6103-9e28-40fc-a7e7-42223da0b3e3","originalAuthorName":"沈阳"},{"authorName":"王贵学","id":"2fdc3cb7-8dfa-4a93-8d50-15ca20de4985","originalAuthorName":"王贵学"},{"authorName":"张勤","id":"1884c909-4564-4eae-abd3-2107a6158559","originalAuthorName":"张勤"},{"authorName":"唐朝君","id":"682454a5-f190-4788-84f8-e398615b0ce1","originalAuthorName":"唐朝君"},{"authorName":"葛淑萍","id":"021d7406-1396-4768-aae6-1dd4a8131d7c","originalAuthorName":"葛淑萍"},{"authorName":"俞青松","id":"38b8093a-79fa-410b-9a6f-92a4e71621a3","originalAuthorName":"俞青松"}],"doi":"","fpage":"1018","id":"c1508148-dba3-4efe-9c1d-8db61f7db6d5","issue":"6","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"2ed1104e-2e11-47f1-a5d1-eefdfdde4ee6","keyword":"NiTi合金","originalKeyword":"NiTi合金"},{"id":"bcb87e33-c109-41fa-a4fb-a7206b1eacb9","keyword":"表面形貌","originalKeyword":"表面形貌"},{"id":"83b9d1c7-afdd-438f-acb1-57667a2d4d50","keyword":"血管内支架","originalKeyword":"血管内支架"},{"id":"be6a92ed-18f4-4219-851c-bb198ac23196","keyword":"细胞<span style=\"color:red\">黏附</span>","originalKeyword":"细胞黏附"},{"id":"e38a2efd-f457-4f71-8643-8887a33f28bc","keyword":"血小板<span style=\"color:red\">黏附</span>","originalKeyword":"血小板黏附"}],"language":"zh","publisherId":"xyjsclygc201006018","title":"NiTi合金表面微观形貌对血管内皮细胞及血小板<span style=\"color:red\">黏附</span>的影响","volume":"39","year":"2010"}],"totalpage":422,"totalrecord":4216}