{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":4,"startPagecode":1},"records":[{"abstractinfo":"使用中国原子能科学研究院HI-13串列加速器产生的32 S离子轰击BOPET薄膜,薄膜在空气中陈化3个月后在专用装置中使用NaOH溶液蚀刻制备核孔膜,研究NaOH溶液浓度、蚀刻温度对微孔孔形的影响。在不同温度和蚀刻液浓度条件下,蚀刻出微孔孔径为0.2至0.93μm的亚微米核孔膜,计算其微孔锥角,得出微孔锥角随着蚀刻温度、蚀刻液浓度和微孔孔径的变化趋势。研究表明,采用低浓度、高温度的NaOH溶液蚀刻有利于减小微孔锥角,有利于制备较小孔径的核孔膜。如选用0.5 mol/L的NaOH溶液浓度,在蚀刻温度为90℃的条件下蚀刻,此时蚀刻时间小于2 h,既可以得到高质量微孔膜也有利于提高生产效率。","authors":[{"authorName":"张璐","id":"42f54614-a57f-4b01-901e-a38fe4810ede","originalAuthorName":"张璐"},{"authorName":"吴振东","id":"6dce418c-f4e9-4870-9c1a-40a5131c8a55","originalAuthorName":"吴振东"},{"authorName":"肖德涛","id":"b96746da-ed83-48bf-9ff0-64a84d1c9616","originalAuthorName":"肖德涛"},{"authorName":"梁海英","id":"3cc5f451-e5a7-4320-bbc5-dc5e57d15df2","originalAuthorName":"梁海英"},{"authorName":"鞠薇","id":"710704f5-9b73-40a8-b78b-af75563b9c11","originalAuthorName":"鞠薇"},{"authorName":"陈东风","id":"8e54212a-5020-495a-9209-c50705598005","originalAuthorName":"陈东风"},{"authorName":"傅元勇","id":"0580ca23-7ac5-49a5-b3cd-ee3f319b747d","originalAuthorName":"傅元勇"}],"doi":"10.11804/NuclPhysRev.31.04.528","fpage":"528","id":"958978b5-22bc-4ca8-8c0d-4fe4289cf9d4","issue":"4","journal":{"abbrevTitle":"YZHWLPL","coverImgSrc":"journal/img/cover/YZHWLPL.jpg","id":"78","issnPpub":"1007-4627","publisherId":"YZHWLPL","title":"原子核物理评论 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"},"keywords":[{"id":"b1d05079-2b6b-47fe-bd44-a44690ae716d","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"nhcl200903020","title":"莱钢1#竖炉砖砌内衬的浇注法修补","volume":"43","year":"2009"},{"abstractinfo":"本文综述了国内外镀锌板无铬钝化技术研究现状,分别介绍了无机、有机、有机无机复合无铬钝化技术发展概况,对比分析了不同技术的优缺点.展望了无铬钝化技术未来的发展趋势,同时指出无机物与植酸的复合钝化技术,有无毒无污染、钝化膜耐蚀性好的优点,该技术将成为无铬钝化的主要发展方向之一.","authors":[{"authorName":"姜琴","id":"f7fa5541-9791-49af-8fb9-2a574e1da08c","originalAuthorName":"姜琴"},{"authorName":"李伟华","id":"714a3ec4-c126-42e1-b863-84cb70b6a7f6","originalAuthorName":"李伟华"},{"authorName":"侯保荣","id":"965f3cb9-d6b8-4018-b3fa-3eaef0b6ee0c","originalAuthorName":"侯保荣"},{"authorName":"张璐","id":"84cc4861-81b5-49d8-9d99-b614ea3f93a7","originalAuthorName":"张璐"}],"doi":"","fpage":"101","id":"232e5a55-563f-49eb-8b63-3fa34836f901","issue":"2","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"e20f42d6-21d3-429a-a59c-ce3afa7e6c4e","keyword":"无铬钝化","originalKeyword":"无铬钝化"},{"id":"a475e8be-65fc-4942-857d-1510a5d1eb22","keyword":"六价铬","originalKeyword":"六价铬"},{"id":"09580887-41c1-40a8-9c4a-4de331d98d57","keyword":"三价铬","originalKeyword":"三价铬"},{"id":"a448fa7f-2df4-4bc9-95d0-44c1f3509f99","keyword":"耐蚀性","originalKeyword":"耐蚀性"},{"id":"a4326ce5-f6ab-4565-830e-7edca9b61e3a","keyword":"植酸","originalKeyword":"植酸"},{"id":"efb3ba47-c26d-4596-976b-06424898fedb","keyword":"转化膜","originalKeyword":"转化膜"}],"language":"zh","publisherId":"fsyfh201302001","title":"镀锌板无铬钝化技术进展","volume":"34","year":"2013"},{"abstractinfo":"本文介绍了用\"电流平衡法”带电测量耦合电容器的电容量Cx和介质损耗因素tanδx,与停电测量结果比较,具有操作简便,易于推广,测试结果准确的优点.","authors":[{"authorName":"叶振捷","id":"d9c1c00c-7107-4e75-8201-97f02324ffbb","originalAuthorName":"叶振捷"},{"authorName":"张璐","id":"8b29d043-0db2-41b5-a6a4-cee97d01e87f","originalAuthorName":"张璐"}],"doi":"10.3969/j.issn.1009-9239.2001.04.010","fpage":"38","id":"2afbd4e2-82d8-43ed-87df-d239a42cd488","issue":"4","journal":{"abbrevTitle":"JYCL","coverImgSrc":"journal/img/cover/JYCL.jpg","id":"50","issnPpub":"1009-9239","publisherId":"JYCL","title":"绝缘材料"},"keywords":[{"id":"6d3b12df-2fd7-40e8-bd7f-4b113b0b0001","keyword":"耦合电容器","originalKeyword":"耦合电容器"},{"id":"311b40ef-9ba2-40b8-8d9e-82e3fb4bc4c9","keyword":"带电测试","originalKeyword":"带电测试"},{"id":"acbe10bf-a037-484f-8bcf-235e83bd5592","keyword":"电容量","originalKeyword":"电容量"},{"id":"8c4ccf0e-125e-4dfe-a194-700b8e613e7f","keyword":"介质损耗","originalKeyword":"介质损耗"}],"language":"zh","publisherId":"jycltx200104010","title":"带电测量耦合电容器电容量和介损的方法研究","volume":"34","year":"2001"},{"abstractinfo":"利用二次氧化法制备了多孔阳极氧化铝模板,通过控制电位聚合技术在阳极氧化铝模板内组装了聚苯胺纳米线阵列.采用扫描电子显微镜、透射电子显微镜和能谱仪等检测技术对填孔过程和阵列的形貌、结构进行分析和表征.结果表明,苯胺在纳米孔中的聚合过程经历四个阶段,填孔终止时间控制为第二阶段结束时间.阳极氧化铝模板中苯胺聚合适宜的电位为1.0V,pH为2.5.聚苯胺纳米线的直径均匀,约为70 nm,与模板孔径基本一致,为非晶结构.","authors":[{"authorName":"张璐","id":"ceacbc8d-e25e-45aa-8b5e-54abd707a420","originalAuthorName":"张璐"},{"authorName":"姚素薇","id":"fae758ad-bbd3-4863-9136-d7b7e3d70a46","originalAuthorName":"姚素薇"},{"authorName":"梁学磊","id":"0161ea89-7587-4caa-9c3b-c382ca11a9da","originalAuthorName":"梁学磊"},{"authorName":"张圆圆","id":"c7cfb887-25fb-41b2-992f-f6e42346a170","originalAuthorName":"张圆圆"}],"doi":"10.3969/j.issn.1001-3849.2013.07.001","fpage":"1","id":"2f537a52-c750-4a75-a9be-8b5a4ec322eb","issue":"7","journal":{"abbrevTitle":"DDYJS","coverImgSrc":"journal/img/cover/DDYJS.jpg","id":"20","issnPpub":"1001-3849","publisherId":"DDYJS","title":"电镀与精饰 "},"keywords":[{"id":"0dee387d-1c6f-49dd-a78d-fc98dea114e4","keyword":"阳极氧化铝模板","originalKeyword":"阳极氧化铝模板"},{"id":"a6bf56af-e711-440d-b486-02fba51eb7d9","keyword":"恒电位聚合法","originalKeyword":"恒电位聚合法"},{"id":"fc0a5765-51c6-4426-a93e-ce2654b41f91","keyword":"聚苯胺","originalKeyword":"聚苯胺"},{"id":"4dc3bb8c-3db0-4e7c-ae2a-ccb15836d267","keyword":"纳米线阵列","originalKeyword":"纳米线阵列"}],"language":"zh","publisherId":"ddjs201307001","title":"聚苯胺纳米线阵列的电化学组装研究","volume":"35","year":"2013"},{"abstractinfo":"盾构机在城市地铁、铁路公路交通、能源输送、地下通道等重大工程中的应用日益广泛,具有开挖速度快、施工质量高、劳动强度低、经济、环保等优点.作为盾构机关键部件之一的盾构刀具相当于盾构机的牙齿,是实现盾构机掘进功能的主要部件.国内盾构刀具产业经过近二十年的发展,在刀具材料、刀具集成制造等方面获得重要的技术突破,目前基本实现了盾构刀具的国产化,并形成了一定产业化规模,可满足市场上各种进口及国产盾构机的刀具需求.本文从盾构刀具的应用、设计开发、产业发展等方面对我国盾构刀具产业现状进行了评述,并指出未来五年中国基础设施建设仍处于高速发展阶段,盾构市场前景广阔,要做大做强盾构刀具产业,必须加强自主创新、突破核心技术,实现智能化制造.","authors":[{"authorName":"张忠健","id":"d92187b3-44fc-4728-8e41-637df391ab7d","originalAuthorName":"张忠健"},{"authorName":"张璐","id":"70a78740-821c-41da-9c0c-55761b485caf","originalAuthorName":"张璐"},{"authorName":"贺军","id":"7f2dbb20-2012-463c-8989-451752f9da41","originalAuthorName":"贺军"},{"authorName":"吴湘伟","id":"09395001-1604-46d1-b0ce-021fde49df51","originalAuthorName":"吴湘伟"}],"doi":"10.3969/j.issn.1003-7292.2015.05.010","fpage":"340","id":"56ea052c-b91e-42aa-8b5a-c7f6c2e5ec8d","issue":"5","journal":{"abbrevTitle":"YZHJ","coverImgSrc":"journal/img/cover/YZHJ.jpg","id":"75","issnPpub":"1003-7292","publisherId":"YZHJ","title":"硬质合金"},"keywords":[{"id":"8e347093-2a7c-49d4-9d97-7507ab0eebce","keyword":"盾构刀具","originalKeyword":"盾构刀具"},{"id":"3937bcec-dba1-453e-914a-668bdba4ce88","keyword":"盾构","originalKeyword":"盾构"},{"id":"18b0d438-c497-4172-8080-98b5c13de048","keyword":"产业发展","originalKeyword":"产业发展"}],"language":"zh","publisherId":"yzhj201505010","title":"盾构刀具产业现状及发展","volume":"32","year":"2015"},{"abstractinfo":"建立二维近壁面汽泡生长模型,研究过冷度,壁面过热度,壁面物性,接触角,核化点尺寸等因素对汽泡生长的影响.本文建立的汽泡生长模型在低壁面过热度条件下趋近于微液层蒸发控制的汽泡生长模型,在高壁面过热度条件下趋近于无限过热液体中传热控制球形汽泡生长模型.","authors":[{"authorName":"张璐","id":"338de84e-d414-4d05-9913-4c44c7027ad8","originalAuthorName":"张璐"},{"authorName":"柯道友","id":"356f7cce-df78-4287-9c93-a952e9836b29","originalAuthorName":"柯道友"}],"doi":"","fpage":"281","id":"60195557-4aaa-419b-b562-b58223ecab8e","issue":"2","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报 "},"keywords":[{"id":"bd33ddb4-0251-46f6-8588-8c8d26f5a7a5","keyword":"核态沸腾","originalKeyword":"核态沸腾"},{"id":"a698b808-f5d0-4065-b407-b976c44df68f","keyword":"汽泡生长","originalKeyword":"汽泡生长"},{"id":"78546d4d-5a01-4600-a49a-b2f3fc89993b","keyword":"过冷度","originalKeyword":"过冷度"},{"id":"eb89f2e5-c3ca-40eb-a2b9-cb4bc4202c96","keyword":"接触角","originalKeyword":"接触角"}],"language":"zh","publisherId":"gcrwlxb200802026","title":"微重力核态沸腾近壁面汽泡生长模型","volume":"29","year":"2008"},{"abstractinfo":"以陶瓷纤维纸为基材,经水玻璃浸渍及锌盐的酸性水解沉积,制备出新型高吸附性能锌掺杂硅胶吸附材料.用扫描电子显微镜、红外光谱仪和比表面积分析仪等对产物进行了表征,并考察了浸渍时间、浸渍温度、锌盐含量、外加酸含量以及反应温度等制备条件对材料吸附水性能的影响.SEM结果表明,制得的吸附材料中,锌掺杂硅胶微粒较均匀地分布在陶瓷纤维表面及孔隙中;FT-IR谱在波数829cm-1附近的特征吸收峰表明,锌掺杂硅胶中存在Zn-O-Si键.与普通硅胶相比,锌掺杂硅胶吸附材料的吸附水性能明显提高.制备锌掺杂硅胶吸附材料的优化条件为浸渍时间为60min,浸渍温度20℃,锌盐含量30%,反应温度60℃,外加浓盐酸的量为1.5mL.","authors":[{"authorName":"刘登卫","id":"7e6f5665-4142-495e-a258-c8069a5e44fa","originalAuthorName":"刘登卫"},{"authorName":"贺拥军","id":"5b4ca8d2-14ef-4184-9f06-1779c5ef3d29","originalAuthorName":"贺拥军"},{"authorName":"张超","id":"60538ead-1d25-48b0-9364-0aad0cf300fd","originalAuthorName":"张超"},{"authorName":"张璐","id":"a2e57691-5c3b-461e-8f2b-034b8c199ea4","originalAuthorName":"张璐"}],"doi":"","fpage":"721","id":"6ae41627-40cc-4523-9311-d6891cfcdcc0","issue":"z4","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"312aa4f0-868d-4df7-93be-d43209ec76a5","keyword":"锌掺杂硅胶","originalKeyword":"锌掺杂硅胶"},{"id":"469622a7-96d0-4f74-8f58-1dfbd2640f75","keyword":"吸附材料","originalKeyword":"吸附材料"},{"id":"854fb09f-68e3-469c-a262-a45cf2418642","keyword":"浸渍","originalKeyword":"浸渍"},{"id":"1e638afa-5650-43f0-afaa-601c4545f9b2","keyword":"水解","originalKeyword":"水解"},{"id":"33bb45a8-8f43-4899-a21d-6a1ea32be5ae","keyword":"吸附性能","originalKeyword":"吸附性能"}],"language":"zh","publisherId":"gncl2011z4036","title":"锌掺杂硅胶吸附材料的制备与性能研究","volume":"42","year":"2011"},{"abstractinfo":"介绍了近年来复合材料层合板分层疲劳模型、数值模拟、以及Ⅰ型Ⅱ型和混合型分层疲劳性能试验的研究进展,并对复合材料层合板分层疲劳性能进一步的研究进行了展望.","authors":[{"authorName":"陈春露","id":"6f84fcc3-b67b-4a85-b038-5119d473603b","originalAuthorName":"陈春露"},{"authorName":"刘文博","id":"14f6712f-3ebc-4f3e-9d7d-1b644949ba99","originalAuthorName":"刘文博"},{"authorName":"张璐","id":"68bf550b-f169-4346-8564-37d80a2e9bf1","originalAuthorName":"张璐"},{"authorName":"王荣国","id":"99ebe67d-dc7c-4625-a01c-28aeee0b4732","originalAuthorName":"王荣国"},{"authorName":"隋晓东","id":"ae85194a-6222-47de-8745-f9052228b672","originalAuthorName":"隋晓东"},{"authorName":"郑达","id":"d628ecd8-6482-430b-873c-32b2e3f52118","originalAuthorName":"郑达"}],"doi":"10.3969/j.issn.1003-0999.2012.01.017","fpage":"83","id":"7b96ea71-f3dc-45c6-80fa-9a5d31e9442e","issue":"1","journal":{"abbrevTitle":"BLGFHCL","coverImgSrc":"journal/img/cover/BLGFHCL.jpg","id":"6","issnPpub":"1003-0999","publisherId":"BLGFHCL","title":"玻璃钢/复合材料"},"keywords":[{"id":"09dd2d4c-dcb1-4409-bfe4-a8be1e67d8a4","keyword":"复合材料层合板","originalKeyword":"复合材料层合板"},{"id":"7b057227-6e04-418a-9056-83f85b7a02c6","keyword":"分层","originalKeyword":"分层"},{"id":"6ad50d2b-6f8e-4d86-a31d-399eced2fa37","keyword":"疲劳","originalKeyword":"疲劳"},{"id":"78719260-7a44-4f10-921d-cfed08ad2d8b","keyword":"模型","originalKeyword":"模型"},{"id":"ecf12603-cf77-49ad-8259-783d056097e6","keyword":"模拟","originalKeyword":"模拟"},{"id":"df9d5b96-8e5c-45bd-83c7-84d5d66184a3","keyword":"Ⅰ型","originalKeyword":"Ⅰ型"},{"id":"53920d79-99ab-4fe1-a4b9-e8f65e4e316a","keyword":"Ⅱ型","originalKeyword":"Ⅱ型"},{"id":"fecff841-38e4-4097-b531-fc2520a67256","keyword":"混合型","originalKeyword":"混合型"}],"language":"zh","publisherId":"blgfhcl201201017","title":"复合材料层合板分层疲劳性能研究进展","volume":"","year":"2012"}],"totalpage":4,"totalrecord":32}