{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"","authors":[{"authorName":"","id":"8b1472b5-9804-41ac-9446-b549620afe9a","originalAuthorName":""},{"authorName":"","id":"0b75cd30-8270-401a-b284-e8cdc713c1cd","originalAuthorName":""},{"authorName":"","id":"8f1b3e7a-e791-44a5-8fc6-d3535700a39d","originalAuthorName":""}],"doi":"","fpage":"59","id":"d1c37eb7-9600-4dc4-aa74-dec4e345d9a3","issue":"12","journal":{"abbrevTitle":"GTYJXBYWB","coverImgSrc":"journal/img/cover/GTYJXBEN.jpg","id":"1","issnPpub":"1006-706X","publisherId":"GTYJXBYWB","title":"钢铁研究学报(英文版)"},"keywords":[{"id":"8c5d1d2e-dce1-4d14-b0a1-f5a66ef5cbaf","keyword":"腐蚀产物","originalKeyword":"腐蚀产物"},{"id":"147fd538-e0b9-4da7-9b93-5df520f34bd8","keyword":"CO2含量","originalKeyword":"CO2含量"},{"id":"a9dd43c4-43aa-4928-a6a6-0cebddc03b84","keyword":"行为环境","originalKeyword":"行为环境"},{"id":"ef5c76f5-a9b8-45e4-b1b3-36e75182eee8","keyword":"H2S","originalKeyword":"H2S"},{"id":"f03bcd92-1242-43cf-b8e8-3bfe26ade949","keyword":"管钢","originalKeyword":"管钢"},{"id":"185be2bc-159a-442d-826f-c3ea168e13d7","keyword":"X射线衍射技术","originalKeyword":"X射线衍射技术"},{"id":"74230dbf-4421-4c01-98a4-f8d8d287fb91","keyword":"扫描电子显微镜","originalKeyword":"扫描电子显微镜"},{"id":"4e1eb92b-b982-400e-b28c-197142d42bbb","keyword":"CO2分压","originalKeyword":"CO2分压"}],"language":"zh","publisherId":"gtyjxb-e201212010","title":"Corrosion Behavior of 110S Tube Steel in Environments of High H2S and CO2 Content","volume":"19","year":"2012"},{"abstractinfo":"采用慢应变速率试验(SSRT)研究了不同电位下X70管线钢在近中性pH溶液中的应力腐蚀破裂(SCC)行为,同时研究了溶液中通入不同含量CO2对SCC的影响.结果表明,X70管线钢在近中性pH溶液中的开裂方式是穿晶型的,具有准解理特征,并且随着外加阴极电位的降低,SCC敏感性增加;随CO2含量的增加,pH值降低,SCC敏感性增加.均表现为氢致开裂占主导.","authors":[{"authorName":"郭浩","id":"3358590a-3838-431e-8869-7a7bd2c9daf7","originalAuthorName":"郭浩"},{"authorName":"李光福","id":"5192f283-bf57-421c-ba9f-07d250e5f15a","originalAuthorName":"李光福"},{"authorName":"蔡珣","id":"275f2ac8-8347-438a-a237-a27de66b4210","originalAuthorName":"蔡珣"},{"authorName":"周建江","id":"3b399fca-7be2-4e76-a74d-972bc7ce27fa","originalAuthorName":"周建江"},{"authorName":"黄春波","id":"e5326131-c86b-4988-8449-96b30c324359","originalAuthorName":"黄春波"},{"authorName":"杨武","id":"57287665-7085-4653-930d-a800ee46bef7","originalAuthorName":"杨武"}],"doi":"10.3969/j.issn.1005-4537.2004.04.004","fpage":"208","id":"05377a0a-8bab-4bd1-a9b9-b0b90c22de2b","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":"0a4ea6a6-5ac1-4251-8d1e-91eb47730849","keyword":"管线钢","originalKeyword":"管线钢"},{"id":"d46db001-001e-4996-986d-5291d8620023","keyword":"应力腐蚀破裂","originalKeyword":"应力腐蚀破裂"},{"id":"26dcbd80-fdcf-40a4-8db6-01f1fc9ec9cd","keyword":"近中性pH","originalKeyword":"近中性pH"},{"id":"b0aa3783-503d-4c11-b7c0-281268704954","keyword":"电位","originalKeyword":"电位"},{"id":"ea4dd3cf-902d-445a-ba56-97ec35803c44","keyword":"CO2含量","originalKeyword":"CO2含量"}],"language":"zh","publisherId":"zgfsyfhxb200404004","title":"外加电位对X70管线钢在近中性pH溶液中的应力腐蚀破裂的影响","volume":"24","year":"2004"},{"abstractinfo":"为有效地控制温室效应和气候剧变,准确可靠地监测CO2气体的变化就变得十分重要.拉曼雷达测量大气中CO2气体含量是一种技术先进的可靠方法.介绍了利用气体的拉曼散射效应来测量CO2含量分布的拉曼激光雷达,分析了拉曼雷达的基本原理,设计了具体的实验检测系统,介绍了实验系统各工作件参数情况.对拉曼雷达的回波信号的反演方法进行了具体阐述,初步取得了大气中CO2气体含量分布规律,合肥地区的二氧化碳气体含量大约在350~400 ppmv范围内波动.","authors":[{"authorName":"赵曰峰","id":"fc57f3d6-6132-4224-8c1f-bebde64c85db","originalAuthorName":"赵曰峰"},{"authorName":"张寅超","id":"a8f235a1-1e4b-4042-8b0f-1cc64ffb3c4d","originalAuthorName":"张寅超"},{"authorName":"洪光烈","id":"57399167-615e-48d6-ba04-fe192b520eaf","originalAuthorName":"洪光烈"},{"authorName":"赵培涛","id":"0d0cbbbf-7d61-4089-aa2c-8424700b77c2","originalAuthorName":"赵培涛"},{"authorName":"苏嘉","id":"08a7ca99-e85f-495d-be61-84ca0953d900","originalAuthorName":"苏嘉"},{"authorName":"谢军","id":"1611ca72-f733-495d-9907-cc81c91d1c26","originalAuthorName":"谢军"},{"authorName":"方欣","id":"1b147112-ee5f-4b48-94f5-e622d20698e2","originalAuthorName":"方欣"},{"authorName":"刘玉丽","id":"716a19c6-031c-48ae-9a92-47d139eb93fb","originalAuthorName":"刘玉丽"},{"authorName":"屈凯峰","id":"858812b7-351f-45ef-9b59-ecc76b322118","originalAuthorName":"屈凯峰"}],"doi":"10.3969/j.issn.1007-5461.2006.03.016","fpage":"355","id":"8d438910-171a-47a7-913c-b944de2a94ee","issue":"3","journal":{"abbrevTitle":"LZDZXB","coverImgSrc":"journal/img/cover/LZDZXB.jpg","id":"53","issnPpub":"1007-5461","publisherId":"LZDZXB","title":"量子电子学报 "},"keywords":[{"id":"36dad117-f925-4b97-b045-97885abdf94a","keyword":"激光技术","originalKeyword":"激光技术"},{"id":"3ad769be-51b6-4533-8e87-9bdc55c89b40","keyword":"二氧化碳气体","originalKeyword":"二氧化碳气体"},{"id":"67a1b70f-39d7-485e-af30-01ad5a2724ec","keyword":"拉曼激光雷达","originalKeyword":"拉曼激光雷达"},{"id":"bdef1702-0352-4b84-a4b0-869c3fbc7248","keyword":"信号反演","originalKeyword":"信号反演"}],"language":"zh","publisherId":"lzdzxb200603016","title":"大气CO2含量分布激光雷达监测","volume":"23","year":"2006"},{"abstractinfo":"采用高温高压反应釜和电化学方法研究Cr含量对管线钢抗CO2腐蚀性能的影响, 并运用扫描电镜及能谱分析腐蚀产物膜形貌及成分. 结果表明, 管线钢添加少量的Cr元素可使其在CO2腐蚀环境中形成结构致密的富Cr腐蚀产物膜, 显著提高其抗CO2腐蚀性能. 随Cr含量提高, 管线钢平均腐蚀速率下降, 抗局部腐蚀能力提高; 而且随Cr含量提高, 管线钢自腐蚀电位向正方向偏移, 极化电阻增大, 抗CO2腐蚀性能提高, 与平均腐蚀速率分析结果一致.","authors":[{"authorName":"胡丽华","id":"8cb3c93c-39bf-44a4-8f6a-db24561262b0","originalAuthorName":"胡丽华"},{"authorName":"俞曼丽","id":"e5066678-81cd-4e21-b6ee-b23c16a6004f","originalAuthorName":"俞曼丽"},{"authorName":"常炜","id":"7ae843a8-e372-4fe7-8daa-017d90795d58","originalAuthorName":"常炜"},{"authorName":"张雷","id":"f9a9ff3c-0a11-4d61-9833-6c6695769208","originalAuthorName":"张雷"},{"authorName":"许立宁","id":"2cfe43fb-04de-47df-8b1d-59779284501e","originalAuthorName":"许立宁"},{"authorName":"路民旭","id":"984825d6-9205-4d13-9586-12cef6692657","originalAuthorName":"路民旭"}],"categoryName":"|","doi":"","fpage":"256","id":"4c6b207f-05c2-42f5-8f67-e184df50d996","issue":"3","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":"1a0b986c-c84f-4e0c-aecb-9a736a4734bb","keyword":"低合金管线钢","originalKeyword":"低合金管线钢"},{"id":"87eb2abc-1550-490e-a173-ee12dca0f4fc","keyword":"Cr content","originalKeyword":"Cr content"},{"id":"5680b289-59ad-47f1-8601-ec3025bd09db","keyword":"CO$_{2$-induced corrosion","originalKeyword":"CO$_{2$-induced corrosion"}],"language":"zh","publisherId":"1002-6495_2011_3_13","title":"Cr含量对低合金管线钢CO2腐蚀性能的影响","volume":"23","year":"2011"},{"abstractinfo":"采用高温高压反应釜和电化学方法研究Cr含量对管线钢抗CO2腐蚀性能的影响,并运用扫描电镜及能谱分析腐蚀产物膜形貌及成分.结果表明,管线钢添加少量的Cr元素可使其在CO2腐蚀环境中形成结构致密的富Cr腐蚀产物膜,显著提高其抗CO2腐蚀性能.随Cr含量提高,管线钢平均腐蚀速率下降,抗局部腐蚀能力提高;而且随Cr含量提高,管线钢自腐蚀电位向正方向偏移,极化电阻增大,抗CO2腐蚀性能提高,与平均腐蚀速率分析结果一致.","authors":[{"authorName":"胡丽华","id":"b391ba4b-093c-4d55-ab7c-f816e5a65460","originalAuthorName":"胡丽华"},{"authorName":"俞曼丽","id":"1c15f38a-4bfc-4381-a7a8-d735fdc063b8","originalAuthorName":"俞曼丽"},{"authorName":"常炜","id":"6035aae8-80ca-4fd0-b6e6-2e8af74d3d42","originalAuthorName":"常炜"},{"authorName":"张雷","id":"d67a9a55-dcdd-4233-beb2-612f173534a5","originalAuthorName":"张雷"},{"authorName":"许立宁","id":"32bb5bfc-02bb-4e83-add0-9705a4c4b09c","originalAuthorName":"许立宁"},{"authorName":"路民旭","id":"5b5abf7e-f020-45d2-90b6-a56ceb2ed13a","originalAuthorName":"路民旭"}],"doi":"","fpage":"256","id":"93e496b9-a996-418f-a725-6aa59f810e58","issue":"3","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":"fd027010-c0fc-426f-9550-2a1f56b339cd","keyword":"低合金管线钢","originalKeyword":"低合金管线钢"},{"id":"83917a68-c925-4dff-b67f-65b79582cdc5","keyword":"Cr含量","originalKeyword":"Cr含量"},{"id":"9e0fa3c3-81c1-4b1e-9907-9521e70b0a16","keyword":"CO2腐蚀","originalKeyword":"CO2腐蚀"}],"language":"zh","publisherId":"fskxyfhjs201103012","title":"Cr含量对低合金管线钢CO2腐蚀性能的影响","volume":"23","year":"2011"},{"abstractinfo":"1-氨丙基-3-甲基咪唑溴([APMim]Br)功能型离子液体对CO2具有良好的选择吸收特性,在二氧化碳吸收工程领域将有较好的应用前景.对于[APMim]Br离子液体水溶液体系,只有当水含量足够大才能有效地实现流体对CO2的有效吸收,而且在有效吸收区间(水含量大于55%)水含量多少对溶液体系CO2吸收效率有着非常显著的影响.为此在密闭石英玻璃反应釜内,测定5~75℃,0.1~7.6 MPa范围内,CO2在水的质量分数ω(H2O)为0.5590、0.6578、0.7680和0.8576的[APMim]Br水溶液中的溶解特性.实验结果表明,低压下化学吸收占主导作用,随水含量增大,溶液体系对CO2溶解度成倍增加,而且产生的物理吸收效应远大于离子液体本身的化学吸收能力.在水的质量分数在0.65~0.85区间,[APMim]Br水溶液在相当大的温度和压力范围内具有优良的CO2吸放气特性,显示出良好的工程应用前景.","authors":[{"authorName":"李松","id":"bbcb099a-dcd4-48db-ac2a-c66558af305e","originalAuthorName":"李松"},{"authorName":"杨翠莲","id":"a1564046-97a5-474f-b347-d78c61800f8f","originalAuthorName":"杨翠莲"},{"authorName":"毕崟","id":"52a95205-2994-4269-bfc1-9b19f887c280","originalAuthorName":"毕崟"},{"authorName":"郭开华","id":"305573a6-d790-4516-bee5-460fe07a5044","originalAuthorName":"郭开华"}],"doi":"","fpage":"1407","id":"5be140ed-3544-46c5-bbf7-dc374b5ff0e5","issue":"7","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":"dba08fd6-41c3-45e6-8478-7d95e7321d39","keyword":"离子液体","originalKeyword":"离子液体"},{"id":"1968bb70-5706-4c3d-8b9b-ad208a89c9a9","keyword":"水溶液","originalKeyword":"水溶液"},{"id":"be1663f1-7ade-400f-9a31-210d731c9935","keyword":"水浓度","originalKeyword":"水浓度"},{"id":"b34774e9-700f-48d6-8f55-0214872d844d","keyword":"二氧化碳","originalKeyword":"二氧化碳"},{"id":"4cbc35d4-972f-45ba-922a-e06d8735098c","keyword":"溶解度","originalKeyword":"溶解度"}],"language":"zh","publisherId":"gcrwlxb201507005","title":"[APMim]Br离子液体溶液水含量对CO2溶解度影响","volume":"36","year":"2015"},{"abstractinfo":"采用失重、扫描电镜(SEM)、电子能谱(EDS)等方法研究了316L,13Cr以及3Cr3三种不同铬含量管线钢材质在模拟集输系统CO2腐蚀环境中腐蚀行为.结果表明,在模拟气、液相腐蚀环境中,316L发生轻度腐蚀,13Cr发生中度腐蚀,3Cr发生极严重腐蚀,13Cr发生了Cl-点蚀.3种材料耐蚀性依次为316L> 13Cr> 3Cr.推荐选用316L内衬复合管作为雅克拉气田集输管线抗腐蚀综合治理材料.","authors":[{"authorName":"李明","id":"0741f301-a6e8-45ea-9cf3-df16f439c3b6","originalAuthorName":"李明"},{"authorName":"胡志兵","id":"7c2db90a-2cf3-431b-9e83-575cde7d56f9","originalAuthorName":"胡志兵"},{"authorName":"杨刚","id":"c55229f7-e4ce-448f-8252-e676d60612ed","originalAuthorName":"杨刚"},{"authorName":"吴成均","id":"062710d7-a132-4712-8a0b-e8d7167cb850","originalAuthorName":"吴成均"}],"doi":"","fpage":"586","id":"f8229a80-23c4-42e8-97b1-84eac6ef316a","issue":"7","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"75750b97-3ed9-4f97-b394-9e7824163d47","keyword":"雅克拉","originalKeyword":"雅克拉"},{"id":"2a5a7d44-1ef9-451d-b3f3-623c1f2b0bf9","keyword":"含Cr管线钢","originalKeyword":"含Cr管线钢"},{"id":"417fd5ed-742b-4d16-b250-236f5a90143f","keyword":"CO2腐蚀","originalKeyword":"CO2腐蚀"},{"id":"426a0fcf-2249-4962-8698-479eebce922e","keyword":"腐蚀行为","originalKeyword":"腐蚀行为"},{"id":"7d3c3972-8a49-4292-8d24-73e50dffce01","keyword":"点蚀","originalKeyword":"点蚀"}],"language":"zh","publisherId":"fsyfh201307009","title":"3种不同铬含量管线钢的CO2腐蚀行为","volume":"34","year":"2013"},{"abstractinfo":"采用高温高压反应釜和电化学技术对含1%(质量分数)Cr管线钢焊接接头的CO2腐蚀行为进行研究,目的在于揭示Cr含量和组织对焊接接头抗CO2性能的影响.结果表明,Cr含量较高的焊缝区,腐蚀产物膜出现Cr元素富集,膜较其他区域更厚更致密,抗CO2腐蚀性能更佳.而Cr含量相同、组织不同的热影响区和母材,腐蚀产物膜特征相似.对于含1%Cr管线钢焊接接头,抗CO2腐蚀性能起主要作用的是Cr含量而非组织.电化学测试表明,在CO2腐蚀介质中焊接接头的母材区域易作为阳极首先发生腐蚀,焊缝和热影响区作为阴极得到保护.","authors":[{"authorName":"胡丽华","id":"0def27e7-b624-4bc3-9fec-1b25640e2a67","originalAuthorName":"胡丽华"},{"authorName":"路民旭","id":"d59aab9b-eddb-45ca-b0b2-9026b8fd403d","originalAuthorName":"路民旭"},{"authorName":"常炜","id":"d719454a-01c9-436f-ac37-ef78091a52ab","originalAuthorName":"常炜"},{"authorName":"李忠涛","id":"6f1b2e1b-86ec-4516-9941-ac8f091f4f43","originalAuthorName":"李忠涛"},{"authorName":"张雷","id":"23bd3138-30b8-40f2-a42b-58f5f48e9a8f","originalAuthorName":"张雷"},{"authorName":"许立宁","id":"a0c39312-29e1-4589-8f15-62c528967529","originalAuthorName":"许立宁"}],"doi":"10.3969/j.issn.1001-4381.2010.07.018","fpage":"82","id":"493ab0b5-e71f-45cc-a074-7b9635d791b3","issue":"7","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"b8158b72-4223-45ab-8e1e-d19aaf6c8338","keyword":"管线钢","originalKeyword":"管线钢"},{"id":"41b0f407-5777-497d-b797-b256779eb39c","keyword":"焊接接头","originalKeyword":"焊接接头"},{"id":"3d769364-bf66-409f-a091-be8bd746b343","keyword":"CO2腐蚀","originalKeyword":"CO2腐蚀"},{"id":"8e041028-838e-4812-b2f5-f0da00677362","keyword":"Cr含量","originalKeyword":"Cr含量"},{"id":"fd5fc0c3-31d2-479d-bfed-51d8013ebe36","keyword":"组织","originalKeyword":"组织"}],"language":"zh","publisherId":"clgc201007018","title":"Cr含量和组织对含1%Cr管线钢焊接接头抗CO2腐蚀性能影响","volume":"","year":"2010"},{"abstractinfo":"通过对转炉顶吹CO2的热力学分析,结合实验室模拟转炉顶吹O2+CO2混合气体试验结果,确立了CO2在转炉中应用的关键参数。得出在转炉中顶吹纯CO2虽可脱碳,但温降较大,顶吹CO2供气强度为3.0 m3/(t·min)时,钢液温降速率为15.1℃/min;通过喷吹O2+CO2混合气体可实现温度平衡,但CO2配比的最大理论比例为79.1%;随着混合气体中CO2比例增大,吹炼终点钢液碳氧积降低,当φ(CO2)∶φ(O2)=1∶1时可控碳氧积为(25~32)×10-8。","authors":[{"authorName":"万雪峰","id":"66fd5014-666b-4702-bdc7-4882a9c1e1e3","originalAuthorName":"万雪峰"},{"authorName":"曹东","id":"1e94dd82-9343-4856-bfc6-224024f0b6e3","originalAuthorName":"曹东"},{"authorName":"刘祥","id":"854e9492-03a7-4d97-b110-07e58f9b9f4b","originalAuthorName":"刘祥"},{"authorName":"朱晓雷","id":"cc6ebe59-7272-4771-90ac-ef32ca63ce74","originalAuthorName":"朱晓雷"},{"authorName":"廖相巍","id":"2ec1dd8e-4428-4d69-8fb2-7ab475c3dfa1","originalAuthorName":"廖相巍"}],"doi":"10.13228/j.boyuan.issn0449-749x.20140282","fpage":"30","id":"53faa42b-fc85-40af-bfb5-e34a32699aa5","issue":"5","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"81f577b7-b09f-4cdb-9ba4-1d8d3176f82f","keyword":"CO2","originalKeyword":"CO2"},{"id":"14e7ff72-b854-4010-82fb-1f19bf2b3b35","keyword":"转炉","originalKeyword":"转炉"},{"id":"11eed776-456f-4f65-af72-479b31265af8","keyword":"混合喷吹","originalKeyword":"混合喷吹"},{"id":"f013f5c5-6881-4fa6-8675-52868e664c71","keyword":"碳氧积","originalKeyword":"碳氧积"}],"language":"zh","publisherId":"gt201505007","title":"转炉应用CO2技术","volume":"","year":"2015"},{"abstractinfo":"分离CO2是当前能源和环境领域的最重要的课题之一.膜分离法在投资、能耗以及环境友好方面优于传统方法,文章提出了CO2分离膜的4种选择透过机制,着重论述了国内外在分离CO2膜技术方面的研究现状,介绍了本课题组在分离CO2反应选择膜方面的研究成果,并进一步探讨了分离CO2膜技术的未来发展趋势.","authors":[{"authorName":"王志","id":"5eac3bce-fe96-4d93-9b69-695416af84ef","originalAuthorName":"王志"},{"authorName":"袁芳","id":"a2e77a47-cc0a-4617-935b-9d16aa6ebd31","originalAuthorName":"袁芳"},{"authorName":"王明","id":"5f65392e-3bcb-44a7-8801-e96b6d0575e6","originalAuthorName":"王明"},{"authorName":"王纪孝","id":"bbe3b646-3db1-4b0a-bbbd-98adbbb11897","originalAuthorName":"王纪孝"},{"authorName":"王世昌","id":"95f24f9b-a1b4-4a2f-ab5a-62c802db4d22","originalAuthorName":"王世昌"}],"doi":"10.3969/j.issn.1007-8924.2011.03.003","fpage":"11","id":"246fd4b2-ec63-430c-a442-599e44c6223d","issue":"3","journal":{"abbrevTitle":"MKXYJS","coverImgSrc":"journal/img/cover/MKXYJS.jpg","id":"54","issnPpub":"1007-8924","publisherId":"MKXYJS","title":"膜科学与技术 "},"keywords":[{"id":"23005b88-0a07-44c1-a701-ff2f9513da9c","keyword":"CO2","originalKeyword":"CO2"},{"id":"5915c53b-beb1-4464-b624-af7d2e0255fa","keyword":"捕集","originalKeyword":"捕集"},{"id":"5ac041ca-3ec5-4324-82bd-30585cb25f61","keyword":"膜分离","originalKeyword":"膜分离"},{"id":"b4042cbc-2f1f-4873-9677-1d059976a82f","keyword":"选择透过机制","originalKeyword":"选择透过机制"}],"language":"zh","publisherId":"mkxyjs201103003","title":"分离CO2膜技术","volume":"31","year":"2011"}],"totalpage":9774,"totalrecord":97737}