材料期刊网

合成材料老化与应用, 2016, 45(5): 97-100.

季戊四醇酯抗氧剂的合成进展

李维义 ^1, , 谭卓华 ^2,

{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"固体氧化物直接碳燃料电池采用固体氧化物作为电解质，能够将碳燃料的化学能直接转化为电能，具有效率高、燃料适应性广、利于 CO2捕集等优点，在能源与环境问题日益突出的现实条件下展现出广阔的应用前景。固体氧化物直接碳燃料电池中的关键问题在于研发合适的碳燃料转化阳极，以满足反应催化、物质输运以及杂质耐受等要求。本文系统地总结并分析了多孔固体阳极、熔融碳酸盐阳极和液态金属阳极三类直接燃料电池阳极的结构特性、工作原理、材料特性等，特别关注了以液态金属作为阳极的直接碳燃料电池，分析了该类电极的优势，探讨了未来固体氧化物直接碳燃料电池阳极的发展方向。","authors":[{"authorName":"王洪建","id":"92d13fbf-bac0-4463-ac9b-2555771ea1b6","originalAuthorName":"王洪建"},{"authorName":"曹天宇","id":"cc4d2ce4-7ddf-4c3f-af8e-c226ebe8b84e","originalAuthorName":"曹天宇"},{"authorName":"史翊翔","id":"d1f4905e-23ba-46d0-a413-3554de0cc8f0","originalAuthorName":"史翊翔"},{"authorName":"蔡宁生","id":"f6d3f04e-5a14-4995-af75-5609fa0eb15d","originalAuthorName":"蔡宁生"}],"doi":"10.3724/SP.J.1077.2013.13553","fpage":"681","id":"561ace36-9997-40d3-9a81-64f43e8cdcb4","issue":"7","journal":{"abbrevTitle":"WJCLXB","coverImgSrc":"journal/img/cover/WJCLXB.jpg","id":"62","issnPpub":"1000-324X","publisherId":"WJCLXB","title":"无机材料学报"},"keywords":[{"id":"50f4e12e-192f-41d7-a8d1-5c25b9de4ba6","keyword":"固体氧化物直接碳燃料电池","originalKeyword":"固体氧化物直接碳燃料电池"},{"id":"727eca5a-6b82-4e2e-9cf7-485f2ce589d5","keyword":"多孔固体阳极","originalKeyword":"多孔固体阳极"},{"id":"64319bdf-f4cc-4347-a42f-de3a39500abf","keyword":"熔融碳酸盐阳极","originalKeyword":"熔融碳酸盐阳极"},{"id":"bd1f0eb8-2d17-4866-a381-5d310238e718","keyword":"液态金属阳极","originalKeyword":"液态金属阳极"},{"id":"055cb192-1891-4568-8e3d-3190fdfd63ef","keyword":"综述","originalKeyword":"综述"}],"language":"zh","publisherId":"wjclxb201407002","title":"固体氧化物直接碳燃料电池新型阳极研究进展","volume":"","year":"2014"},{"abstractinfo":"针对生产过程中发生的液态金属导致零件失效的几个典型案例进行了剖析,研究了液态金属导致零件失效的机理,并提出了预防措施.","authors":[{"authorName":"张权明","id":"ce3eebec-9d76-4663-9d18-6fe0585f7ec8","originalAuthorName":"张权明"},{"authorName":"迟淳","id":"6cf51910-5313-4ed3-800b-0b58b23392ec","originalAuthorName":"迟淳"},{"authorName":"张勇","id":"d80d757c-8b48-43d7-ab09-34b9b034b278","originalAuthorName":"张勇"},{"authorName":"张万欣","id":"8a9ed4f7-1a9f-4536-a03d-4d3f7fa3a205","originalAuthorName":"张万欣"}],"doi":"","fpage":"51","id":"6a7feb67-1958-4dbf-9eda-37436ea9a815","issue":"6","journal":{"abbrevTitle":"WLCS","coverImgSrc":"journal/img/cover/WLCS.jpg","id":"64","issnPpub":"1001-0777","publisherId":"WLCS","title":"物理测试"},"keywords":[{"id":"d3e02744-5da4-4c90-9733-aaeeb8d737ca","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"2efe64ff-fb44-4ade-94b6-82c92e8d28fa","keyword":"脆化开裂","originalKeyword":"脆化开裂"},{"id":"49d57e8a-43b0-47ff-a66c-b8297bb77f08","keyword":"失效","originalKeyword":"失效"}],"language":"zh","publisherId":"wlcs200806014","title":"液态金属致脆失效案例分析","volume":"26","year":"2008"},{"abstractinfo":"针对生产过程中发生的液态金属导致零件失效的几个典型案例进行了剖析，研究了液态金属导致零件失效的机理，并提出了预防措施。","authors":[{"authorName":"张权明","id":"73978c9e-c313-4a1b-825a-c281e9d48f4a","originalAuthorName":"张权明"},{"authorName":"迟淳","id":"6e50c292-e0a7-43d7-8ba9-07082b044c08","originalAuthorName":"迟淳"},{"authorName":"张勇","id":"c4210dcf-4798-4afc-9cce-d7aff794f561","originalAuthorName":"张勇"},{"authorName":"张万欣","id":"c97ef99a-c8d8-4ce6-a3e2-b97867430635","originalAuthorName":"张万欣"}],"categoryName":"|","doi":"","fpage":"51","id":"e1c5d9ec-5bf9-4b2a-b1b9-aecfc18f2066","issue":"6","journal":{"abbrevTitle":"WLCS","coverImgSrc":"journal/img/cover/WLCS.jpg","id":"64","issnPpub":"1001-0777","publisherId":"WLCS","title":"物理测试"},"keywords":[{"id":"09ed9b6f-9d4b-4383-b60a-2b05cdd61545","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"8e934548-46b5-4b09-a521-e60f32c52bf7","keyword":"brittle fracture","originalKeyword":"brittle fracture"},{"id":"70d27297-fc03-46d1-b815-64c0b95c08fe","keyword":"failure","originalKeyword":"failure"}],"language":"zh","publisherId":"1001-0777_2008_6_14","title":"液态金属致脆失效案例分析","volume":"26","year":"2008"},{"abstractinfo":"对液态金属电磁成形的物理和数学模型进行了分析,提出了双频电磁成形的方法(利用两种频率的电磁场实现固态金属无接触加热熔化和熔化后的金属无模壳电磁成形)和原理.在分析液态金属电磁成形理论模型的基础上确认:作用在液态金属表面的电磁压力和加热密度主要取决于其表面上磁场的大小以及磁场在液态金属中的分布规律.最后分析了复杂形状液态金属电磁成形数值计算中存在的难点和解决方法.","authors":[{"authorName":"李双明","id":"7ac6681c-ab3c-438a-bf7b-2f52ca06ba2b","originalAuthorName":"李双明"},{"authorName":"李建国","id":"7d3c4a69-cc4e-449b-8ada-43e20988039c","originalAuthorName":"李建国"},{"authorName":"沈军","id":"62357fa3-1838-48e4-ae61-7c8988f30245","originalAuthorName":"沈军"},{"authorName":"李金山","id":"c307f3b9-0b32-44d8-a338-c8dbaa31ca06","originalAuthorName":"李金山"},{"authorName":"张军","id":"89246da3-9a92-49f3-9bf0-fdda6fb95e48","originalAuthorName":"张军"},{"authorName":"傅恒志","id":"c65eb376-ae81-4f39-8071-f97394c39635","originalAuthorName":"傅恒志"}],"doi":"","fpage":"5","id":"dd28452d-fbb5-480a-9365-9757da925706","issue":"3","journal":{"abbrevTitle":"GTYJXB","coverImgSrc":"journal/img/cover/GTYJXB.jpg","id":"30","issnPpub":"1001-0963","publisherId":"GTYJXB","title":"钢铁研究学报"},"keywords":[{"id":"4eca8a56-05c6-4f79-bc6a-e5eb3392cd64","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"5c3904a9-9d7b-496b-b2e1-7e9d84102862","keyword":"电磁成形","originalKeyword":"电磁成形"},{"id":"f6e65f1e-9e9c-41c6-948e-758e97f68483","keyword":"双频","originalKeyword":"双频"},{"id":"6e186537-bc6a-4595-95bf-b59d951fcba9","keyword":"电磁压力","originalKeyword":"电磁压力"},{"id":"e5b9a7eb-f68f-4dba-979b-c6c11aa316c5","keyword":"理论模型","originalKeyword":"理论模型"}],"language":"zh","publisherId":"gtyjxb200003002","title":"液态金属电磁成形的理论模型","volume":"12","year":"2000"},{"abstractinfo":"液态金属的非透明性和相对较高的温度,给流速的测量带来了众多困难.为此介绍了几种液态金属的流速测量技术,分析了各种流速测量技术的特点,为在研究和实验中正确地选择和使用合适的测量设备提供依据和参考.","authors":[{"authorName":"于湛","id":"dabc2d51-de7f-481b-a5cb-52255c508f84","originalAuthorName":"于湛"},{"authorName":"雷作胜","id":"3eef90f6-aabb-44f1-8ea2-a7eee32c2a45","originalAuthorName":"雷作胜"},{"authorName":"贾洪海","id":"789afea6-1710-4f34-8e4f-e1da2843c9aa","originalAuthorName":"贾洪海"},{"authorName":"金小礼","id":"2b9ecb0f-fe16-421e-ae70-f8fdf5d0a6d9","originalAuthorName":"金小礼"},{"authorName":"任忠鸣","id":"4c78f54e-361e-43b6-b542-b8a98dd61460","originalAuthorName":"任忠鸣"},{"authorName":"邓康","id":"0d38e155-ba81-4adf-b262-a077d313c242","originalAuthorName":"邓康"},{"authorName":"钟云波","id":"a19786d5-70b0-426e-aaf4-592773436da7","originalAuthorName":"钟云波"}],"doi":"10.3969/j.issn.1001-7208.2007.02.012","fpage":"54","id":"f8a6bedd-b002-4af8-9da8-85e77b1b622f","issue":"2","journal":{"abbrevTitle":"SHJS","coverImgSrc":"journal/img/cover/SHJS.jpg","id":"59","issnPpub":"1001-7208","publisherId":"SHJS","title":"上海金属"},"keywords":[{"id":"7e8a502d-511f-4c63-898f-568057723b95","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"6bb7b8ee-761a-40f8-ae37-115d3ff58f25","keyword":"流速测量","originalKeyword":"流速测量"},{"id":"947f4819-1de1-4f80-b310-a89fd410c9f6","keyword":"测速方法","originalKeyword":"测速方法"},{"id":"f2423acb-b773-4393-b8ba-82059cbfee0a","keyword":"技术进展","originalKeyword":"技术进展"}],"language":"zh","publisherId":"shjs200702012","title":"液态金属流速的测量技术","volume":"29","year":"2007"},{"abstractinfo":"探讨了液态金属质量的含义、表征与评测方法,评述了用热分析方法评测液态金属质量的进展.着重介绍了计算机和人工智能在热分析液态金属质量评测中的应用.","authors":[{"authorName":"李言祥","id":"843a8e19-afd7-4a51-a08a-3eec53b2d701","originalAuthorName":"李言祥"},{"authorName":"王强","id":"f5b3a921-6c82-4a76-9c65-93c1f6f64bd0","originalAuthorName":"王强"},{"authorName":"徐雪蓉","id":"965194f1-cec1-4cb7-8005-68f746ec14b8","originalAuthorName":"徐雪蓉"}],"doi":"","fpage":"1","id":"66adcaa6-72a7-428a-a7d8-1e48b209073c","issue":"8","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"47f92143-5fad-47ca-bd0f-143fb7239d2f","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"f3c2874f-e682-4b83-9794-aec4e912283f","keyword":"熔体质量","originalKeyword":"熔体质量"},{"id":"372030c5-145e-4134-8df3-4a5bb7f51f54","keyword":"热分析","originalKeyword":"热分析"}],"language":"zh","publisherId":"cldb200208001","title":"液态金属质量的表征与评测技术进展","volume":"16","year":"2002"},{"abstractinfo":"详细论述了目前广泛研究的液态金属电磁净化技术,对各种分离方法的电磁力作用原理、影响因素、应用的局限性进行了深入分析.并就目前研究中存在的问题、应用必须解决的关键问题和今后的研究方向提出了自己的见解.","authors":[{"authorName":"张国志","id":"a58bc85e-34c3-4ca6-a782-ecd5e1cdf5f7","originalAuthorName":"张国志"},{"authorName":"辛启斌","id":"3de32299-6e6e-4bf7-8fde-79afc569763f","originalAuthorName":"辛启斌"},{"authorName":"张辉","id":"720d2929-1cd2-468e-98d2-24070816a705","originalAuthorName":"张辉"},{"authorName":"贾光霖","id":"4470da88-26c5-4c79-8e2a-f8aff9144a83","originalAuthorName":"贾光霖"},{"authorName":"高允彦","id":"c63d21a3-7b2a-4a7b-8f3e-5679ca42b650","originalAuthorName":"高允彦"}],"doi":"10.3969/j.issn.1671-6620.2002.01.006","fpage":"31","id":"5e9b6c9c-0c5e-4931-a6be-6af7dc97f8e6","issue":"1","journal":{"abbrevTitle":"CLYYJXB","coverImgSrc":"journal/img/cover/CLYYJXB.jpg","id":"17","issnPpub":"1671-6620","publisherId":"CLYYJXB","title":"材料与冶金学报"},"keywords":[{"id":"c888b7c4-11bf-464e-bff8-7e48c2ce5c1b","keyword":"电磁净化","originalKeyword":"电磁净化"},{"id":"d9bb1430-ecdf-44ca-b6fc-da2e740d8486","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"a5d8d141-b4db-4908-a215-60d739dcc61f","keyword":"非金属夹杂","originalKeyword":"非金属夹杂"}],"language":"zh","publisherId":"clyyjxb200201006","title":"关于液态金属电磁净化的探讨","volume":"1","year":"2002"},{"abstractinfo":"采用分子动力学方法对液态Ga 的凝固过程进行了模拟研究. 结果表明, 与通常液态及非晶态金属相反, 随着温度降低, 与二十面体相关的1551键型数越来越少, 而与菱面体相关的1311, 1301和1201键型数目显著增加, 最后形成以菱面体结构单元为主的非晶态结构. 以1.69×1012K/s的速度冷却时, 得到非晶态结构; 以1.01×1011K/s的速度冷却时, 发生晶化, 结晶转变温度约为144K. ","authors":[{"authorName":"易双萍","id":"b7809342-e30e-487b-b1dc-8226cfd25a83","originalAuthorName":"易双萍"},{"authorName":"刘让苏","id":"7d8a06a7-713f-4ac2-98f4-7835d78a53bf","originalAuthorName":"刘让苏"},{"authorName":"李基永","id":"a3fdacfc-b2ff-4b01-8b42-2946363a2a19","originalAuthorName":"李基永"},{"authorName":"董科军","id":"26c0224d-9661-4447-aa29-c0349c118a5b","originalAuthorName":"董科军"}],"doi":"","fpage":"257","id":"758ebbe6-e065-49ed-bc56-e612fc4d44e6","issue":"z2","journal":{"abbrevTitle":"ZGYSJSXB","coverImgSrc":"journal/img/cover/ZGYSJSXB.jpg","id":"88","issnPpub":"1004-0609","publisherId":"ZGYSJSXB","title":"中国有色金属学报"},"keywords":[{"id":"3e38ffbc-1ca4-46d2-9450-0a1b2dbaf2ba","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"d23eab5c-b9ea-415b-b10b-79931f5ec6fd","keyword":"结构转变","originalKeyword":"结构转变"},{"id":"16b7ec24-97b1-417b-b551-4eb66fcd19f7","keyword":"分子动力学","originalKeyword":"分子动力学"}],"language":"zh","publisherId":"zgysjsxb2001z2058","title":"液态金属Ga的快速凝固模拟","volume":"11","year":"2001"},{"abstractinfo":"对影响液态金属电磁成形形状的电磁压力、表面张力以及静压力进行了讨论.计算了圆形和矩形两种形状线圈中磁场和电磁压力的分布.结果发现:支撑高度为30～40 mm铝液和15～20 mm钢液所需电流约为1 500～2 000 A;计算的矩形线圈中等磁感应强度线形状与文献中实测形状以及实验电磁成形试样形状吻合较好.对铝和钢液表面张力进行计算时发现:液态金属电磁成形试样直径大于10 mm时,铝液的表面张力与高度为30 mm铝液柱产生的静压力和支撑该高度的电磁压力相比,可忽略不计,而要忽略不计钢液表面张力时,钢成形液柱的直径应更小.此外,在电磁成形综合分析中,利用最小作用原理对力平衡条件下,液态金属的电磁成形形状进行了分析,获得电磁成形形状稳定性的条件,最后提出了固-液界面上复杂形状试样的电磁成形问题及其影响因素.","authors":[{"authorName":"李双明","id":"5a3dbe14-d92e-445d-99ff-39cac36e54b9","originalAuthorName":"李双明"},{"authorName":"李建国","id":"d54fdea2-972f-4c4d-b9ab-464ffdfd2287","originalAuthorName":"李建国"},{"authorName":"沈军","id":"7677180c-0d81-41f6-9200-3687f6eb3660","originalAuthorName":"沈军"},{"authorName":"李金山","id":"f727f5a9-e2cc-4f5a-956f-6e38b6aa0920","originalAuthorName":"李金山"},{"authorName":"张军","id":"e590e2b5-2fae-40e3-be36-73f67d9cfcfb","originalAuthorName":"张军"},{"authorName":"傅恒志","id":"1fb2b825-d04c-4a12-a311-0a64a526672d","originalAuthorName":"傅恒志"}],"doi":"","fpage":"13","id":"0590126c-c06f-4d86-b27c-457600530f4d","issue":"4","journal":{"abbrevTitle":"GTYJXB","coverImgSrc":"journal/img/cover/GTYJXB.jpg","id":"30","issnPpub":"1001-0963","publisherId":"GTYJXB","title":"钢铁研究学报"},"keywords":[{"id":"9ba46cd9-3b47-4258-8020-e411ae3c9405","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"3b18c183-2d63-416e-a794-79c6d9a7ddf9","keyword":"电磁成形","originalKeyword":"电磁成形"},{"id":"7daa85df-b625-4665-9eaf-abf44ae8bbb5","keyword":"磁场","originalKeyword":"磁场"},{"id":"2766d717-e771-4ac0-bffc-83f88727932d","keyword":"电磁压力","originalKeyword":"电磁压力"},{"id":"092bde4c-de4b-453f-bca5-cf24cbb32c11","keyword":"界面","originalKeyword":"界面"}],"language":"zh","publisherId":"gtyjxb199904004","title":"液态金属电磁成形的数值计算","volume":"11","year":"1999"},{"abstractinfo":"分析了液态金属对固态金属材料的腐蚀形式,就国内外关于纯金属、合金材料在液态金属中的腐蚀行为及防护措施的研究进展作了评述,并对液态金属腐蚀的研究方向提出一些建议.","authors":[{"authorName":"刘树勋","id":"90a7e267-e8e9-46c4-94ba-584e6bcafda9","originalAuthorName":"刘树勋"},{"authorName":"李培杰","id":"e453413f-74ed-479f-a1ae-03b2c6933f1e","originalAuthorName":"李培杰"},{"authorName":"曾大本","id":"0cf41464-fc16-4963-94e3-00cb9f2cc787","originalAuthorName":"曾大本"}],"doi":"10.3969/j.issn.1002-6495.2001.05.007","fpage":"275","id":"ea7fa939-8814-4b07-9918-0379311cd316","issue":"5","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":"ad5c6d52-fc96-4779-bcb4-bb222cc0560f","keyword":"液态金属","originalKeyword":"液态金属"},{"id":"de9e2a36-ba18-44a1-ad4c-15ee8e151ad3","keyword":"腐蚀","originalKeyword":"腐蚀"},{"id":"c6e18c15-483c-4a2f-8825-a6c141f3a936","keyword":"Mg合金","originalKeyword":"Mg合金"}],"language":"zh","publisherId":"fskxyfhjs200105007","title":"液态金属腐蚀的研究进展","volume":"13","year":"2001"}],"totalpage":2572,"totalrecord":25717}