{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"比较了5种不同管径碳纳米管的电化学储氢能力.采用三电极体系,Ni(OH)2/NiOOH为对电极,CNTs-Ni(质量比为1:9)为工作电极,Hg/HgO为参比电极,30%的KOH作为电解液.实验结果显示:在同等制作条件和200mA/g的充放电电流密度,0.1V的放电终了电压下,10～30nm的碳管储氢能力最好,克容量最大为480.6mAh/g,相应的平台电压高达0.92V;20～40nm的最高克容量为430.5mAh/g,仅低于10～30nm的电化学储氢量.10～20nm、40～60nm和60～100nm碳管的电化学储氢量分别是:401.1mAh/g、384.7mAh/g和298.3mAh/g.由此可见碳纳米管的管径大小也是影响其电化学储氢性能的一大因素.<span style=\"color:red\">纯</span>镍电极在同等条件下的最高放电量只有17.8mAh/g,对整个电极放电量的影响可以忽略不计.","authors":[{"authorName":"付小娟","id":"4d7be9d0-3910-4866-a585-808e28b486c7","originalAuthorName":"付小娟"},{"authorName":"张海燕","id":"8e78f1e6-cfbe-4660-af66-efc4746f1499","originalAuthorName":"张海燕"},{"authorName":"<span style=\"color:red\">周</span><span style=\"color:red\">纯</span>","id":"3440ce1f-cab6-407d-a6c2-bd1ae4fdcf68","originalAuthorName":"周纯"},{"authorName":"尹建峰","id":"2387c8a6-aab9-4baf-926f-1221df558f0c","originalAuthorName":"尹建峰"},{"authorName":"李明华","id":"6f081e6a-8318-4e38-9d70-58ce9900a515","originalAuthorName":"李明华"}],"doi":"","fpage":"117","id":"0bb6104e-a2dd-4dac-91ad-c949fa8acbfd","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":"3569adf8-207d-420c-a035-7e99d4dabe95","keyword":"碳纳米管","originalKeyword":"碳纳米管"},{"id":"35417410-0b89-47be-80e9-322ae6f80311","keyword":"电化学储氢","originalKeyword":"电化学储氢"},{"id":"2505f51e-fd15-45d7-94df-90d1b52d226a","keyword":"克容量","originalKeyword":"克容量"},{"id":"39be5ac8-daec-4663-a1a5-eb9ee2470e73","keyword":"CNTs-Ni电极","originalKeyword":"CNTs-Ni电极"}],"language":"zh","publisherId":"cldb200510031","title":"不同管径碳纳米管电化学储氢性能的比较","volume":"19","year":"2005"},{"abstractinfo":"用微米级SiO2、Si和碳黑混合粉末为原料, 以氮气为反应气,采用碳热还原法合成了氮化硅纳米粉体.测量了300～1273K退火温度下纳米氮化硅的电子自旋共振(ESR)谱,研究了测量温度、纳米氮化硅退火温度对ESR谱线型、g因子、线宽的影响.结果证实退火影响纳米氮化硅的磁性.","authors":[{"authorName":"洪军","id":"20059754-46ee-444d-b074-77661fb7a33b","originalAuthorName":"洪军"},{"authorName":"何艳阳","id":"7e12501e-1b66-45a9-a1ce-5f2b9881827d","originalAuthorName":"何艳阳"},{"authorName":"钟韶","id":"475cbd1a-8c12-40d7-9481-91cc83a5fb98","originalAuthorName":"钟韶"},{"authorName":"张海燕","id":"589489a6-859d-4ce4-9383-2893b7b14f43","originalAuthorName":"张海燕"},{"authorName":"薛新民","id":"71444e6a-6a5d-42c3-9435-6df2b0886a63","originalAuthorName":"薛新民"},{"authorName":"<span style=\"color:red\">周</span><span style=\"color:red\">纯</span>","id":"20dffa4c-2feb-45c5-a88f-ac11abf875d0","originalAuthorName":"周纯"},{"authorName":"陈进","id":"84840af8-de77-43ac-a385-2d7db0352eb2","originalAuthorName":"陈进"},{"authorName":"陈易明","id":"9899d710-2b0d-4e35-9d6a-564e5b3474b7","originalAuthorName":"陈易明"}],"doi":"10.3969/j.issn.1000-985X.2005.04.037","fpage":"744","id":"2249cd93-0cb1-46d6-98ed-0ba46bfa8b24","issue":"4","journal":{"abbrevTitle":"RGJTXB","coverImgSrc":"journal/img/cover/RGJTXB.jpg","id":"57","issnPpub":"1000-985X","publisherId":"RGJTXB","title":"人工晶体学报"},"keywords":[{"id":"e32b9ef7-45a3-47f4-a323-db9d2a072419","keyword":"纳米氮化硅","originalKeyword":"纳米氮化硅"},{"id":"c8209a0d-d13f-4aa4-8e3d-d9cd8b3f9581","keyword":"电子自旋共振","originalKeyword":"电子自旋共振"},{"id":"2a0d40f0-9bca-4866-a3a4-3707292ddf4e","keyword":"碳还原","originalKeyword":"碳还原"},{"id":"0f2c82d2-df97-45ed-b297-03746380ecf7","keyword":"退火","originalKeyword":"退火"}],"language":"zh","publisherId":"rgjtxb98200504037","title":"真空退火处理对纳米氮化硅电子自旋共振谱的影响","volume":"34","year":"2005"},{"abstractinfo":"利用真空扩散焊方法制备了铜中间层钛-钢焊接接头,并采用OM、SEM、EDS、显微硬度和拉伸试验方法,研究了铜中间层钛-钢扩散复合界面组织和性能。结果表明,Fe、Ti原子在界面处发生了互扩散,钛侧形成α-βTi＋αTi或βTi＋α-βTi＋αTi组织,钢侧发生脱碳并形成柱状晶组织;拉伸强度随扩散温度升高呈现先增加后减小的趋势,950℃、30 min扩散试样拉伸强度最高,达到262 MPa;拉伸断口具有塑性断裂区与脆性断裂区特征,并在断口上检测出TiC相。","authors":[{"authorName":"刘德义","id":"dbc91812-0ab6-42f9-b318-f18477261a06","originalAuthorName":"刘德义"},{"authorName":"<span style=\"color:red\">周</span><span style=\"color:red\">纯</span>","id":"f9009308-810b-4a47-9d79-0be2e503e3d5","originalAuthorName":"周纯"},{"authorName":"丛立军","id":"f095568a-c684-4ad2-b87c-af0221cd4fff","originalAuthorName":"丛立军"},{"authorName":"刘世程","id":"4066b64a-0ced-4492-a87a-f8fc65af4f51","originalAuthorName":"刘世程"}],"doi":"","fpage":"105","id":"e1add6a2-39d1-45c3-9f2e-86282f311ee8","issue":"4","journal":{"abbrevTitle":"CLRCLXB","coverImgSrc":"journal/img/cover/CLRCLXB.jpg","id":"15","issnPpub":"1009-6264","publisherId":"CLRCLXB","title":"材料热处理学报"},"keywords":[{"id":"8b4dff6e-f1a5-4e05-b2d1-b109681c380f","keyword":"钛-钢","originalKeyword":"钛-钢"},{"id":"85e90212-abc9-445e-98f4-5a3ff0e1e257","keyword":"扩散复合","originalKeyword":"扩散复合"},{"id":"78683362-68a4-4dca-806b-38feecb7db74","keyword":"铜中间层","originalKeyword":"铜中间层"},{"id":"2fa5bc08-c4bd-4514-86fe-fd59f50180c1","keyword":"组织与性能","originalKeyword":"组织与性能"}],"language":"zh","publisherId":"jsrclxb201204022","title":"铜中间层钛-钢扩散复合界面组织与性能","volume":"33","year":"2012"},{"abstractinfo":"报告一种研制的低温固化高温使用树脂体系Xufyg-44.用它成型复合材料层压制件时,固化温度低于70 ℃,最终固化产物的玻璃化转变温度高于200 ℃,浇注体力学性能以及复合材料制件在整个固化周期中的尺寸稳定性良好.","authors":[{"authorName":"汪少敏","id":"0b58a32d-8701-4edf-b37f-80a1e9a93008","originalAuthorName":"汪少敏"},{"authorName":"过梅丽","id":"a06828bd-b3e4-4019-a29e-2b4145676354","originalAuthorName":"过梅丽"},{"authorName":"殷立新","id":"6693bb6b-24c0-4550-a253-0c9694bd4db6","originalAuthorName":"殷立新"},{"authorName":"<span style=\"color:red\">周</span><span style=\"color:red\">纯</span>","id":"6686d4fc-4c82-4959-b89e-903d95341b31","originalAuthorName":"周纯"}],"doi":"10.3321/j.issn:1000-3851.2002.02.005","fpage":"28","id":"ca75de52-d29f-4585-9f43-40bba2788586","issue":"2","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":"e1dad743-ceca-47a2-9c24-991f8dc99ee8","keyword":"低温固化高温使用","originalKeyword":"低温固化高温使用"},{"id":"77f3d5a5-8e8a-41f6-b550-ae049cd78787","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"5a39f9b0-457d-437d-b5bc-ceb5f4aef12c","keyword":"热变形","originalKeyword":"热变形"}],"language":"zh","publisherId":"fhclxb200202005","title":"LTM树脂及其复合材料的初步研究","volume":"19","year":"2002"},{"abstractinfo":"测量了工业<span style=\"color:red\">纯</span>钛低<span style=\"color:red\">周</span>疲劳的应力—应变响应,选择动态模量DM与弹性模量EM之比值DM·EM1衡量材料的相对“软”“硬”程度发现在各个应变幅下DM·EM1有向0.35～0.40靠近的趋势讨论了新的参量DM·EM1与循环硬化及循环软化之间的关系","authors":[{"authorName":"张哲峰","id":"ff89860f-9636-4d78-b6c3-b339d8bc2a0c","originalAuthorName":"张哲峰"},{"authorName":"谭晓礼","id":"113d860b-d7ba-4689-9c55-d625dbb9d19f","originalAuthorName":"谭晓礼"},{"authorName":"顾海澄","id":"91c56ad6-c5b6-4b8a-9455-dcaf0ea4ab97","originalAuthorName":"顾海澄"}],"categoryName":"|","doi":"","fpage":"499","id":"7ffa3b77-0a67-44f3-9e8c-89405cb3124b","issue":"5","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"fc73f3d2-e1e2-483f-87d4-1c1cd989943e","keyword":"工业<span style=\"color:red\">纯</span>钛","originalKeyword":"工业纯钛"},{"id":"9686333d-6fbf-4966-8f64-24379239a976","keyword":"null","originalKeyword":"null"},{"id":"1813a62f-b5ac-41d8-9dbe-c45ba611c8c7","keyword":"null","originalKeyword":"null"},{"id":"786f617e-b75a-463a-ab58-aa6027c5651a","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"1005-3093_1997_5_16","title":"工业<span style=\"color:red\">纯</span>钛低<span style=\"color:red\">周</span>疲劳应力—应变响应","volume":"11","year":"1997"},{"abstractinfo":"为了研究<span style=\"color:red\">纯</span>铜在低<span style=\"color:red\">周</span>疲劳中的温度响应与微观形貌,借助于红外热像仪及远距离高倍显微镜同步监测工业<span style=\"color:red\">纯</span>铜的表面疲劳变化,同时运用扫描电子显微镜(SEM)对试样断口进行微观分析.研究结果表明:试样表面温度的变化与表面微观形貌的变化具有明显的相关性,并受应力水平及加载频率的影响,表面最高温升与加载频率呈线性关系;试样断口出现明显的裂纹扩展区和瞬断区,且随着应力水平及加载频率的增加而形成较大的瞬断区及较多的韧窝.","authors":[{"authorName":"李娜","id":"6cb94ee1-8f55-40f1-8f00-073ce4fbc21b","originalAuthorName":"李娜"},{"authorName":"童小燕","id":"bb8f567b-ae9e-420b-b337-3749b8ef0a55","originalAuthorName":"童小燕"},{"authorName":"姚磊江","id":"c924d25f-34c9-4e6d-ab00-e39dc9510c0e","originalAuthorName":"姚磊江"}],"doi":"10.3969/j.issn.1673-2812.2006.05.031","fpage":"754","id":"1e047116-a3d0-431b-ae4a-2c07a6851ab1","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":"22228fa1-7620-4f4d-8da6-6e7d45f98d1a","keyword":"温度响应","originalKeyword":"温度响应"},{"id":"01a27352-f206-4151-b324-5866caee01d2","keyword":"微观形貌","originalKeyword":"微观形貌"},{"id":"087720a7-e61d-4ab5-ac81-a23fc02dfc42","keyword":"低<span style=\"color:red\">周</span>疲劳","originalKeyword":"低周疲劳"},{"id":"d0c478e5-47a9-4800-b93f-71a93a6dd10d","keyword":"应力水平","originalKeyword":"应力水平"},{"id":"734da31d-094c-4d00-bf70-41c2d958cf6b","keyword":"加载频率","originalKeyword":"加载频率"}],"language":"zh","publisherId":"clkxygc200605031","title":"<span style=\"color:red\">纯</span>铜低<span style=\"color:red\">周</span>疲劳中的温度响应与微观形貌变化","volume":"24","year":"2006"},{"abstractinfo":"研究了阴极下限电位和阴极半<span style=\"color:red\">周</span>时间对高<span style=\"color:red\">纯</span>铝在2mol/L HCl 溶液中三角波动电位初期的伏安特性和表面形貌的影响。随阴极下限电位的负移，阳极溶解电流快速减小，腐蚀箔表面蚀坑直径和密度明显降低；但在同一阴极下限电位时，随阴极半<span style=\"color:red\">周</span>时间的延长，阳极电流则缓慢降低。蚀坑直径无显著变化，蚀坑密度却大提高。当阴极下限电位低于-2.4V vs SCE时，阳极电流首先从一较小值逐渐增大到一最大值，然后随循环数的增加又不断减至很小，腐蚀箔表面可见蚀坑很少。实验结果表明，阴极下限电位是决定铝阳极溶解程度和表面形貌的关键因素，尽管阴极时间也发挥一定的作用；阴极析氢过程对铝的阳极点蚀具有促进和阻阻碍的双重作用。","authors":[{"authorName":"肖占文","id":"d42dc62c-fa4d-4d0c-aa0d-37027716210f","originalAuthorName":"肖占文"},{"authorName":"杨邦朝","id":"ea5b8182-0b69-4589-a41f-50a6c1577026","originalAuthorName":"杨邦朝"}],"categoryName":"|","doi":"","fpage":"193","id":"e0f7f7c3-e76a-4e7b-b815-1f1aec06d590","issue":"4","journal":{"abbrevTitle":"ZGFSYFHXB","coverImgSrc":"journal/img/cover/中国腐蚀封面19-3期-01.jpg","id":"81","issnPpub":"1005-4537","publisherId":"ZGFSYFHXB","title":"中国腐蚀与防护学报"},"keywords":[{"id":"dd7050b8-9be5-40c1-bd3a-89046b94566e","keyword":"铝","originalKeyword":"铝"},{"id":"9256428d-3283-4c7a-9495-eefed9eb6763","keyword":"AC etching","originalKeyword":"AC etching"},{"id":"57e2ab94-15ae-41ee-8697-bf748603a7c9","keyword":"cathodic potential","originalKeyword":"cathodic potential"},{"id":"7b44c7e4-6708-4748-ac55-0bbfa3a06ae3","keyword":"voltammetric characteristics","originalKeyword":"voltammetric characteristics"},{"id":"73a0223c-7067-43bb-a486-91eb9755d78f","keyword":"surface morphology","originalKeyword":"surface morphology"}],"language":"zh","publisherId":"1005-4537_1999_4_3","title":"交流负半<span style=\"color:red\">周</span>对高<span style=\"color:red\">纯</span>铝在盐酸溶液中点蚀行为的影响","volume":"19","year":"1999"},{"abstractinfo":"论述了超高<span style=\"color:red\">周</span>疲劳研究的背景及意义,总结了近年来超高<span style=\"color:red\">周</span>疲劳的研究成果包括超高<span style=\"color:red\">周</span>疲劳的典型特征如S-N曲线、裂纹起源、起裂机理、影响超高<span style=\"color:red\">周</span>疲劳行为的因素等,介绍了超高<span style=\"color:red\">周</span>疲劳的常用实验手段,提出了今后超高<span style=\"color:red\">周</span>疲劳研究的课题.","authors":[{"authorName":"关昕","id":"0ac19842-8b56-426f-8905-2388e7a25b47","originalAuthorName":"关昕"},{"authorName":"孟延军","id":"58d24d51-0717-4882-bcd8-6c2afb28dd18","originalAuthorName":"孟延军"}],"doi":"","fpage":"58","id":"e4637bac-c1ab-4be4-843c-0b2fc9d06e80","issue":"1","journal":{"abbrevTitle":"GTYJ","coverImgSrc":"journal/img/cover/GTYJ.jpg","id":"29","issnPpub":"1001-1447","publisherId":"GTYJ","title":"钢铁研究"},"keywords":[{"id":"fc7ed857-e1c0-43de-9636-ad6114993fd8","keyword":"超高<span style=\"color:red\">周</span>疲劳","originalKeyword":"超高周疲劳"},{"id":"10ad3e45-0a4e-4eb7-9a69-588ccacf882e","keyword":"S-N曲线","originalKeyword":"S-N曲线"},{"id":"8217367e-ada6-4836-a546-fc39c08018ab","keyword":"疲劳裂纹萌生","originalKeyword":"疲劳裂纹萌生"},{"id":"6ef2ce57-4acd-4632-a6d5-c41726a86dba","keyword":"超声疲劳实验","originalKeyword":"超声疲劳实验"}],"language":"zh","publisherId":"gtyj200901018","title":"超高<span style=\"color:red\">周</span>疲劳的研究进展","volume":"37","year":"2009"},{"abstractinfo":"研究了不同温度下TC17合金低<span style=\"color:red\">周</span>疲劳性能和断口形貌,确定了不同温度下合金低<span style=\"color:red\">周</span>疲劳曲线的数学表达式,分析了合金棒材低<span style=\"color:red\">周</span>疲劳断口形貌特征.","authors":[{"authorName":"张翥","id":"08f7ef9f-76b4-43b4-a22c-5e4c97332d9c","originalAuthorName":"张翥"},{"authorName":"惠松骁","id":"95300b8b-74b1-4a44-9a99-d5da348d9ace","originalAuthorName":"惠松骁"},{"authorName":"路纲","id":"b4d1bce2-6620-453b-ab68-5919f79cf6a5","originalAuthorName":"路纲"}],"doi":"10.3321/j.issn:0412-1961.2002.z1.079","fpage":"267","id":"5245b7d9-ad01-42aa-96ae-965e18ec3e68","issue":"z1","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"1ab386e7-9137-42ac-932c-aad72f085293","keyword":"低<span style=\"color:red\">周</span>疲劳","originalKeyword":"低周疲劳"},{"id":"707dc835-b982-4d1a-8bac-aaf2daa1a891","keyword":"断口形貌","originalKeyword":"断口形貌"},{"id":"84cd2432-b6a6-470a-93bc-ec98a918a3b5","keyword":"TC17钛合金","originalKeyword":"TC17钛合金"}],"language":"zh","publisherId":"jsxb2002z1079","title":"TC17合金低<span style=\"color:red\">周</span>疲劳性能与低<span style=\"color:red\">周</span>疲劳断口形貌","volume":"38","year":"2002"},{"abstractinfo":"对高<span style=\"color:red\">周</span>疲劳和低<span style=\"color:red\">周</span>疲劳寿命预测模型进行了研究,提出了一种能够将高<span style=\"color:red\">周</span>疲劳和低<span style=\"color:red\">周</span>疲劳统一表征的能量形式参量.用统一的能量形式表征参量对高温合金GH141的760℃高<span style=\"color:red\">周</span>疲劳和低<span style=\"color:red\">周</span>疲劳数据进行处理,得到理想的能量-寿命方程.用1Cr11Ni2W2MoV钢500℃和粉末盘材料FGH95的600℃高温低<span style=\"color:red\">周</span>疲劳和高<span style=\"color:red\">周</span>疲劳数据对统一表征方法进行验证,验证结果表明,用能量形式的表征参量能够得到理想的能量-寿命方程.","authors":[{"authorName":"许超","id":"b736c564-a712-4cae-ba28-e1f545e3fbee","originalAuthorName":"许超"},{"authorName":"张国栋","id":"1c3a219e-8948-44a2-ac77-d7a1db019a04","originalAuthorName":"张国栋"},{"authorName":"苏彬","id":"115a0fbf-8817-41cd-8719-b1cf173341c4","originalAuthorName":"苏彬"}],"doi":"10.3969/j.issn.1001-4381.2007.08.016","fpage":"65","id":"90ae7451-07db-49d8-bc65-8529908ec2cb","issue":"8","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"fa75e230-7af7-47c8-af9d-3a42d6a0957a","keyword":"高<span style=\"color:red\">周</span>疲劳","originalKeyword":"高周疲劳"},{"id":"fff773bd-ef31-49d2-a540-5c0587429d8e","keyword":"低<span style=\"color:red\">周</span>疲劳","originalKeyword":"低周疲劳"},{"id":"7e70aa0a-f69e-49d8-90a4-c7e78e1e84d8","keyword":"寿命预测","originalKeyword":"寿命预测"},{"id":"120f5885-b123-425d-9772-e00834ea620b","keyword":"能量表征","originalKeyword":"能量表征"},{"id":"2778e939-7c24-4364-bc09-9b7d01d11edf","keyword":"高温合金","originalKeyword":"高温合金"}],"language":"zh","publisherId":"clgc200708016","title":"高<span style=\"color:red\">周</span>疲劳和低<span style=\"color:red\">周</span>疲劳统一的能量表征方法研究","volume":"","year":"2007"}],"totalpage":924,"totalrecord":9236}