{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"报道了罗丹明B掺杂PMMA材料制作过程及材料吸收和荧光光谱实验.吸收光谱表明,PMMA样品从紫外到近红外范围存在较小的吸收.罗丹明B/PMMA样品吸收光谱主要反映罗丹明B的吸收特征,其吸收峰中心波长位于550nm.荧光光谱显示,以630nm激发,反斯托克斯荧光峰位于595nm,能量差为0.11eV.该材料辐射反斯托克斯荧光,可用于激光制冷领域的研究.","authors":[{"authorName":"吴云龙","id":"5a8b5dbe-647c-4286-8869-9fed78b0b31e","originalAuthorName":"吴云龙"},{"authorName":"熊玉峰","id":"aefde0ff-548c-4782-98ab-6372b4456c82","originalAuthorName":"熊玉峰"},{"authorName":"房晖","id":"f363e0e8-721b-42e6-96b5-4a47a3e68a84","originalAuthorName":"房晖"}],"doi":"10.3969/j.issn.1007-4252.2004.03.023","fpage":"383","id":"27c60b3c-b52c-46c0-9a4f-9d904d03c7b6","issue":"3","journal":{"abbrevTitle":"GNCLYQJXB","coverImgSrc":"journal/img/cover/GNCLYQJXB.jpg","id":"34","issnPpub":"1007-4252","publisherId":"GNCLYQJXB","title":"功能材料与器件学报 "},"keywords":[{"id":"7eec47c8-9adc-4fb0-8fd0-ab4779828cee","keyword":"激光制冷","originalKeyword":"激光制冷"},{"id":"1f177b96-10d6-4ec2-9484-7b3eac5a089a","keyword":"反斯托克斯荧光","originalKeyword":"反斯托克斯荧光"},{"id":"64c96264-9b88-4a86-93c9-8fb2118fbf74","keyword":"罗丹明B","originalKeyword":"罗丹明B"},{"id":"47b9dc4a-7305-4b0c-9ecd-a56f02c15e94","keyword":"PMMA","originalKeyword":"PMMA"}],"language":"zh","publisherId":"gnclyqjxb200403023","title":"一种潜在的激光制冷介质-罗丹明B掺杂PMMA","volume":"10","year":"2004"},{"abstractinfo":"我们利用光致发光(PL)和激发光谱(PLE)技术研究了GaAs量子阱的光谱性质,在GaAs量子阱的光致发光中观察到上转换发光,首次提出GaAs量子阱结构可能实现激光制冷,探索了GaAs量子阱结构的发光机理。","authors":[{"authorName":"张喜田","id":"e0441096-7b0d-4bb8-94cd-697751b279ec","originalAuthorName":"张喜田"},{"authorName":"张伟力","id":"4cf834ff-f9f1-4aac-a539-74d435a03f12","originalAuthorName":"张伟力"},{"authorName":"高红","id":"a965d396-75a9-4b3a-a670-68fa23d57fb4","originalAuthorName":"高红"},{"authorName":"许武","id":"ca864380-c209-4721-a1fd-38be6c2abe34","originalAuthorName":"许武"},{"authorName":"秦伟平","id":"1e36e747-c5fe-4197-bb84-400ce16e962f","originalAuthorName":"秦伟平"},{"authorName":"张家骅","id":"99b8abea-bf3d-41d6-ba0f-584d7230d8d5","originalAuthorName":"张家骅"},{"authorName":"陈宝玖","id":"2a2f6856-d4f2-4dc4-b400-d564ea723ec4","originalAuthorName":"陈宝玖"}],"doi":"10.3969/j.issn.1000-985X.2001.02.010","fpage":"159","id":"5c949073-6e0a-4324-be85-afebd0edaf44","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":"9b7f60f8-1c25-4715-b243-a49ec0293107","keyword":"光致发光","originalKeyword":"光致发光"},{"id":"1b6f1128-24f6-4ccd-a4a3-803b9f5febdf","keyword":"激发光谱","originalKeyword":"激发光谱"},{"id":"70f35b8b-1d94-4614-8c3d-dcbc25a539fe","keyword":"量子阱","originalKeyword":"量子阱"},{"id":"d7167842-18a8-4fc5-9298-532bb2c6cf7e","keyword":"激光制冷","originalKeyword":"激光制冷"},{"id":"b56432b5-953f-4208-9745-4025a37a7866","keyword":"上转换","originalKeyword":"上转换"}],"language":"zh","publisherId":"rgjtxb98200102010","title":"半导体GaAs—Ga0.65Al0.35As多量子阱的光谱性质及实现激光制冷的可能","volume":"30","year":"2001"},{"abstractinfo":"激光诱导反斯托克斯荧光制冷,是近年来刚刚起步的一个全新的制冷概念.它在体积、重量、振动、电磁、寿命等方面都具有其他制冷方式所无法比拟的优点,针对空间红外探测器致冷苛刻的空间环境具有良好的适应性.详细介绍了反斯托克斯荧光制冷目前发展的状况,展望了它在空间遥感领域的应用前景.","authors":[{"authorName":"房晖","id":"470e110b-9a97-4824-8dcc-1e5a21ab0079","originalAuthorName":"房晖"},{"authorName":"吴云龙","id":"ae47cd2d-eb88-45ca-9be3-fe17fe02f147","originalAuthorName":"吴云龙"},{"authorName":"熊玉峰","id":"954d1b3f-5ae1-452b-8826-1a4995bc5659","originalAuthorName":"熊玉峰"},{"authorName":"乔延利","id":"093436ba-0f3b-442d-a5f4-f4b9ddc96494","originalAuthorName":"乔延利"},{"authorName":"王乐意","id":"c21d216a-ed90-431d-9d74-b26baace67e1","originalAuthorName":"王乐意"},{"authorName":"易维宁","id":"29044e34-e84f-494c-8a25-66b8df2c54c6","originalAuthorName":"易维宁"}],"doi":"10.3969/j.issn.1007-5461.2004.04.003","fpage":"411","id":"a32da7ab-1d0e-401f-97a0-e3de332c526d","issue":"4","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":"e3ca262a-33e2-4256-9e79-e5773f72e062","keyword":"激光技术","originalKeyword":"激光技术"},{"id":"ecd57c4f-d0dd-4e59-8d82-dc30571eb5e6","keyword":"制冷","originalKeyword":"制冷"},{"id":"c342f91a-9dc7-40c8-964c-642671661c8f","keyword":"空间遥感","originalKeyword":"空间遥感"},{"id":"9d8bf6d1-639d-4fcf-9c51-6648b97e4f28","keyword":"反斯托克斯荧光","originalKeyword":"反斯托克斯荧光"},{"id":"f6b16bad-22d4-4e4c-af60-a4c518224a72","keyword":"激光制冷","originalKeyword":"激光制冷"}],"language":"zh","publisherId":"lzdzxb200404003","title":"反斯托克斯荧光制冷及其在空间遥感领域的应用","volume":"21","year":"2004"},{"abstractinfo":"本文运用微槽群复合相变和热电制冷(TEC)技术来实现激光器系统低温下的高热流密度散热.通过对不同工质在不同充液率下的实验研究发现,工质和充液率对系统的运行状况有重要的影响.在选用甲醇作为循环工质,并且在系统充液率为1.5的情况下,系统能够达到所需的散热冷却效果;本文实验分析了冷凝器的工作状况对蒸发器表面温度的影响,提出通过提高TEC制冷片的制冷量和强化铜散热片的散热能力来降低冷凝器的温度,进而降低蒸发器的温度.","authors":[{"authorName":"聂雪磊","id":"48c99dcc-210c-4d4b-8826-ed4c01a178ca","originalAuthorName":"聂雪磊"},{"authorName":"王涛","id":"6729c48e-9257-4475-b6e1-8ba7d7050bf9","originalAuthorName":"王涛"},{"authorName":"胡学功","id":"9cb90041-1a65-4bd1-996c-520bcf513fd2","originalAuthorName":"胡学功"},{"authorName":"唐大伟","id":"dc4be471-231f-46a2-92ac-adc932f7bb61","originalAuthorName":"唐大伟"},{"authorName":"谢宁宁","id":"131d4d15-a57c-4ab2-8d1f-b2e9375dd7ba","originalAuthorName":"谢宁宁"}],"doi":"","fpage":"1347","id":"2545e4c4-7ea6-40b7-873e-44034b2207e6","issue":"8","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":"11ebe698-1b90-4106-84f0-6a45845a8202","keyword":"激光器冷却","originalKeyword":"激光器冷却"},{"id":"1beb9f85-3a01-4dad-9368-7bdcbd3e90bd","keyword":"微槽群","originalKeyword":"微槽群"},{"id":"b7e37786-3646-40e7-9e7d-c80fa7ee838d","keyword":"热电制冷","originalKeyword":"热电制冷"}],"language":"zh","publisherId":"gcrwlxb200908024","title":"微槽群相变与热电制冷结合的激光器冷却系统","volume":"30","year":"2009"},{"abstractinfo":"本文介绍了利用数字式温度传感器DS18B20构造大功率激光二极管恒温制冷系统的方法.该系统利用DS18B20作为温度传感元件,单片机作为核心控制部件控制半导体制冷器对大功率激光二极管进行制冷和制热.该系统具有体积小、外围电路简单、温控精度高等特点,温控精度可达士0.1℃.","authors":[{"authorName":"戚俊","id":"5a13a836-742d-4d73-98d1-e59a672b86e3","originalAuthorName":"戚俊"},{"authorName":"李季","id":"c5666a60-d407-425f-9954-7f79b8445bdd","originalAuthorName":"李季"},{"authorName":"陈结祥","id":"544b2704-23f6-45c0-998e-4700b973171c","originalAuthorName":"陈结祥"}],"doi":"10.3969/j.issn.1007-5461.2002.02.014","fpage":"162","id":"fb4ddecf-fc09-4e57-b9cc-9e42f243ff40","issue":"2","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":"5a632f79-8546-4bd2-8702-5d4bd420c106","keyword":"数字式温度传感器","originalKeyword":"数字式温度传感器"},{"id":"1805061e-2793-4de5-babc-ada264571583","keyword":"DS18B20","originalKeyword":"DS18B20"},{"id":"ee524593-56f5-4e7e-bf26-41643cad720c","keyword":"温度控制","originalKeyword":"温度控制"},{"id":"3c192b6c-870c-4230-8575-8c8a98a2f097","keyword":"大功率激光二极管","originalKeyword":"大功率激光二极管"},{"id":"5afc9bbb-d52b-47d0-b5a3-f271d11dfd9c","keyword":"半导体致冷器","originalKeyword":"半导体致冷器"}],"language":"zh","publisherId":"lzdzxb200202014","title":"DS18B20在大功率激光二极管恒温制冷系统中的应用","volume":"19","year":"2002"},{"abstractinfo":"本文采用有限容积法对制冷剂喷射冷却(Cryogen spray cooling,CSC)过程进行了数值分析,研究了皮肤组织温度场随时间、空间的分布规律,初步分析了喷射过程中可能发生的冷损伤.探讨了不同喷嘴距离对于喷射换热过程的影响.结果表明:本文的模拟结果定性符合文献中的试验结果;由于制冷剂喷射不均匀性带来的冷保护不足问题可以通过适当延长冷却时间(如大于80 ms)加以避免;低温制冷剂带来的冷损伤仅局限于浅表皮层,不会对人体造成伤害;喷射距离对于整个换热过程的影响非常有限,可以较为自由地布置喷嘴位置.","authors":[{"authorName":"李东","id":"42d1f6e5-9ae5-4806-a1f7-b0dfdd8059ec","originalAuthorName":"李东"},{"authorName":"何雅玲","id":"8ad448d3-b054-4412-9d27-f5845ecb2a00","originalAuthorName":"何雅玲"},{"authorName":"王国祥","id":"b420c952-32df-4eee-a16f-04dca9cd03e5","originalAuthorName":"王国祥"},{"authorName":"刘迎文","id":"aa731827-4d70-4db3-9f6b-2a9ac2316eca","originalAuthorName":"刘迎文"},{"authorName":"肖杰","id":"417519fe-2f3a-411d-b1dc-c9eead04808b","originalAuthorName":"肖杰"}],"doi":"","fpage":"2107","id":"4f224b67-a61f-4ab2-9b67-7b65b467f0e6","issue":"12","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":"00e5d699-9570-4111-bbd3-56efa9896e79","keyword":"制冷剂喷射冷却","originalKeyword":"制冷剂喷射冷却"},{"id":"e4292823-faef-4d08-b11c-368b9011e602","keyword":"葡萄酒色斑","originalKeyword":"葡萄酒色斑"},{"id":"f823076f-d56d-4b0d-95e4-bc6ee2c6d3e9","keyword":"数值模拟","originalKeyword":"数值模拟"}],"language":"zh","publisherId":"gcrwlxb200812035","title":"激光治疗PWS中制冷剂喷射冷却过程的数值模拟","volume":"29","year":"2008"},{"abstractinfo":"就 Gd5Si2Ge2化合物的激光熔覆成形工艺作了初步研究.实验表明: Gd5Si2Ge2在 Gd基体上可以实现良好的冶金结合.在最小厚度不小于 1mm的基板上,控制激光参数可以使熔覆层的稀释度保持在 10%左右.","authors":[{"authorName":"付浩","id":"d5b598d9-5e6f-4059-896d-e4d587a9f888","originalAuthorName":"付浩"},{"authorName":"陈云贵","id":"4c9c8161-8a9b-4474-b012-9af960d88c00","originalAuthorName":"陈云贵"},{"authorName":"唐永柏","id":"f3737991-86b5-47b8-9331-3b4cc14706ff","originalAuthorName":"唐永柏"},{"authorName":"涂铭旌","id":"e2fe1567-a35f-4f6e-bdc5-8f1de2ad89fe","originalAuthorName":"涂铭旌"}],"doi":"","fpage":"387","id":"4efba72b-b779-4832-9be6-ae6b1b3cbc44","issue":"5","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"2fae0d89-7a3b-4f03-9e2f-3250aee042a4","keyword":"磁制冷材料","originalKeyword":"磁制冷材料"},{"id":"c20bc35b-781e-4741-86ea-1e73879f3ec1","keyword":"激光熔覆","originalKeyword":"激光熔覆"},{"id":"c5ed6f9d-1bc4-4413-9130-0ae1b7861336","keyword":"金属间化合物","originalKeyword":"金属间化合物"},{"id":"5c6587dd-0855-4ed3-bf32-11796a0288c7","keyword":"钆","originalKeyword":"钆"}],"language":"zh","publisherId":"xyjsclygc200305017","title":"Gd5Si2Ge2/Gd室温磁制冷复合材料激光熔覆成形工艺研究","volume":"32","year":"2003"},{"abstractinfo":"提出了吸收制冷循环的极限制冷温度概念,以自行复叠吸收制冷(ACAR)循环为例分析了多种因素对极限制冷温度和COP等性能参数的影响.分析结果表明制冷剂的配比是影响ACAR循环极限制冷温度等性能的关键因素,为此计算得到了理论最佳制冷剂配比.同时,分析了传统吸收制冷循环的特性,并在相同条件下和ACAR循环进行了比较,结果表明ACAR循环可以获得低得多的制冷温度,具有高得多的COP,用于深度冷冻具有独特的优势.","authors":[{"authorName":"何一坚","id":"e4b8b357-8b82-4fba-ba9d-40d5a78a952c","originalAuthorName":"何一坚"},{"authorName":"陈光明","id":"a7181436-e40e-4a44-aadd-70fffdcc1fce","originalAuthorName":"陈光明"}],"doi":"","fpage":"917","id":"9f20944b-5c47-44b2-a91a-7132b02fae12","issue":"6","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":"43bc4fb0-9422-4ecc-b324-5958d0e0a1c1","keyword":"吸收制冷","originalKeyword":"吸收制冷"},{"id":"b781055a-e1b0-4a71-8e97-297ebe637657","keyword":"自行复叠","originalKeyword":"自行复叠"},{"id":"4e3574ea-5e20-4119-97fa-37ee72337a46","keyword":"深度冷冻","originalKeyword":"深度冷冻"}],"language":"zh","publisherId":"gcrwlxb200406005","title":"吸收制冷循环极限制冷温度研究","volume":"25","year":"2004"},{"abstractinfo":"制冷剂闪蒸瞬态喷雾冷却是皮肤激光手术中的重要辅助手段,既能够提高激光能量改善治疗效果,又可以保护表皮正常组织不受激光热损伤.针对制冷剂闪蒸瞬态喷雾冷却过程中所涉及的喷雾动力学和复杂沸腾相变传热等学术难点问题,本文建立了制冷剂闪蒸喷雾冷却实验台,对R134a制冷剂闪蒸喷雾冷却的喷雾特性和表面传热特性进行实验研究,得到了制冷剂闪蒸瞬态喷雾冷却特定喷雾条件下的喷雾特性和表面传热特性,以期为皮肤激光临床手术提供定量的指导.","authors":[{"authorName":"周致富","id":"02839f5b-2858-4735-b5b1-7090f46d6cca","originalAuthorName":"周致富"},{"authorName":"吴威涛","id":"76f1986a-09a4-44d3-a574-224ad2631bdc","originalAuthorName":"吴威涛"},{"authorName":"龚政","id":"9beb07e0-969d-405c-b00e-092875c61402","originalAuthorName":"龚政"},{"authorName":"王国祥","id":"eef517f2-6849-4275-9c82-62b704cdf97a","originalAuthorName":"王国祥"},{"authorName":"陈斌","id":"c5707226-0bb5-40cb-85d1-c0b2600cbac8","originalAuthorName":"陈斌"},{"authorName":"王跃社","id":"86ad7fde-c29e-4b31-a30a-b71b7c725be2","originalAuthorName":"王跃社"}],"doi":"","fpage":"977","id":"47f39eea-2eb9-47bf-8213-8cebed7b9fd8","issue":"6","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":"a17610ff-217e-4553-b8ab-060147b5ddaf","keyword":"皮肤激光手术","originalKeyword":"皮肤激光手术"},{"id":"9cc1089f-2149-49da-b3d3-302de43db634","keyword":"闪蒸瞬态喷雾","originalKeyword":"闪蒸瞬态喷雾"},{"id":"8bb32347-0818-4759-806c-d247613b52eb","keyword":"R134a","originalKeyword":"R134a"},{"id":"ba4e8b45-0049-4678-9eef-299c41b59abf","keyword":"传热特性","originalKeyword":"传热特性"}],"language":"zh","publisherId":"gcrwlxb201106020","title":"R134制冷剂闪蒸瞬态喷雾和传热特性的实验研究","volume":"32","year":"2011"},{"abstractinfo":"室温磁制冷技术的进步有助于推进室温磁制冷技术的实用化进程,是目前研究的热点.通过列举近几年室温磁制冷技术的一些新进展,诸如千瓦级磁制冷机的开发,拓宽温跨的技术,磁制冷机新分类法以及快速成型技术制作复杂形状磁制冷工质等,这些技术进步将会拓展室温制冷技术的应用领域.","authors":[{"authorName":"金培育","id":"f5cc2877-e459-4c54-a19a-2c686feab158","originalAuthorName":"金培育"},{"authorName":"黄焦宏","id":"bb766ad2-61be-48ea-b5bb-103d568575e3","originalAuthorName":"黄焦宏"},{"authorName":"杨占峰","id":"f2a1a01d-94e3-42d5-81d6-cd550babb9df","originalAuthorName":"杨占峰"},{"authorName":"闫宏伟","id":"f2799c19-c4fa-4f9c-a9a7-932778638508","originalAuthorName":"闫宏伟"},{"authorName":"刘翠兰","id":"56daf516-405d-4092-b36d-5378170e5572","originalAuthorName":"刘翠兰"},{"authorName":"程娟","id":"47443970-6f8b-45a7-a19c-f818f1bff955","originalAuthorName":"程娟"}],"doi":"","fpage":"101","id":"334eb553-f2c4-4050-9865-64bc272afcb3","issue":"3","journal":{"abbrevTitle":"XT","coverImgSrc":"journal/img/cover/XT.jpg","id":"65","issnPpub":"1004-0277","publisherId":"XT","title":"稀土"},"keywords":[{"id":"da3b46d9-9a7c-4005-b7d8-6bfc613c2dc7","keyword":"室温磁制冷技术","originalKeyword":"室温磁制冷技术"},{"id":"a7e2b886-8b1b-4252-b42d-0adad112fe9c","keyword":"室温磁制冷机","originalKeyword":"室温磁制冷机"},{"id":"4043c78e-fc28-4f66-b4e0-c7e3b99ad149","keyword":"室温磁制冷机分类","originalKeyword":"室温磁制冷机分类"},{"id":"2455a1fa-69ab-4cf0-8041-13d0e4175d9c","keyword":"磁制冷工质","originalKeyword":"磁制冷工质"}],"language":"zh","publisherId":"xitu201403020","title":"磁制冷技术的新进展","volume":"35","year":"2014"}],"totalpage":684,"totalrecord":6836}