{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"通过电镀法制备了用于催化分解高浓度过氧化氢的银网催化剂,采用过氧化氢预处理的方法对其初始催化性能进行了改进. 结果表明,采用90%过氧化氢预处理可明显提高银网催化剂的初始活性,扫描电子显微镜和X射线光电子能谱表征结果显示90%过氧化氢预处理后的银网催化剂表面形成了大量1 μm的沟壑并有Ag2O的生成,这是其性能提高的主要原因.","authors":[{"authorName":"周志江","id":"0892c996-44b5-487f-894d-a6725fcd6340","originalAuthorName":"周志江"},{"authorName":"王晓东","id":"e8cd1deb-7cc1-49c1-988a-58d76ee8d719","originalAuthorName":"王晓东"},{"authorName":"<span style=\"color:red\">单</span><span style=\"color:red\">继</span><span style=\"color:red\">宏</span>","id":"d7fb903f-d2bd-4ddd-b2cf-64ce9b92a7e5","originalAuthorName":"单继宏"},{"authorName":"丛昱","id":"92e79d88-1426-426d-ac15-19325d3eba7b","originalAuthorName":"丛昱"},{"authorName":"杨小峰","id":"16e652cc-32f7-4fd6-8708-ebea989986a9","originalAuthorName":"杨小峰"},{"authorName":"张涛","id":"31dec3c3-171d-4728-89cb-9b305a9e8c53","originalAuthorName":"张涛"}],"doi":"","fpage":"957","id":"61db44ae-b24b-401a-a893-34582ce2ecad","issue":"11","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报   "},"keywords":[{"id":"4c8ae519-e3fc-4161-8aaf-a1e2b35bf00e","keyword":"过氧化氢","originalKeyword":"过氧化氢"},{"id":"81b5c3fc-a368-4196-8b8b-f462f49632b4","keyword":"分解","originalKeyword":"分解"},{"id":"27ff1c2c-31c5-48de-bd67-68a6a3ad7d41","keyword":"银网催化剂","originalKeyword":"银网催化剂"},{"id":"60f5e1f2-0db9-4b90-9510-9b842d728023","keyword":"预处理","originalKeyword":"预处理"}],"language":"zh","publisherId":"cuihuaxb200611007","title":"预处理条件对高浓度过氧化氢分解用银网催化剂初始活性的影响","volume":"27","year":"2006"},{"abstractinfo":"以SBA-15为载体,采用后修饰法制备了Ag/SBA-15催化剂.XRD和TEM结果表明,金属Ag粒子均匀分散于SBA-15的纳米孔道中,粒子平均大小为4～5 nm.同时,负载金属Ag纳米粒子后,载体的介孔结构仍然能很好地保持.CO催化氧化测试结果表明,Ag/SBA-15具有很高的催化活性,120℃时就能使CO完全氧化.而在富H2气氛下,80℃时CO的转化率达到最大值(48%),此时O2的选择性为28%.高温H2还原是活化Ag/SBA-15的必要步骤.","authors":[{"authorName":"涂彩华","id":"86cd2ed8-2f32-4ffd-b286-5159dbe7052b","originalAuthorName":"涂彩华"},{"authorName":"王爱琴","id":"d2a67696-c77a-4fa0-96ee-4fb9d5ac520d","originalAuthorName":"王爱琴"},{"authorName":"郑明远","id":"35402fd4-f2fc-4753-bb49-ede6e2dad959","originalAuthorName":"郑明远"},{"authorName":"孟云","id":"f1929454-5aa7-4f23-ba24-c49c921d6b65","originalAuthorName":"孟云"},{"authorName":"<span style=\"color:red\">单</span><span style=\"color:red\">继</span><span style=\"color:red\">宏</span>","id":"e5e088c9-6283-4844-9a3a-c94e9b2cdae5","originalAuthorName":"单继宏"},{"authorName":"张涛","id":"7c07c6db-637f-4e6e-b8e3-9ff7b2576da8","originalAuthorName":"张涛"}],"doi":"","fpage":"631","id":"b94773bd-a31c-4cef-8778-c6726832c3c6","issue":"8","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报   "},"keywords":[{"id":"124b24d7-4bbb-4324-9b43-175b7f4419da","keyword":"银","originalKeyword":"银"},{"id":"acbbddf4-b8a0-40c2-9fbe-ce5c46fca875","keyword":"纳米粒子","originalKeyword":"纳米粒子"},{"id":"43eb0b65-29d8-424b-b4ac-df80b3df9089","keyword":"SBA-15","originalKeyword":"SBA-15"},{"id":"437272d7-e56b-4bc5-98cb-b1cbb5fdf468","keyword":"一氧化碳","originalKeyword":"一氧化碳"},{"id":"bed0fc93-19c5-453c-96fb-2f507c6e7542","keyword":"催化氧化","originalKeyword":"催化氧化"}],"language":"zh","publisherId":"cuihuaxb200508003","title":"一种新的高活性CO氧化催化剂Ag/SBA-15","volume":"26","year":"2005"},{"abstractinfo":"用电化学测试手段分别测定了20钢、2Cr13、QAl 9-2、QAl 10-3-1.5和QAl 10-4-4等5种材料在NaCl溶液中的腐蚀电位及与QAl 9-2偶接时的电偶腐蚀电流的变化,并对测试后各试样的腐蚀状态进行了观察.结果表明,铝青铜材料的抗腐蚀性比钢好.其中QAl 10-4-4的腐蚀电位最为偏正,但它与QAl 9-2配副会对QAl 9-2产生较大的阳极电偶腐蚀;QAl 9-2和QAl 10-3-1.5材料与QAl 9-2配副均有较好的耐电偶腐蚀性能.研究结果对<span style=\"color:red\">继</span>动器壳体材料的选择具有指导意义.","authors":[{"authorName":"孙瑜珉","id":"51e99317-d6bf-431c-9a6f-c3d6f4585354","originalAuthorName":"孙瑜珉"},{"authorName":"王艳滨","id":"c2914604-7d17-4b6a-a81d-8cc5caf4d1cc","originalAuthorName":"王艳滨"},{"authorName":"翟文杰","id":"d72a5d12-baa0-4d59-8f4d-a3da259c0a08","originalAuthorName":"翟文杰"}],"doi":"10.3969/j.issn.1003-1545.2003.02.008","fpage":"22","id":"99ca24e2-000b-494d-b1a3-2134704d4fce","issue":"2","journal":{"abbrevTitle":"CLKFYYY","coverImgSrc":"journal/img/cover/CLKFYYY.jpg","id":"10","issnPpub":"1003-1545","publisherId":"CLKFYYY","title":"材料开发与应用"},"keywords":[{"id":"cd50c162-3395-4884-8f0c-416f8e837441","keyword":"电化学","originalKeyword":"电化学"},{"id":"b3ff1209-0319-4d41-92df-0b3d22d367b8","keyword":"腐蚀电位","originalKeyword":"腐蚀电位"},{"id":"0f5918e1-888f-46b7-b83d-8685b3cd2270","keyword":"腐蚀电流","originalKeyword":"腐蚀电流"}],"language":"zh","publisherId":"clkfyyy200302008","title":"船用<span style=\"color:red\">继</span>动器壳体材料的腐蚀性能分析","volume":"18","year":"2003"},{"abstractinfo":"采用砂土作为模拟土壤，通过失重法及电化学方法，研究了土壤盐浓差Ａ３钢的<span style=\"color:red\">宏</span>电池民腐蚀的影响规律。结果表明位于高盐土壤中的试样试验初期为<span style=\"color:red\">宏</span>电池阳极，而在第５天发生了极性逆转。　","authors":[{"authorName":"孙成","id":"fad53d26-8b5f-49e0-833b-04d86bc59f07","originalAuthorName":"孙成"},{"authorName":"李洪锡","id":"d9c6adad-694f-4c0f-bfe1-7b10d99e9dec","originalAuthorName":"李洪锡"},{"authorName":"张淑泉等","id":"318f7173-1276-4af4-93d0-409b388c169f","originalAuthorName":"张淑泉等"}],"categoryName":"|","doi":"","fpage":"101","id":"95a0908c-96bd-4cf5-8373-77ba2eda5a34","issue":"2","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报（英文）"},"keywords":[{"id":"b0cf9065-4aea-40fc-8ba6-085cd4197a44","keyword":"碳钢","originalKeyword":"碳钢"},{"id":"a7ec12b9-aed6-44bf-bdc3-43ea8e43cfc8","keyword":"salt concernation in soil","originalKeyword":"salt concernation in soil"},{"id":"eaa98ff4-1a71-47df-8ad0-8680ec9b8d8e","keyword":"macrocell cornion","originalKeyword":"macrocell cornion"}],"language":"zh","publisherId":"1002-6495_2000_2_5","title":"土壤盐浓差<span style=\"color:red\">宏</span>电池对碳钢的腐蚀","volume":"12","year":"2000"},{"abstractinfo":"采用砂土作为模拟土壤,通过失重法及电化学方法,研究了土壤盐浓差对A3钢的<span style=\"color:red\">宏</span>电池腐蚀的影响规律.结果表明位于高盐土壤中的试样试验初期为<span style=\"color:red\">宏</span>电池阳极,而在第5 天发生了极性逆转.","authors":[{"authorName":"孙成","id":"6de82a3c-7871-46f6-80e2-4cd3ede997d0","originalAuthorName":"孙成"},{"authorName":"李洪锡","id":"5178d6b7-b30b-4d5f-abb8-36d24e0c2d27","originalAuthorName":"李洪锡"},{"authorName":"张淑泉","id":"9ec4e07e-1a37-46ee-a419-15611c940a62","originalAuthorName":"张淑泉"},{"authorName":"高立群","id":"a0520bef-d3fb-41f6-9480-1511ae90f247","originalAuthorName":"高立群"}],"doi":"10.3969/j.issn.1002-6495.2000.02.010","fpage":"101","id":"9584052e-0be4-4bd0-b182-6d32766f1812","issue":"2","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报（英文）"},"keywords":[{"id":"94335ec0-11e8-4b6a-ab8e-a8be9b6685e3","keyword":"碳钢","originalKeyword":"碳钢"},{"id":"98b42eb4-64b9-4a06-a5ce-a907f37ee9b2","keyword":"土壤盐浓差","originalKeyword":"土壤盐浓差"},{"id":"1189b6f3-4a3d-4c81-9f5b-3376383c26dd","keyword":"<span style=\"color:red\">宏</span>电池腐蚀","originalKeyword":"宏电池腐蚀"}],"language":"zh","publisherId":"fskxyfhjs200002010","title":"土壤盐浓差<span style=\"color:red\">宏</span>电池对碳钢的腐蚀","volume":"12","year":"2000"},{"abstractinfo":"采用电化学测试和扫描电子显微镜等技术对模拟硫酸型酸雨作用下X70钢土壤<span style=\"color:red\">宏</span>电池腐蚀进行研究.结果表明,X70钢在酸化后土壤中腐蚀电位较负,成为<span style=\"color:red\">宏</span>电池阳极,从而受到加速作用.<span style=\"color:red\">宏</span>电池阴阳极面积比增大,<span style=\"color:red\">宏</span>电池阳极的腐蚀速率也增大.当<span style=\"color:red\">宏</span>电池阴阳极面积比1∶1时,<span style=\"color:red\">宏</span>电池腐蚀强度系数γ为4.32;当<span style=\"color:red\">宏</span>电池阴阳极面积比15∶1时,<span style=\"color:red\">宏</span>电池腐蚀强度系数γ则达到18.29.","authors":[{"authorName":"王欣","id":"7e0f5555-421b-4572-ab11-47c90aa4d447","originalAuthorName":"王欣"},{"authorName":"许进","id":"8efdacda-3892-4fb1-87c4-2ba2ea633be0","originalAuthorName":"许进"},{"authorName":"孙成","id":"db6bb14a-61c2-4864-aff5-653272ba57ca","originalAuthorName":"孙成"},{"authorName":"王福会","id":"355be2fb-8dd8-4c76-ae32-00482b45d125","originalAuthorName":"王福会"}],"doi":"","fpage":"5","id":"adcffd4f-6af5-4d2d-921a-2a3313a59e0d","issue":"1","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"51b70f32-7c1c-400f-b53f-a9f3b832d438","keyword":"模拟硫酸型酸雨","originalKeyword":"模拟硫酸型酸雨"},{"id":"607e33be-78aa-4f53-af4b-4cf590f9f9db","keyword":"X70钢","originalKeyword":"X70钢"},{"id":"524a95cc-4e85-42c5-8571-266ba81616e7","keyword":"<span style=\"color:red\">宏</span>电池腐蚀","originalKeyword":"宏电池腐蚀"},{"id":"9c30813d-04f5-49fe-899c-70ea575dcfe0","keyword":"土壤","originalKeyword":"土壤"},{"id":"d3f0263a-a255-412e-80d7-37610a06458e","keyword":"腐蚀强度系数","originalKeyword":"腐蚀强度系数"}],"language":"zh","publisherId":"fsyfh201301002","title":"模拟硫酸型酸雨作用下的X70钢土壤<span style=\"color:red\">宏</span>电池腐蚀","volume":"34","year":"2013"},{"abstractinfo":"本文探讨一种适用于复合材料<span style=\"color:red\">宏</span>细观间跨尺度分析的细观元方法.细观元法在结构的常规有限元内部设置密集细观单元以反映材料细观构造,又通过协调条件将各细观元结点自由度转换为同一常规有限元自由度,再上机计算.此方法可实现材料细观结构到构件宏观响应的直接过渡分析,而计算单元与自由度又等同一般常规有限元,为解决具有细观结构新材料与构件跨尺度分析提供一种新的有力工具.本文给出用于<span style=\"color:red\">宏</span>细观跨尺度分析细观元法的基本原理与算式,并以纤维增强复合材料和功能梯度复合材料为例介绍其工程应用.","authors":[{"authorName":"王华宁","id":"266224b2-8e7d-4839-990b-c01a62e75706","originalAuthorName":"王华宁"},{"authorName":"曹志远","id":"9b098c6e-f065-40a7-9487-5eae6ab5ef50","originalAuthorName":"曹志远"},{"authorName":"程红梅","id":"23d489fb-3951-4785-ba08-34f7050bd443","originalAuthorName":"程红梅"},{"authorName":"付志平","id":"a91349cd-ec91-42e1-b4a8-1b85589d46a5","originalAuthorName":"付志平"}],"doi":"10.3969/j.issn.1003-0999.2006.06.001","fpage":"3","id":"9ee4517b-aabc-45b2-90a7-dddf9c17790e","issue":"6","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":"d54efe84-e28b-4a22-917c-e54440855bfd","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"e3ed01dc-ffec-4865-9ed2-4c4600a03ae9","keyword":"跨尺度分析","originalKeyword":"跨尺度分析"},{"id":"1c7c3b1d-4a22-4b94-841e-8a2e09a0bfbc","keyword":"细观元法","originalKeyword":"细观元法"}],"language":"zh","publisherId":"blgfhcl200606001","title":"复合材料构件<span style=\"color:red\">宏</span>细观跨尺度分析","volume":"","year":"2006"},{"abstractinfo":"在实验室中通过模拟装置对Q235钢在土壤中的<span style=\"color:red\">宏</span>电池腐蚀行为进行了研究.结果表明,饱和/非饱和土壤环境的差异对金属的<span style=\"color:red\">宏</span>电池腐蚀具有决定性的作用;土壤的电阻率可以影响<span style=\"color:red\">宏</span>电池的电流分布.","authors":[{"authorName":"高立群","id":"53ba4774-c0b8-40b7-823e-77ef806b4f77","originalAuthorName":"高立群"},{"authorName":"李洪锡","id":"c5bd9149-887e-48dc-9192-4fca7b24e4dd","originalAuthorName":"李洪锡"},{"authorName":"孙成","id":"9c38d662-02aa-4c44-9931-dff5ad5448ff","originalAuthorName":"孙成"},{"authorName":"张淑泉","id":"21939267-8a35-412b-ae7d-bd3584819d96","originalAuthorName":"张淑泉"}],"doi":"10.3969/j.issn.1005-748X.2000.01.004","fpage":"12","id":"af178b23-7628-4fa2-a6f1-0276a4f3f1eb","issue":"1","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"418b0aba-1250-4260-92e7-e31615cc2be4","keyword":"土壤腐蚀","originalKeyword":"土壤腐蚀"},{"id":"6d3000a8-e51a-493a-9c94-a797d35478f0","keyword":"<span style=\"color:red\">宏</span>电池腐蚀","originalKeyword":"宏电池腐蚀"},{"id":"a7ec575f-208c-46eb-8e4e-1b8fb5ed4a47","keyword":"Q235钢","originalKeyword":"Q235钢"}],"language":"zh","publisherId":"fsyfh200001004","title":"Q235钢在土壤中<span style=\"color:red\">宏</span>电池腐蚀行为的研究","volume":"21","year":"2000"},{"abstractinfo":"利用极化曲线、电化学阻抗、扫描电镜和表面能谱等方法,研究了硫酸盐还原菌对X70钢在土壤中<span style=\"color:red\">宏</span>电池腐蚀的影响.结果表明,接菌或灭菌粘土和砂土组成的<span style=\"color:red\">宏</span>电池,砂土中试样为<span style=\"color:red\">宏</span>电池的阴极,粘土中试样为阳极；随实验时间的增加,接菌及灭菌粘土中自然埋藏X70钢腐蚀速率逐渐减小,而砂土中<span style=\"color:red\">宏</span>电池阳极的腐蚀速率一直相当高；接菌土壤<span style=\"color:red\">宏</span>电池的电流和电动势比灭菌的大,接菌及灭菌粘土中阳极的腐蚀速率分别是自然腐蚀速率的4.93和2.45倍；在<span style=\"color:red\">宏</span>电池阴阳极面积比15∶1情况下,接菌及灭菌粘土中<span style=\"color:red\">宏</span>电池阳极的腐蚀速率分别为<span style=\"color:red\">宏</span>电池阴阳极面积比11时的5.01及2.33倍.","authors":[{"authorName":"伍远辉","id":"3360dfcc-966d-427e-88ef-c88c7da3cf6b","originalAuthorName":"伍远辉"},{"authorName":"孙成","id":"7e954ce6-8329-40d0-9737-9dcc93f83b47","originalAuthorName":"孙成"},{"authorName":"勾华","id":"9976c10c-84a2-48d6-95f4-536a7b3d3e0d","originalAuthorName":"勾华"}],"categoryName":"|","doi":"","fpage":"98","id":"94a7098f-c6d5-4000-beab-73e726119d7f","issue":"2","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报（英文）"},"keywords":[{"id":"a363a45b-2eaf-48cc-adc1-cdba9aad92c7","keyword":"硫酸盐还原菌","originalKeyword":"硫酸盐还原菌"},{"id":"fa1b9bab-0bee-4853-a086-67f6d70b26f5","keyword":"null","originalKeyword":"null"},{"id":"ab114aa5-873c-4f8e-aa59-34be419b840e","keyword":"null","originalKeyword":"null"},{"id":"0eed7156-ebd5-48a2-a2e3-e1d8b3e2defe","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"1002-6495_2007_2_14","title":"硫酸盐还原菌对X70钢土壤<span style=\"color:red\">宏</span>电池腐蚀的影响","volume":"19","year":"2007"},{"abstractinfo":"利用极化曲线、电化学阻抗、扫描电镜和表面能谱等方法,研究了硫酸盐还原菌对X70钢在土壤中<span style=\"color:red\">宏</span>电池腐蚀的影响.结果表明,接菌或灭菌粘土和砂土组成的<span style=\"color:red\">宏</span>电池,砂土中试样为<span style=\"color:red\">宏</span>电池的阴极,粘土中试样为阳极;随实验时间的增加,接菌及灭菌粘土中自然埋藏X70钢腐蚀速率逐渐减小,而砂土中<span style=\"color:red\">宏</span>电池阳极的腐蚀速率一直相当高;接菌土壤<span style=\"color:red\">宏</span>电池的电流和电动势比灭菌的大,接菌及灭菌粘土中阳极的腐蚀速率分别是自然腐蚀速率的4.93和2.45倍;在<span style=\"color:red\">宏</span>电池阴阳极面积比15∶1情况下,接菌及灭菌粘土中<span style=\"color:red\">宏</span>电池阳极的腐蚀速率分别为<span style=\"color:red\">宏</span>电池阴阳极面积比1∶1时的5.01及2.33倍.","authors":[{"authorName":"伍远辉","id":"89474cf1-7316-4f27-a996-250a47d3cb1d","originalAuthorName":"伍远辉"},{"authorName":"孙成","id":"3c794e0e-7af2-4fc1-a272-e7bcb411081c","originalAuthorName":"孙成"},{"authorName":"勾华","id":"1497de99-2481-4659-9f4c-40eef303dfcf","originalAuthorName":"勾华"}],"doi":"10.3969/j.issn.1002-6495.2007.02.006","fpage":"98","id":"38642e0c-f12a-401c-a7b0-daa2fa662b00","issue":"2","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报（英文）"},"keywords":[{"id":"4fb4c93b-b4ba-45c2-a5d8-7aa0f296d906","keyword":"硫酸盐还原菌","originalKeyword":"硫酸盐还原菌"},{"id":"ff6d0436-225b-4989-a795-ff580b7eb0c0","keyword":"X70钢","originalKeyword":"X70钢"},{"id":"ddd5734d-c364-419c-b0a7-5a948d4bda9b","keyword":"<span style=\"color:red\">宏</span>电池","originalKeyword":"宏电池"},{"id":"47f73327-9665-4572-a104-dbde0d4dc1e9","keyword":"腐蚀","originalKeyword":"腐蚀"}],"language":"zh","publisherId":"fskxyfhjs200702006","title":"硫酸盐还原菌对X70钢土壤<span style=\"color:red\">宏</span>电池腐蚀的影响","volume":"19","year":"2007"}],"totalpage":640,"totalrecord":6395}