{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"在固定床反应器上考察了氢型丝光沸石(HM)-氧化铝双组元负载MoO3催化剂上的 1-丁烯歧化反应性能,通过氨程序升温脱附、X射线衍射和氢程序升温还原对样品进行了表征. 实验结果表明,在110 ℃, 0.1 MPa, WHSV=1.5 h-1 及TOS=1 h的反应条件下, MoO3没有歧化反应活性. Al2O3, HM-Al2O3和HM载体上只生成异构产物,并且载体酸性越强,异构产物越多. MoO3/HM几乎没有歧化活性,而MoO3/Al2O3催化剂上生成了一定量的歧化产物,且各产物收率相近. MoO3/HM-Al2O3具有最高的歧化活性, 1-丁烯转化率为84.9%, 丙烯和戊烯收率分别为28.5%和20.6%. 催化剂本身的酸性和载体表面Mo物种存在状态是影响 1-丁烯歧化制丙烯反应性能的两个关键因素.","authors":[{"authorName":"刘会娟","id":"07406847-2012-47d7-a09b-913b7d91848f","originalAuthorName":"刘会娟"},{"authorName":"黄声骏","id":"87fe79bb-3a9e-459d-acb8-36aef97fed70","originalAuthorName":"黄声骏"},{"authorName":"张玲","id":"eeae2025-5b69-4c92-babc-6e637b796d25","originalAuthorName":"张玲"},{"authorName":"刘盛林","id":"1f9d74cc-c956-4c71-afc9-806c51e862df","originalAuthorName":"刘盛林"},{"authorName":"<span style=\"color:red\">王威</span>","id":"609b36bb-304e-4bb5-98b6-bc1b34844f7e","originalAuthorName":"王威"},{"authorName":"辛文杰","id":"ba0d36f5-8918-453e-a8a8-e640e9648a8a","originalAuthorName":"辛文杰"},{"authorName":"谢素娟","id":"18fd125e-1f51-483d-b261-f88b80fa2868","originalAuthorName":"谢素娟"},{"authorName":"徐龙伢","id":"8c16092a-d0b7-4e97-9724-a35e7a3eea8e","originalAuthorName":"徐龙伢"}],"doi":"","fpage":"513","id":"06467deb-4faf-4fd4-9933-64b1b9edbaeb","issue":"6","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报   "},"keywords":[{"id":"2bcf2bb6-6f15-42df-8f41-737e20ed11de","keyword":"丝光沸石","originalKeyword":"丝光沸石"},{"id":"4ff9c95d-e67f-4404-9088-2a070f9a96d1","keyword":"氧化铝","originalKeyword":"氧化铝"},{"id":"cade48f4-9705-4760-8a53-4d0168e79b01","keyword":"钼","originalKeyword":"钼"},{"id":"6223cf4b-b28c-4e64-93b6-2419bcf99cf7","keyword":"1-丁烯","originalKeyword":"1-丁烯"},{"id":"ea425139-39ff-42d9-b645-f2d99929a12b","keyword":"歧化","originalKeyword":"歧化"}],"language":"zh","publisherId":"cuihuaxb200806004","title":"丝光沸石-氧化铝双组元负载钼催化剂上的 1-丁烯歧化反应","volume":"29","year":"2008"},{"abstractinfo":"采用磁控溅射法在立方织构Ni-5%(原子分数,下同)W基底上沉积了Ag薄膜作为第二代高温超导带材--YBaCuO涂层导体的导电缓冲层,并通过后期在Ar气氛下热处理使Ag膜具有(200)择优取向.磁控溅射后Ag膜的择优取向为(111),随着热处理温度的升高,(200)择优取向强度增加.采用慢降温工艺即在900℃下恒温30min,然后以较慢的速率10℃/h降至800℃后样品随炉冷却,有利于Ag薄膜由(111)向(200)的择优生长转变.","authors":[{"authorName":"李凤华","id":"33c26d14-597a-4fee-8a92-6eba1a7fbde4","originalAuthorName":"李凤华"},{"authorName":"<span style=\"color:red\">王威</span>","id":"3e3d3338-7973-49d2-9d13-25465d3d9585","originalAuthorName":"王威"},{"authorName":"李英楠","id":"3c8c38f2-adbd-4b56-97b4-e7af76da365f","originalAuthorName":"李英楠"},{"authorName":"罗清威","id":"edf4ce6f-ad60-40fe-bb1c-e7d3fb3827ce","originalAuthorName":"罗清威"},{"authorName":"单玉桥","id":"b8ff4a22-6dee-48e1-be4a-c1528db27e84","originalAuthorName":"单玉桥"},{"authorName":"樊占国","id":"5b744756-dd5f-4c3d-9868-6b8356faf06c","originalAuthorName":"樊占国"},{"authorName":"卢亚峰","id":"de50094e-befa-4f64-97ea-79d7dfea0d5d","originalAuthorName":"卢亚峰"},{"authorName":"李成山","id":"7712c814-12eb-4002-9133-dc3b4c0a4391","originalAuthorName":"李成山"}],"doi":"","fpage":"1857","id":"0d9246e2-7201-4640-9b69-85fc21c719e6","issue":"11","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"a187f9a8-72e6-43ca-879e-7a6613d220e6","keyword":"YBaCuO涂层导体","originalKeyword":"YBaCuO涂层导体"},{"id":"c52e1db6-1a6d-48fd-aed4-23dc671646e6","keyword":"Ag","originalKeyword":"Ag"},{"id":"b5b1b580-8934-4247-a6f8-6de3df681ed7","keyword":"择优取向","originalKeyword":"择优取向"},{"id":"aba72c39-ac18-4532-8258-d4b431c55dae","keyword":"热处理","originalKeyword":"热处理"}],"language":"zh","publisherId":"gncl200911027","title":"热处理对立方织构Ni-5%(体积分数)W基带上Ag薄膜择优取向的影响","volume":"40","year":"2009"},{"abstractinfo":"研究了51CrV4、52CrMoV4、60Si2CrVA、60Si2MnA共4种高速列车常用弹簧钢的表面脱碳形貌,比较了脱碳敏感性大小.结果表明,Cr-V系弹簧钢具有较小的脱碳敏感性,Si-Mn系弹簧钢的脱碳倾向较大.在850 ～1050℃温度范围内,60Si2MnA的脱碳最严重,60Si2CrVA次之,51CrV4、52CrMoV4的脱碳敏感性最小.弹簧钢的化学成分对其脱碳行为有重要影响.","authors":[{"authorName":"史显波","id":"d73af78a-e8ae-4ffa-8118-956c39344015","originalAuthorName":"史显波"},{"authorName":"赵连玉","id":"540c24b2-8db6-471b-8ee3-0afe7500c629","originalAuthorName":"赵连玉"},{"authorName":"<span style=\"color:red\">王威</span>","id":"c844bf07-f244-4ec5-97a4-1e288be91ec9","originalAuthorName":"王威"},{"authorName":"曾波","id":"e2e1fd60-2790-49b3-aed8-5802694f5fb3","originalAuthorName":"曾波"},{"authorName":"赵立君","id":"d652f198-33c4-4c6a-bf9e-550ef966149b","originalAuthorName":"赵立君"},{"authorName":"单以银","id":"10545b3a-c997-4e1a-a40b-6a35c3e3702c","originalAuthorName":"单以银"},{"authorName":"沈明钢","id":"f098b958-5867-4625-a2fe-d956847090ad","originalAuthorName":"沈明钢"},{"authorName":"杨柯","id":"bb400e8f-6066-4c50-8871-6c2552d9b83c","originalAuthorName":"杨柯"}],"doi":"","fpage":"47","id":"189f55bc-ed83-49ea-a43d-0f12e0b11560","issue":"7","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":"c2f19784-04dc-45e6-bd34-7f32b611d3ee","keyword":"弹簧钢","originalKeyword":"弹簧钢"},{"id":"a5e063dc-9343-46be-b79b-50ea4b90838e","keyword":"脱碳敏感性","originalKeyword":"脱碳敏感性"},{"id":"d0855d38-c87f-464e-96c8-05cd22eb5a58","keyword":"51CrV4","originalKeyword":"51CrV4"},{"id":"fe002f05-4785-4bc8-ac85-5e3e6b77f4a7","keyword":"52CrMoV4","originalKeyword":"52CrMoV4"},{"id":"fe0736b7-977f-4eec-a2ee-9adbf13af460","keyword":"60Si2CrVA","originalKeyword":"60Si2CrVA"},{"id":"ef19272c-94e6-4cfe-ab55-ced7a3656bde","keyword":"60Si2MnA","originalKeyword":"60Si2MnA"}],"language":"zh","publisherId":"jsrclxb201307010","title":"几种高速列车用弹簧钢的脱碳敏感性","volume":"34","year":"2013"},{"abstractinfo":"加速器驱动次临界(accelerator driven subcritical system, ADS)系统由加速器、散裂靶、反应堆3 部分组成, 被认为是安全处理核废料最具前景的技术方案. 其中, 散裂靶用结构材料需要同时具有耐高温、抗辐照、抗液态金属腐蚀等性能. 针对这一挑战研发了新型核用(9%~12%)Cr 马氏体耐热钢——SIMP 钢. 通过制衡(9%~12%)Cr 马氏体耐热钢中C, Cr, Si 等元素含量对耐高温、抗辐照、抗液态金属腐蚀性能的影响, 获得了SIMP 钢优化的化学成分, 极好地平衡了SIMP 钢耐高温、抗辐照、抗液态金属腐蚀3 方面性能. 对1 t 和5 t SIMP 钢各项性能进行测试, 结果表明, SIMP 钢是ADS 系统中散裂靶的首选结构材料.","authors":[{"authorName":"杨柯","id":"848b9e33-8456-46a5-9d78-98c05fff6862","originalAuthorName":"杨柯"},{"authorName":"严伟","id":"c84d9207-1102-4a45-8841-a095d6f5faf6","originalAuthorName":"严伟"},{"authorName":"王志光","id":"f2a21cfa-2a15-4330-a76a-688aa896d87f","originalAuthorName":"王志光"},{"authorName":"单以银","id":"c3feda48-7f33-4ce3-b3f4-254f1882f3f2","originalAuthorName":"单以银"},{"authorName":"石全强","id":"dd2fedf6-6d91-43b5-af46-6db4a83693e3","originalAuthorName":"石全强"},{"authorName":"史显波","id":"56aa3fa1-0542-455a-9c59-2c00b76b4334","originalAuthorName":"史显波"},{"authorName":"<span style=\"color:red\">王威</span>","id":"f209680a-f28f-4215-8c8b-7cac53b44c41","originalAuthorName":"王威"}],"doi":"10.11900/0412.1961.2016.00320","fpage":"1207","id":"20957ced-a01d-46b9-9bfb-7b9670714129","issue":"10","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"c0aa9d85-4d6e-45d2-a3e3-42369786fcb5","keyword":"加速器驱动次临界(ADS)系统","originalKeyword":"加速器驱动次临界(ADS)系统"},{"id":"c19f21ed-645f-46a7-b291-6d702096c664","keyword":"核结构用钢","originalKeyword":"核结构用钢"},{"id":"91061d01-08c5-4d41-b39c-aee27ca4073c","keyword":"耐热","originalKeyword":"耐热"},{"id":"22349d8c-70c1-4b41-8993-b36aff785423","keyword":"辐照","originalKeyword":"辐照"},{"id":"565a497d-1764-4256-b16c-944841145504","keyword":"液态金属腐蚀","originalKeyword":"液态金属腐蚀"}],"language":"zh","publisherId":"0412-1961(2016)10-1207-15","title":"核用新型耐高温、抗辐照、耐液态金属腐蚀结构材料——SIMP钢的研究进展","volume":"52","year":"2016"},{"abstractinfo":"通过二次冷轧铜棒并850℃恒温热处理,制备出具有较强立方织构的Cu基带。以硝酸银、亚硫酸钠和硫代硫酸钠为主要原料配制镀银液,在立方织构Cu基带上制备出具有较强Ag（200）择优取向的银镀层。在600℃恒温热处理30min后Ag膜仍具有（200）择优取向,而830℃热处理后,Ag会扩散到Cu基底中,重复镀银、热处理5次后,Ag膜具有（200）的择优取向并少量面内织构,所得Ag/立方织构Cu复合带材可作为第二代高温超导带材YBCO涂层导体的金属基底。","authors":[{"authorName":"李凤华","id":"abf5c3ef-a5d2-4cb7-8061-8d10e66fcb92","originalAuthorName":"李凤华"},{"authorName":"庞雪","id":"b39ebf51-cd24-4302-b2c3-6e5f81455199","originalAuthorName":"庞雪"},{"authorName":"罗清威","id":"24ccb4b9-643a-4528-9ef4-6c50a58a96d9","originalAuthorName":"罗清威"},{"authorName":"李英楠","id":"31dae43a-9fe9-46f1-8b23-c5b49d9f95f0","originalAuthorName":"李英楠"},{"authorName":"<span style=\"color:red\">王威</span>","id":"8f069e04-ddd1-4694-8f3d-c9ba7a62b0a9","originalAuthorName":"王威"},{"authorName":"冉阿倩","id":"7f174fa0-c00b-4b00-adfd-db38894e41f4","originalAuthorName":"冉阿倩"},{"authorName":"樊占国","id":"7d5e5d8b-90e7-4f68-8542-8671c3cd422c","originalAuthorName":"樊占国"}],"doi":"","fpage":"120","id":"91409edd-a396-4059-b131-30dc5e224f7e","issue":"1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"92380027-8bc7-42a5-bb63-758b27186225","keyword":"YBCO涂层导体","originalKeyword":"YBCO涂层导体"},{"id":"ab929192-79b2-4a18-a882-ead000877023","keyword":"立方织构","originalKeyword":"立方织构"},{"id":"5ed4f29b-0252-4440-bd91-9c9a1e46daf7","keyword":"Cu带","originalKeyword":"Cu带"},{"id":"9581864a-5655-44f9-a750-bcc6e4ca51bc","keyword":"化学镀银","originalKeyword":"化学镀银"}],"language":"zh","publisherId":"gncl201201032","title":"用于涂层导体的Ag/立方织构Cu复合基带的制备","volume":"43","year":"2012"},{"abstractinfo":"研究了灰口铸铁(HT150)在900℃大压下量塑性变形后石墨的分布形态,结果表明:随着压下量的增加,石墨片逐渐趋于平行分布;变形过程中发生了碳的回溶,同时伴随着石墨片的断裂;石墨片体积分数及片间距随压下量的增加而逐渐减少.","authors":[{"authorName":"高聿为","id":"22554612-4500-4995-a78e-89ee52051d0a","originalAuthorName":"高聿为"},{"authorName":"<span style=\"color:red\">王威</span>","id":"4788db91-e060-4447-b0f2-92ace7230375","originalAuthorName":"王威"},{"authorName":"荆天辅","id":"69a1dd00-55ce-413b-a3d5-9279946e6f92","originalAuthorName":"荆天辅"},{"authorName":"乔桂英","id":"57b1cf68-6d67-4599-bae1-065f91909b2b","originalAuthorName":"乔桂英"},{"authorName":"赵新","id":"a8f3cd0c-e814-45de-90e1-a4b653b03a78","originalAuthorName":"赵新"},{"authorName":"周继峰","id":"b4bea487-8f62-4e04-89e6-ea12c6b04842","originalAuthorName":"周继峰"},{"authorName":"肖福仁","id":"c9781da2-3e26-476f-a445-fe0eecfd061a","originalAuthorName":"肖福仁"}],"doi":"10.3969/j.issn.1009-6264.2004.04.013","fpage":"49","id":"b4d4c753-7042-44f3-9478-4f92ba695586","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":"8985f3e8-698e-493f-8141-e2e428c711b7","keyword":"灰口铸铁","originalKeyword":"灰口铸铁"},{"id":"120389d4-d3a7-41ab-b7e5-d1588cba47e1","keyword":"塑性变形","originalKeyword":"塑性变形"},{"id":"87e89f3a-6e14-41fb-be14-91a1289834a1","keyword":"回归分析","originalKeyword":"回归分析"},{"id":"b62b0fb4-f63a-4835-8922-a60a5fcf3e64","keyword":"石墨形态","originalKeyword":"石墨形态"}],"language":"zh","publisherId":"jsrclxb200404013","title":"热压变形对灰口铸铁石墨形态的影响","volume":"25","year":"2004"},{"abstractinfo":"<p>采用高分辨透射电镜(HRTEM)和原子探针层析技术(APT)等分析手段研究了一种多相强化型马氏体时效不锈钢时效过程中的元素偏聚特征及其与材料力学和耐蚀性能的关系. 结果表明, 马氏体时效不锈钢在时效过程中析出3种强化相: 富Mo的R′相、Ni<sub>3</sub>Ti金属间化合物η相和富Cr的α′相. 其中R′相与η相一起形成核壳状结构, α′相则单独弥散分布于基体中. 时效时间延长至40 h后, 主要强化相η相的成分、数量密度和等效半径基本稳定, 同时马氏体时效不锈钢的强度不再发生明显的变化, 这种优异的抗过时效能力是由于核壳状结构的形成. 腐蚀实验结果表明, 由于富Cr的α′相的析出, 导致贫Cr区的形成, 进而降低了马氏体时效不锈钢的耐蚀性能.</p>","authors":[{"authorName":"田家龙","id":"294e0d82-e548-4718-a35a-5c40cd1814d6","originalAuthorName":"田家龙"},{"authorName":"李永灿","id":"f6ce014e-a4c2-4777-b86c-ef1aa35e57a5","originalAuthorName":"李永灿"},{"authorName":"<span style=\"color:red\">王威</span>","id":"8ebd3e77-766e-4265-a938-f57c31ee5593","originalAuthorName":"王威"},{"authorName":"严伟","id":"4d2ecf84-3634-4208-87ac-5d4045f67c57","originalAuthorName":"严伟"},{"authorName":"单以银","id":"7784f0e4-a4e3-4a5b-9313-895be4306bfc","originalAuthorName":"单以银"},{"authorName":"姜周华","id":"b3662db4-20ca-4b4e-8c28-ffddce080011","originalAuthorName":"姜周华"},{"authorName":"杨柯","id":"e90612d3-8b33-43ed-ad94-e319961a97b9","originalAuthorName":"杨柯"}],"categoryName":"Orginal Article","doi":"10.11900/0412.1961.2016.00234","fpage":"1517","id":"37d26956-4060-4167-bd9f-1186dc26c1c2","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":"52ca0324-eb27-41f5-8947-6fa7ed083b5a","keyword":"马氏体时效不锈钢,","originalKeyword":"马氏体时效不锈钢,"},{"id":"9d2de289-fddc-490c-9a31-0592656967a2","keyword":"合金元素偏聚,","originalKeyword":"合金元素偏聚,"},{"id":"25dfe779-4307-450a-bdbe-438a6aa1711a","keyword":"力学性能,","originalKeyword":"力学性能,"},{"id":"e0c20c63-5e50-4db2-ad67-1a20c0090ffb","keyword":"耐蚀性能","originalKeyword":"耐蚀性能"}],"language":"zh","publisherId":"C20160234","title":"多相强化型马氏体时效不锈钢中的合金元素偏聚效应<sup>*</sup>","volume":"52","year":"2016"},{"abstractinfo":"加速器驱动次临界(accelerator driven subcritical system,ADS)系统由加速器、散裂靶、反应堆3部分组成,被认为是安全处理核废料最具前景的技术方案.其中,散裂靶用结构材料需要同时具有耐高温、抗辐照、抗液态金属腐蚀等性能.针对这一挑战研发了新型核用(9％～12％)Cr马氏体耐热钢-SIMP钢.通过制衡(9％～l2％)Cr马氏体耐热钢中C,Cr,Si等元素含量对耐高温、抗辐照、抗液态金属腐蚀性能的影响,获得了SIMP钢优化的化学成分,极好地平衡了SIMP钢耐高温、抗辐照、抗液态金属腐蚀3方面性能.对It和5 t SIMP钢各项性能进行测试,结果表明,SIMP钢是ADS系统中散裂靶的首选结构材料.","authors":[{"authorName":"杨柯","id":"30bb7323-e036-4a91-8fae-2832e0435f06","originalAuthorName":"杨柯"},{"authorName":"严伟","id":"eef8f9a5-3d8c-4f75-b012-1d8b7fdcf8d9","originalAuthorName":"严伟"},{"authorName":"王志光","id":"ffd5795f-424d-4fc3-bf2d-a2ad3c8511b4","originalAuthorName":"王志光"},{"authorName":"单以银","id":"5e792da7-2427-446d-b02c-0126c35d8d7d","originalAuthorName":"单以银"},{"authorName":"石全强","id":"7970669b-5e65-4374-ab84-2bab8462a371","originalAuthorName":"石全强"},{"authorName":"史显波","id":"72847ed1-9f39-4fa5-b983-d20cb1ba6467","originalAuthorName":"史显波"},{"authorName":"<span style=\"color:red\">王威</span>","id":"935e2c17-f3a3-44ce-8bc6-a5ff39514ee7","originalAuthorName":"王威"}],"doi":"10.11900/0412.1961.2016.00320","fpage":"1207","id":"39a63b76-a1f3-41c6-87a1-0231ea2a48f0","issue":"10","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"fa97f1a4-c012-4f5f-8b74-3d456625edc5","keyword":"加速器驱动次临界(ADS)系统","originalKeyword":"加速器驱动次临界(ADS)系统"},{"id":"1c1add50-5c51-4909-af40-54d5ab93077d","keyword":"核结构用钢","originalKeyword":"核结构用钢"},{"id":"0d8d173f-0910-4b4a-a454-9a90c077c766","keyword":"耐热","originalKeyword":"耐热"},{"id":"e3def91b-4823-48d3-a01e-9ada160cb5c5","keyword":"辐照","originalKeyword":"辐照"},{"id":"7cd1b74e-169e-422a-94ca-9163d1502725","keyword":"液态金属腐蚀","originalKeyword":"液态金属腐蚀"}],"language":"zh","publisherId":"jsxb201610007","title":"核用新型耐高温、抗辐照、耐液态金属腐蚀结构材料——SIMP钢的研究进展","volume":"52","year":"2016"},{"abstractinfo":"采用高分辨透射电镜(HRTEM)和原子探针层析技术(APT)等分析手段研究了一种多相强化型马氏体时效不锈钢时效过程中的元素偏聚特征及其与材料力学和耐蚀性能的关系.结果表明,马氏体时效不锈钢在时效过程中析出3种强化相:富Mo的R'相、Ni3Ti金属间化合物η相和富Cr的α′相.其中R′相与η相一起形成核壳状结构,α′相则单独弥散分布于基体中.时效时间延长至40 h后,主要强化相η相的成分、数量密度和等效半径基本稳定,同时马氏体时效不锈钢的强度不再发生明显的变化,这种优异的抗过时效能力是由于核壳状结构的形成.腐蚀实验结果表明,由于富Cr的α′相的析出,导致贫Cr区的形成,进而降低了马氏体时效不锈钢的耐蚀性能.","authors":[{"authorName":"田家龙","id":"3b686bcb-9106-4b30-96cb-ef33042ca31e","originalAuthorName":"田家龙"},{"authorName":"李永灿","id":"731b86ad-2244-4227-b469-a384b8962b0c","originalAuthorName":"李永灿"},{"authorName":"<span style=\"color:red\">王威</span>","id":"e56ac072-50c0-48da-840c-f98232c480c1","originalAuthorName":"王威"},{"authorName":"严伟","id":"fd85889c-4ca9-4f9d-bf3e-a766fd074b96","originalAuthorName":"严伟"},{"authorName":"单以银","id":"83d0baa1-20fc-4dae-bd7d-92d53546b7a4","originalAuthorName":"单以银"},{"authorName":"姜周华","id":"9f8f7698-48f9-47e1-9c97-2fe95b0c2534","originalAuthorName":"姜周华"},{"authorName":"杨柯","id":"668144b9-ae32-4370-8515-0320e2d0035a","originalAuthorName":"杨柯"}],"doi":"10.11900/0412.1961.2016.00234","fpage":"1517","id":"cbebe8c4-717e-4362-8a39-86630b400567","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":"085dda73-ab94-4a7b-a42a-256573bcef56","keyword":"马氏体时效不锈钢","originalKeyword":"马氏体时效不锈钢"},{"id":"9bd5edae-f4dc-4ad9-b370-c754be83188c","keyword":"合金元素偏聚","originalKeyword":"合金元素偏聚"},{"id":"d775ef5f-72ed-45a7-8c95-8eb015358c2f","keyword":"力学性能","originalKeyword":"力学性能"},{"id":"657aff82-c98a-43f9-a1c8-8303943b0a03","keyword":"耐蚀性能","originalKeyword":"耐蚀性能"}],"language":"zh","publisherId":"jsxb201612005","title":"多相强化型马氏体时效不锈钢中的合金元素偏聚效应","volume":"52","year":"2016"},{"abstractinfo":"近年来,离子液体在金属萃取领域的研究受到广泛关注,主要集中在两个方面,一是疏水性离子液体作为“绿色”溶剂用于金属离子萃取;二是带有官能团的功能性离子液体作为萃取剂用于金属离子萃取,其中,后者是目前研究的热点.本文主要对近年来功能性离子液体萃取分离放射性金属、重金属和稀土金属等研究进行综述,并对其未来发展进行了展望.","authors":[{"authorName":"<span style=\"color:red\">王威</span>","id":"5afc869b-a9e1-41e8-b6ee-5685b6ad6f3f","originalAuthorName":"王威"},{"authorName":"陈继","id":"d1a3d26b-ad9b-4945-9b84-bd685fc55485","originalAuthorName":"陈继"},{"authorName":"刘红召","id":"ea7e1607-e6d7-4f31-9aab-886ab494d50e","originalAuthorName":"刘红召"},{"authorName":"杨华玲","id":"5bc803cf-7517-4a38-a9e7-2a4c92bb7e86","originalAuthorName":"杨华玲"},{"authorName":"曹耀华","id":"ef2aed2b-f636-46ea-a4f5-81ef0ab423a7","originalAuthorName":"曹耀华"},{"authorName":"高照国","id":"991e877f-462d-414a-9cd9-607b22829a03","originalAuthorName":"高照国"},{"authorName":"张博","id":"b4378449-63c0-4871-94be-1bf3dc9ab685","originalAuthorName":"张博"}],"doi":"10.11944/j.issn.1000-0518.2015.07.140441","fpage":"733","id":"562174c1-e1bf-4ec9-aad2-292cdf9ae8fb","issue":"7","journal":{"abbrevTitle":"YYHX","coverImgSrc":"journal/img/cover/YYHX.jpg","id":"73","issnPpub":"1000-0518","publisherId":"YYHX","title":"应用化学"},"keywords":[{"id":"3e195ff9-96dc-4c42-977b-e5d7f7fc75fb","keyword":"功能性离子液体","originalKeyword":"功能性离子液体"},{"id":"baeadbdd-d8cc-4a5e-8caf-af309b1a78cd","keyword":"萃取","originalKeyword":"萃取"},{"id":"10b36bc3-4e20-4e6a-bab2-5ef7afe54e78","keyword":"金属离子","originalKeyword":"金属离子"}],"language":"zh","publisherId":"yyhx201507001","title":"功能性离子液体在金属萃取分离中的研究进展","volume":"32","year":"2015"}],"totalpage":6,"totalrecord":53}