{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"本文利用金相、电子背散射衍射（EBSD）技术结合纳米压痕仪研究了低碳微合金钢的组织转变、晶粒的晶体学取向及其纳米力学性能。试样No.1由1℃/s冷速连续冷却到室温所得组织主要是贝氏体铁素体、粒状贝氏体以及少量岛状第二相，试样No.2由1℃/s冷速连续冷却到560℃淬水所得组织主要是针状铁素体和淬水时形成的马氏体/贝氏体，其中相邻针状铁素体之间为小角晶界；其中试样No.1中粒状贝氏体的平均纳米压痕硬度与试样No.2中针状铁素体的平均纳米压痕硬度极为接近。研究发现，取向差角较小的针状铁素体组织在连续冷却过程中合并成粒状贝氏体。","authors":[{"authorName":"尚成嘉","id":"ad1d4f4b-bfc0-4b17-ad1d-3a2d4f656fd6","originalAuthorName":"尚成嘉"},{"authorName":"王学敏","id":"d7cbf51f-9045-4f58-9b7f-d1e7a62b71a3","originalAuthorName":"王学敏"},{"authorName":"周召槿","id":"b96a821a-9f5e-44a3-bc5a-477a10b7b154","originalAuthorName":"周召槿"},{"authorName":"梁鑫","id":"3c3ce9dd-c829-4976-b291-8a28b357ce9b","originalAuthorName":"梁鑫"},{"authorName":"缪成亮","id":"4a6abfaa-7417-4b65-9945-1e929dbe3eca","originalAuthorName":"缪成亮"},{"authorName":"贺信莱","id":"51bcbcbd-2cd5-4180-9198-8e8b44101a1f","originalAuthorName":"贺信莱"}],"categoryName":"|","doi":"","fpage":"287","id":"94347abd-a4bc-4ff1-a0a8-ac3513fb1535","issue":"3","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"23dc6987-ba62-4060-917e-6795320e9c24","keyword":"低碳微合金钢","originalKeyword":"低碳微合金钢"},{"id":"2ad6bc40-f8af-46e2-998c-802d8953987e","keyword":"null","originalKeyword":"null"},{"id":"e2a141b8-18db-42e7-a346-744bb54f05ef","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"0412-1961_2008_3_7","title":"Mn-Mo-Nb-B低碳微合金钢中温转变组织的演化","volume":"44","year":"2008"},{"abstractinfo":"利用金相、电子背散射衍射(EBSD)技术结合纳米压痕仪研究了低碳Mn-Mo-Nb-B微合金钢的组织转变、晶粒的晶体学取向及其纳米力学性能.由1℃/s冷速连续冷却到室温所得组织主要是贝氏体铁素体和粒状贝氏体.以1℃/s冷速连续冷却到560℃淬水所得组织为针状铁素体和淬水时形成的马氏体/贝氏体,其中相邻针状铁索体之间为小角晶界;前一试样中粒状贝氏体的平均纳米压痕硬度(2.31 GPa)与后一试样中针状铁素体的平均纳米压痕硬度(2.22 GPa)极为接近.取向差较小的针状铁素体组织在1℃/s冷速下连续冷却过程中碰撞,接合成粒状贝氏体.","authors":[{"authorName":"尚成嘉","id":"c8e71752-208f-4178-8c2b-4b8f110b844e","originalAuthorName":"尚成嘉"},{"authorName":"王学敏","id":"71f9b811-743a-4862-a2f2-23db9741f903","originalAuthorName":"王学敏"},{"authorName":"周召槿","id":"71417ea7-6e46-447f-84d3-b8877093dc2e","originalAuthorName":"周召槿"},{"authorName":"梁鑫","id":"722b805d-c283-4728-a5fc-8d26117a9b45","originalAuthorName":"梁鑫"},{"authorName":"缪成亮","id":"c7d0f8fd-0073-42e7-82bc-04802889c11d","originalAuthorName":"缪成亮"},{"authorName":"贺信莱","id":"f4eb94b9-90e1-404b-b017-1ab9c1ff3bc2","originalAuthorName":"贺信莱"}],"doi":"10.3321/j.issn:0412-1961.2008.03.006","fpage":"287","id":"c128a7d5-a7db-44ac-84b9-b6b3b17a814d","issue":"3","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"34480bf6-cd4f-44b0-bd62-dd44a040e520","keyword":"低碳微合金钢","originalKeyword":"低碳微合金钢"},{"id":"842851ee-5790-42f3-9a68-c2bb0788a09f","keyword":"针状铁素体","originalKeyword":"针状铁素体"},{"id":"f3aa5a3b-d267-4239-aac4-4b259b448308","keyword":"粒状贝氏体","originalKeyword":"粒状贝氏体"},{"id":"846da541-6b7a-41f9-a963-7e3c1ba0f558","keyword":"晶粒取向","originalKeyword":"晶粒取向"},{"id":"60d58a53-c550-490c-9585-6063f1722115","keyword":"纳米硬度","originalKeyword":"纳米硬度"}],"language":"zh","publisherId":"jsxb200803006","title":"Mn-Mo-Nb-B低碳微合金钢中温转变组织的演化","volume":"44","year":"2008"},{"abstractinfo":"利用Gleeble-3500热模拟机研究了低冷速条件下奥氏体化温度对高强度低合金钢相变组织及-20℃冲击韧性的影响.研究发现,随着奥氏体化温度的升高,显微组织由粒状贝氏体逐渐变为板条贝氏体.奥氏体化温度为1000℃时冲击韧性最佳,显微组织中马氏体/奥氏体(M/A)岛细小弥散且大角晶界密度最大.低于1000℃奥氏体化时M/A岛粗化显著,大角晶界密度较低;而高于1000℃时,虽然M/A岛细小弥散,但是大角晶界密度有所下降.动力学分析表明,随着奥氏体化温度的升高,相变起始温度逐渐下降,转变速率不断加快,较低的相变起始温度及较快的转变速率有利于M/A岛细化.所有转变过程均可分为贝氏体转变及马氏体转变两个阶段,1000℃奥氏体化时贝氏体转变分数最大,转变最完全.晶体学分析进一步显示,当M/A岛得到细化时(奥氏体化温度1000℃及1300℃),除原奥氏体晶界外,更多大角晶界来源于发生协变相变时,晶体学集合内不同Bain组之间的界面.当奥氏体化温度过高时,在粗大的奥氏体晶粒内部,集合内的相变产物由单一Bain组主导,从而导致大角晶界密度的降低及冲击韧性的下降.","authors":[{"authorName":"由洋","id":"db45cee7-f1ff-44e4-a1fe-9177ef46adb6","originalAuthorName":"由洋"},{"authorName":"王学敏","id":"96731c4e-a2fe-4f74-ae5f-cfeaf4a1cca3","originalAuthorName":"王学敏"},{"authorName":"尚成嘉","id":"8d5eeb2c-1b42-400e-8494-bbce76ca7136","originalAuthorName":"尚成嘉"}],"doi":"10.3724/SP.J.1037.2012.00305","fpage":"1290","id":"8b6384d1-6f5a-4aa7-9e5d-66018ed185ea","issue":"11","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"05180011-90dc-42e9-8769-fbad59b71211","keyword":"HSLA100钢","originalKeyword":"HSLA100钢"},{"id":"5ffe5531-81d6-4bb4-80c8-a683f126251d","keyword":"奥氏体晶粒大小","originalKeyword":"奥氏体晶粒大小"},{"id":"70caaada-9618-4393-b3a8-fdd4b0d80e47","keyword":"相变","originalKeyword":"相变"},{"id":"b362a3b5-c12e-46e3-87fe-228095026af8","keyword":"韧性","originalKeyword":"韧性"},{"id":"e09f372d-346d-46ac-8f34-139518612d63","keyword":"晶体学包","originalKeyword":"晶体学包"}],"language":"zh","publisherId":"jsxb201211002","title":"奥氏体化温度对HSLA100高强度低合金钢组织及冲击韧性的影响","volume":"48","year":"2012"},{"abstractinfo":"利用径迹显微照相技术研究了2.25Cr-1.0Mo钢以15℃/s从1320℃冷却到1000、900、800℃等温10s时硼的分布,讨论了硼的偏聚对含硼低碳钢热塑性的影响.结果表明,从高温冷却到各实验温度时,硼偏聚到奥氏体晶界,在900℃左右偏聚量最大.含硼0.00075 wt%样品晶界与晶内均未出现明显的含硼析出,含硼0.0035 wt%的样品冷却到900℃和800℃时,时,晶界与晶内出现少量含硼析出物.含硼0.0081 wt%的样品,在1000℃时,晶界和晶内均已出现大量含硼析出物,随着温度的降低,含硼析出物增多,冷却到800℃时,偏聚到晶界的硼多数已析出.分析表明添加硼后,硼偏聚到奥氏体晶界,抑制了晶界处铁素体的形核,提高了含硼钢的热塑性.","authors":[{"authorName":"赵守田","id":"573082d9-102d-4b4c-86b0-83a210bdd53f","originalAuthorName":"赵守田"},{"authorName":"吴平","id":"6e78fb72-957a-43d6-92b2-d46312cc4399","originalAuthorName":"吴平"},{"authorName":"郭爱民","id":"7530df59-280b-4ad6-bea0-343448320baa","originalAuthorName":"郭爱民"},{"authorName":"陈森","id":"63c9a063-f1ce-4963-b2a5-226b84f28134","originalAuthorName":"陈森"},{"authorName":"唐文斌","id":"f1a9d67a-de2e-485b-af53-35078378d569","originalAuthorName":"唐文斌"},{"authorName":"王学敏","id":"3e3d6228-15fa-4b68-abe5-9ad8fd51ca96","originalAuthorName":"王学敏"},{"authorName":"杨善武","id":"092d0200-6a9a-4a82-97b5-209e10c5257a","originalAuthorName":"杨善武"},{"authorName":"贺信莱","id":"e4668b08-86a5-4c51-8485-1814426b436a","originalAuthorName":"贺信莱"}],"doi":"","fpage":"85","id":"60e14b87-05b8-437f-9035-04e6ebb6f259","issue":"11","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":"e4d3be25-0ad7-46b4-aa39-7d9d35d1997a","keyword":"硼","originalKeyword":"硼"},{"id":"a9de747e-d327-4d4d-8ac5-2c9b04a05c25","keyword":"偏聚","originalKeyword":"偏聚"},{"id":"fd639f18-6a98-41c5-b0d6-30c1dc8c307c","keyword":"热塑性","originalKeyword":"热塑性"},{"id":"7516e894-140e-4c1f-ac33-3eb64ce6ccf3","keyword":"微合金钢","originalKeyword":"微合金钢"}],"language":"zh","publisherId":"jsrclxb201011017","title":"微合金钢高温热塑性低谷区硼的偏聚","volume":"31","year":"2010"},{"abstractinfo":"","authors":[{"authorName":"李秀程","id":"1f6d2376-f38f-477b-861c-7b3824ed25ca","originalAuthorName":"李秀程"},{"authorName":"尚成嘉","id":"27da5358-560c-4ac6-9f03-c4cdbf2be8c5","originalAuthorName":"尚成嘉"},{"authorName":"袁胜福","id":"e94ed6a3-1b9f-4907-b9a9-3a35cc10b2aa","originalAuthorName":"袁胜福"},{"authorName":"谢振家","id":"88bb5c24-fed2-4fdc-afdd-d0dbf6621828","originalAuthorName":"谢振家"},{"authorName":"张继武","id":"2877d55f-7356-4010-8c57-900f1e1e5dc8","originalAuthorName":"张继武"},{"authorName":"王学敏","id":"81c0ba7c-b15c-4800-a246-98c44b136bb9","originalAuthorName":"王学敏"},{"authorName":"王靖元","id":"879a9eda-0efd-4284-9974-f54c3996c135","originalAuthorName":"王靖元"},{"authorName":"张超","id":"0a05e3f8-f5c7-446e-a89b-55b95b3f336b","originalAuthorName":"张超"}],"doi":"10.3969/j.issn.1000-6826.2015.05.20","fpage":"73","id":"67f75953-c3c5-4f9b-9d14-eb8ead311498","issue":"5","journal":{"abbrevTitle":"JSSJ","coverImgSrc":"journal/img/cover/3abe017a-2574-4821-8152-4ae974ef0471.jpg","id":"47","issnPpub":"1000-6826","publisherId":"JSSJ","title":"金属世界"},"keywords":[{"id":"c57bf706-087f-4d93-84f7-13cf6451449f","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"jssj201505020","title":"新型膨胀套管材料研发及其商业前景","volume":"","year":"2015"},{"abstractinfo":"用硼径迹显微照相技术研究了超低碳微合金钢从1150℃以5℃/s冷却到850℃过程中硼晶界偏聚的形成与发展过程,测量了不同温度时硼富集因子与贫化区宽度,分析了铜元素对硼晶界偏聚的影响.结果表明:在冷却初始阶段,晶界硼偏聚量迅速增加,在1000℃左右达到最大值后,随着温度的降低,硼晶界偏聚量开始逐渐减少,在910℃左右达到最小,温度继续降低,晶界上硼的偏聚量又开始增加.实验结果还表明添加铜元素能促进硼向晶界的偏聚.","authors":[{"authorName":"赵守田","id":"aa3658f9-020e-4871-aaa5-4e749fcd6070","originalAuthorName":"赵守田"},{"authorName":"吴平","id":"52f4199a-b77c-4590-8a25-a263f588efb6","originalAuthorName":"吴平"},{"authorName":"陈森","id":"8152ee99-7358-4cd4-88ef-358a5507defd","originalAuthorName":"陈森"},{"authorName":"赵鑫","id":"ae037012-e468-4f12-adf6-d234f0bfbef3","originalAuthorName":"赵鑫"},{"authorName":"苑少强","id":"7f49d895-02c1-4260-bad7-8fd090bcc98b","originalAuthorName":"苑少强"},{"authorName":"王学敏","id":"9430950f-a86e-4cf0-83f5-7daa6d04bc72","originalAuthorName":"王学敏"},{"authorName":"杨善武","id":"38cc0f84-3f44-42a0-b87c-10885aa8eb6f","originalAuthorName":"杨善武"},{"authorName":"贺信莱","id":"e6ec5294-68e1-41d4-b8e0-38e5cd79919b","originalAuthorName":"贺信莱"}],"doi":"10.3969/j.issn.1001-4381.2009.04.002","fpage":"6","id":"b10cd1d8-1334-42a1-9bae-5d7d7379c93e","issue":"4","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"5325f436-09f0-4c28-bae0-38880ef338d1","keyword":"硼","originalKeyword":"硼"},{"id":"2e079580-3d38-4389-9d18-d599ce08ae7e","keyword":"非平衡偏聚","originalKeyword":"非平衡偏聚"},{"id":"9eae9978-db59-4071-8c35-f47cfb67ded3","keyword":"铜","originalKeyword":"铜"}],"language":"zh","publisherId":"clgc200904002","title":"超低碳微合金钢中硼的偏聚","volume":"","year":"2009"},{"abstractinfo":"本文报道了用改进的垂直气相法(多级提纯垂直气相法)生长富Cd的CdSe单晶体，并对晶体的性能进行了观测，其电阻率为107Ωcm量级，电子陷阱浓度为108cm-3量级，第一次报道了(110)面的腐蚀形貌。结果表明：采用这种方法制备CdSe单晶，设备简单，易于操作，在提纯和生长过程中不需要转移原料，有利于减少晶体中的杂质含量，降低位错密度，改善晶体的电学性能。多级提纯垂直气相法是一种有前途的CdSe单晶体生长的新方法。","authors":[{"authorName":"邵双运","id":"050c4e2e-057a-4456-8400-b61a2da45a4a","originalAuthorName":"邵双运"},{"authorName":"金应荣","id":"a2d375c1-1948-4f1f-b9ef-4d3f0dc1ae7b","originalAuthorName":"金应荣"},{"authorName":"朱世富","id":"8f27c916-aebc-45ce-ab7d-ecd4c84a4678","originalAuthorName":"朱世富"},{"authorName":"赵北君","id":"4cd7321d-85c9-4413-8c19-97af187e03f1","originalAuthorName":"赵北君"},{"authorName":"宋芳","id":"42ec7bc3-41c3-4d77-8d92-da3e0c77f882","originalAuthorName":"宋芳"},{"authorName":"王学敏","id":"aac13a2c-ba62-4e32-bf39-9d7ffd7f1724","originalAuthorName":"王学敏"},{"authorName":"朱兴华","id":"e1304834-65b8-4f9e-a770-f9838c02af98","originalAuthorName":"朱兴华"}],"doi":"10.3969/j.issn.1000-985X.2001.02.002","fpage":"119","id":"a9152630-4272-4949-a626-254327bfaceb","issue":"2","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":"c67c97bb-f285-4920-9f2a-574219219919","keyword":"CdSe单晶体","originalKeyword":"CdSe单晶体"},{"id":"a83a6871-d03b-45f5-8cc7-50169bffbd28","keyword":"多级提纯","originalKeyword":"多级提纯"},{"id":"7574cde3-f798-43ff-b93e-f9a908cd7069","keyword":"气相生长","originalKeyword":"气相生长"},{"id":"162b0c0b-bb14-4b29-9c72-23e5eb577a25","keyword":"电阻率","originalKeyword":"电阻率"}],"language":"zh","publisherId":"rgjtxb98200102002","title":"CdSe单晶体的生长及其特性研究","volume":"30","year":"2001"},{"abstractinfo":"通过热模拟实验研究了HTP X80管线钢的晶粒细化与组织控制的工艺要点,确定了奥氏体再结晶温度区和非再结晶温度区,揭示了高Nb含量的HTP钢在连续冷却过程中的相变特点.所得到的技术要点对细化奥氏体晶粒,避免混晶的出现,以及通过控制冷却得到理想的相变产物具有指导性.","authors":[{"authorName":"缪成亮","id":"dea98da8-553c-451e-8b99-0ae32831f7f2","originalAuthorName":"缪成亮"},{"authorName":"尚成嘉","id":"9ded192c-497a-40b4-b677-df1dbc475252","originalAuthorName":"尚成嘉"},{"authorName":"曹建平","id":"00bd8721-c28f-47d5-99a2-aa9c977f1c3b","originalAuthorName":"曹建平"},{"authorName":"王学敏","id":"de7c087e-b446-4445-af43-de347576c182","originalAuthorName":"王学敏"},{"authorName":"贺信莱","id":"22727eee-a2d6-4985-a583-17ea21e5a0c9","originalAuthorName":"贺信莱"}],"doi":"","fpage":"62","id":"119888d7-b8f6-42a1-9f3a-6d1afee8d5e5","issue":"3","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"b4975ab3-b311-411b-a7d9-2b37c43e2de1","keyword":"HTP}X80管线钢","originalKeyword":"HTP}X80管线钢"},{"id":"93c2fc92-6758-45c8-9ef6-6c1d7bf68f05","keyword":"再结晶","originalKeyword":"再结晶"},{"id":"43e141c9-76eb-4b91-9861-9727d803b1b7","keyword":"等温转变","originalKeyword":"等温转变"},{"id":"1e49bc87-830e-486e-aff5-aa747959c146","keyword":"连续冷却转变","originalKeyword":"连续冷却转变"}],"language":"zh","publisherId":"gt200903015","title":"HTP X80管线钢的晶粒细化与组织控制","volume":"44","year":"2009"},{"abstractinfo":"采用超声波处理为分散手段,通过自乳化法制备了改性氯化聚丙烯(CPP)乳液.比较了机械搅拌和超声乳化工艺对制备CPP乳液性能的影响;研究了超声波作用时间、作用功率对乳液性能的影响以及对乳液粒径及其分布的影响,结果表明,超声波的作用功率为400 W,作用时间为6 min时,得到的CPP乳液具有良好的稳定性,而且乳液涂膜在PP塑料上的附着力达到0级.","authors":[{"authorName":"董雪茹","id":"db3f688f-3560-4a3f-9a1a-560d855e9331","originalAuthorName":"董雪茹"},{"authorName":"强黎明","id":"4035f740-89bf-465c-ae8d-3b144b3de107","originalAuthorName":"强黎明"},{"authorName":"王学敏","id":"624d3d69-5cce-4694-97a9-d537dd012188","originalAuthorName":"王学敏"},{"authorName":"刘大壮","id":"8fea9d43-a079-4914-afbf-7cf32dcf071a","originalAuthorName":"刘大壮"}],"doi":"10.3969/j.issn.0253-4312.2011.02.003","fpage":"10","id":"2b84da7e-b347-4e84-9479-30c365c16898","issue":"2","journal":{"abbrevTitle":"TLGY","coverImgSrc":"journal/img/cover/TLGY.jpg","id":"61","issnPpub":"0253-4312","publisherId":"TLGY","title":"涂料工业 "},"keywords":[{"id":"7beb7e64-7592-4f92-8b56-42a00d558108","keyword":"超声波","originalKeyword":"超声波"},{"id":"86a9788a-abd1-4ad2-b5ed-6afdc00dde12","keyword":"氯化聚丙烯","originalKeyword":"氯化聚丙烯"},{"id":"49a9aa09-bdca-49d9-8692-112743877a59","keyword":"乳化","originalKeyword":"乳化"},{"id":"a301ef4c-7cd1-4102-be47-8f2549976753","keyword":"附着力","originalKeyword":"附着力"}],"language":"zh","publisherId":"tlgy201102003","title":"超声波对制备改性氯化聚丙烯乳液的影响","volume":"41","year":"2011"},{"abstractinfo":"用蠕变法在Gleeble-1500热模拟机上研究了不同Cu含量的Cu-Nb系超低碳钢的时效\n过程. 结果表明, 在蠕变过程中, 沉淀析出使蠕变曲线出现平台, 平台的起点与结束\n点分别对应析出开始点(Ps)与结束点(P f). 并得出了两类钢的沉淀析出等温转变(PTT)曲线. 由蠕变法测出的Pf与由硬度法测出的峰值\n时间tp吻合得较好.","authors":[{"authorName":"王学敏","id":"be61704f-7f1b-49d6-929c-3a63a960ce2c","originalAuthorName":"王学敏"},{"authorName":"尚成嘉","id":"55f9cae3-db8c-4f33-85d9-83287515ce88","originalAuthorName":"尚成嘉"},{"authorName":"杨善武","id":"93d48b4f-382a-413a-a1ea-0ea4d0790cb2","originalAuthorName":"杨善武"},{"authorName":"李闯","id":"974bee47-3346-4831-91d4-aab8c96e26a2","originalAuthorName":"李闯"},{"authorName":"贺信莱","id":"44f9cea8-a613-452a-af66-f7aa8bbe8431","originalAuthorName":"贺信莱"},{"authorName":"周桂峰","id":"64d2b29d-c27a-48c9-ad0e-14988bf61c4f","originalAuthorName":"周桂峰"}],"categoryName":"|","doi":"","fpage":"1256","id":"2df1439a-9e2a-4218-bc40-9f127149a41e","issue":"12","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"4774a851-d6e9-4426-b2d8-d0d92c750bb5","keyword":"Cu-Nb系超低碳钢","originalKeyword":"Cu-Nb系超低碳钢"},{"id":"e68cdacd-613f-491f-8512-832eedb22be7","keyword":"creep","originalKeyword":"creep"},{"id":"bc6daec9-8470-42e4-9c98-93be31af0b60","keyword":"aging hardening","originalKeyword":"aging hardening"}],"language":"zh","publisherId":"0412-1961_2005_12_8","title":"用蠕变法研究Cu-Nb钢中的时效行为","volume":"41","year":"2005"}],"totalpage":465,"totalrecord":4648}