{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"在高阻硅基片上,我们制备了末端串联了dc-SQUID的λ/4谐振器,实现了可调超导共面波导谐振器.通过与谐振器耦合的传输线,我们测量了可调λ/4谐振器在外加磁通偏置下谐振频率的可调性,并将结果和理论值进行了比较和分析.","authors":[{"authorName":"汪橙","id":"f4453c2d-effa-49b0-841c-60db2477eda0","originalAuthorName":"汪橙"},{"authorName":"翟计全","id":"9b32a8bb-aade-49e4-b6cd-057b3a3d5ffd","originalAuthorName":"翟计全"},{"authorName":"潘佳政","id":"1fe15ed2-7d4a-4073-a18c-728ef688a127","originalAuthorName":"潘佳政"},{"authorName":"周渝","id":"d9557c90-de8a-41ae-99ea-e2f8586fc0fd","originalAuthorName":"周渝"},{"authorName":"范云益","id":"04257c71-28a6-484e-8e13-b6b3f6d74466","originalAuthorName":"范云益"},{"authorName":"钟先茜","id":"d76d7152-4e14-4053-9680-90624059aa2a","originalAuthorName":"钟先茜"},{"authorName":"曹志敏","id":"0a7cd833-9c2f-41fd-82e3-e4cb6cc758a0","originalAuthorName":"曹志敏"},{"authorName":"李永超","id":"8f751d66-1fe6-4223-8042-d1bcdd4a6684","originalAuthorName":"李永超"},{"authorName":"许伟伟","id":"bcb6f343-0d14-40e4-bdac-b573fff379f7","originalAuthorName":"许伟伟"}],"doi":"","fpage":"457","id":"8fa6c31a-66eb-4553-b77b-20b5978a3125","issue":"6","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"6e40921e-4967-477a-b517-2f478b337141","keyword":"可调谐振器","originalKeyword":"可调谐振器"},{"id":"90a1cf4d-e4d5-4324-9be0-13a77c286671","keyword":"超导共面波导谐振器","originalKeyword":"超导共面波导谐振器"},{"id":"7568bd47-9ff5-427a-8a90-864f277ab671","keyword":"传输线","originalKeyword":"传输线"}],"language":"zh","publisherId":"dwwlxb201506007","title":"传输线法测量可调谐振器","volume":"37","year":"2015"},{"abstractinfo":"和传统的共面波导谐振腔相比,超导共面波导谐振器(SCPWR)具有低损耗、高Q值等优势,可以方便地与超导量子比特相互耦合.通过在谐振器的中心导体中嵌入一系列的dc-SQUID,可以实现谐振器谐振频率的连续可调.我们利用深紫外曝光和电子束蒸发相结合的微加工工艺,制备了分别嵌入1个和3个dc-SQUID的SCPWR,并在极低温(mK)和低噪声环境下,测量了样品的传输特性.实验结果表明,嵌入1个和3个dc-SQUID的实验样品分别实现了60 MHz和187 MHz范围的谐振频率可调,实验数据与理论计算结果具有较好的一致性.","authors":[{"authorName":"钟先茜","id":"9ca26b85-616f-48c9-bbd4-aebd092dac6e","originalAuthorName":"钟先茜"},{"authorName":"翟计全","id":"c6e3b0c5-d657-4b01-aca7-bb1709c3d8d4","originalAuthorName":"翟计全"},{"authorName":"周渝","id":"d0ba1390-a6c7-4754-ac0d-7c3e2f05bad7","originalAuthorName":"周渝"},{"authorName":"汪橙","id":"1c279a0c-acfe-4c2a-bc67-969e92865af0","originalAuthorName":"汪橙"},{"authorName":"曹志敏","id":"2ffceca5-d9e7-4cb4-80de-efbe0fac1a40","originalAuthorName":"曹志敏"},{"authorName":"范云益","id":"e03d4ec9-23eb-49d7-b797-9051722bdbdc","originalAuthorName":"范云益"},{"authorName":"潘佳政","id":"a017bf3b-8ec8-4a75-a741-fbc93cdb1409","originalAuthorName":"潘佳政"},{"authorName":"李永超","id":"bc40a552-8c08-4d8b-b3eb-e5343bbbf855","originalAuthorName":"李永超"},{"authorName":"许伟伟","id":"9e426a3a-cb2a-4f47-a923-db9071489a01","originalAuthorName":"许伟伟"}],"doi":"","fpage":"477","id":"75f34a8b-a885-4452-894e-2d5f901210fd","issue":"6","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"e4a9537d-15e9-442d-a72c-2eaed657f58b","keyword":"共面波导谐振器","originalKeyword":"共面波导谐振器"},{"id":"3198fcc8-7a47-4299-bf4c-5f07684d3da9","keyword":"可调谐振器","originalKeyword":"可调谐振器"},{"id":"178098d2-a978-4325-a4bf-4acd079ae628","keyword":"超导量子比特","originalKeyword":"超导量子比特"},{"id":"72b26541-1a9b-45cc-ac04-7c01c2df4203","keyword":"电感","originalKeyword":"电感"}],"language":"zh","publisherId":"dwwlxb201506011","title":"可调半波长超导共面波导谐振器","volume":"37","year":"2015"},{"abstractinfo":"高温超导介质谐振器是毫米波应用的重要部件之一.本文研究了在确定频率下的介质谐振器的理论计算和实验结果,表明了采用园柱形GdBaCuO超导薄膜介质谐振器可以在毫米波段获得稳定的高Q谐振.","authors":[{"authorName":"唐义平","id":"637702ca-ec8e-49f3-a8f5-51d0189c18b9","originalAuthorName":"唐义平"},{"authorName":"魏斌","id":"c72dcad1-7a9c-43af-b353-e6634d7c194d","originalAuthorName":"魏斌"},{"authorName":"王瑞兰","id":"7fae8566-f2d2-4699-a432-46a682ee482b","originalAuthorName":"王瑞兰"},{"authorName":"李宏成","id":"9a1abc39-1158-413c-9d77-3c22f8abc1e6","originalAuthorName":"李宏成"},{"authorName":"曹必松","id":"30394e32-c109-4f3e-bad9-c4445f8eaa37","originalAuthorName":"曹必松"},{"authorName":"","id":"5e6c4dfd-1462-408d-a0e4-fdf089814334","originalAuthorName":""}],"doi":"10.3969/j.issn.1000-3258.2000.01.008","fpage":"43","id":"f9fcdd60-a236-4b6c-ac80-370e891d3ec8","issue":"1","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"bf53cde9-3834-475d-9a59-e634428ce7a3","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"dwwlxb200001008","title":"GdBaCuO毫米波介质谐振器","volume":"15","year":"2000"},{"abstractinfo":"本文报导了一种新型结构的高温超导薄膜梳齿谐振器.我们通过改变谐振器梳齿的长度,使谐振器的谐振频率可以从800MHz到1300MHz左右,这正是我们研制的Hi-Tc rf SQUID所需要的两个频段.我们对这种新型谐振器的谐振频率与几何尺寸的关系进行了数值拟合.测试了使用该种新型谐振器的Hi-Tc rf SQUID的噪声.","authors":[{"authorName":"茅海炎","id":"50daf892-e7d2-49b4-a3ea-2de44b9af839","originalAuthorName":"茅海炎"},{"authorName":"王福仁","id":"4bd37361-0b48-45ee-9afd-8992973da3b4","originalAuthorName":"王福仁"},{"authorName":"孟树超","id":"6446e8e3-a73a-443a-8fca-b6f43d66f831","originalAuthorName":"孟树超"},{"authorName":"毛博","id":"29fbc0c9-5398-43a4-84ef-2198cd6a5811","originalAuthorName":"毛博"},{"authorName":"李壮志","id":"db76d33a-196a-4293-b464-d81035a31dce","originalAuthorName":"李壮志"},{"authorName":"聂瑞娟","id":"2950b07f-16af-4fa6-b6cd-275694d9e865","originalAuthorName":"聂瑞娟"},{"authorName":"刘新元","id":"09f1ad0d-29e3-4d42-ada0-886ec5386771","originalAuthorName":"刘新元"},{"authorName":"戴远东","id":"fa2c7cc3-40e1-4a44-871c-353b9a69a4de","originalAuthorName":"戴远东"}],"doi":"10.3969/j.issn.1000-3258.2005.03.015","fpage":"269","id":"994481d5-a3aa-4333-b4a0-620f07315344","issue":"3","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"765578bc-716c-47a3-a2b6-3c074a615a92","keyword":"超导薄膜","originalKeyword":"超导薄膜"},{"id":"3f209010-b7b4-48d9-a8af-6fd1e644263f","keyword":"谐振器","originalKeyword":"谐振器"},{"id":"723a89a5-5681-4c35-a981-1349698af8fc","keyword":"射频量子干涉仪","originalKeyword":"射频量子干涉仪"},{"id":"5df11ace-f251-4e73-8339-1b809c34ee8a","keyword":"磁通噪声","originalKeyword":"磁通噪声"}],"language":"zh","publisherId":"dwwlxb200503015","title":"新型的高温超导薄膜梳齿谐振器","volume":"27","year":"2005"},{"abstractinfo":"采用一维Mason模型,研究了体声波谐振器的频率特性,探讨了压电薄膜AlN和上电极膜厚对谐振频率的影响,压电参数d33及压电薄膜与电极的厚度比率对机电耦合系数的影响,同时研究了谐振区域的面积和声能在衬底中的损耗对品质因数的影响.测量的体声波谐振器频率特性曲线与模拟结果吻合的较好.","authors":[{"authorName":"李位勇","id":"1213a921-0450-456a-ac66-0be3a516bd93","originalAuthorName":"李位勇"},{"authorName":"顾豪爽","id":"e0e8b230-5359-4fb7-8219-defd0d40fa30","originalAuthorName":"顾豪爽"},{"authorName":"张凯","id":"cd992006-3dab-46d4-b21b-23c5b5ded5a2","originalAuthorName":"张凯"},{"authorName":"胡明哲","id":"ff82b379-ffbe-4aee-8283-2c13243acde4","originalAuthorName":"胡明哲"},{"authorName":"胡光","id":"dc82da1e-3fe3-4dc5-befb-6a1b5bc48332","originalAuthorName":"胡光"}],"doi":"10.3969/j.issn.1007-4252.2006.05.016","fpage":"439","id":"250a2009-4acd-4481-8b76-b110510cc4b0","issue":"5","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":"3e697a7e-ff94-41ca-a292-e319cea853d7","keyword":"体声波谐振器","originalKeyword":"体声波谐振器"},{"id":"a4bae7ae-a424-4de2-848f-eb6f7c5920d4","keyword":"Mason模型","originalKeyword":"Mason模型"},{"id":"bef9d733-d9a3-4959-8e45-d31e9d1b6c87","keyword":"压电薄膜","originalKeyword":"压电薄膜"},{"id":"b51ef289-8b9f-4a24-b329-d3861ef68eb8","keyword":"频率特性","originalKeyword":"频率特性"}],"language":"zh","publisherId":"gnclyqjxb200605016","title":"AlN薄膜体声波谐振器研究","volume":"12","year":"2006"},{"abstractinfo":"研究了单端加载铁电叉指电容的微带半波长谐振器的压控特性.铁电材料为LaAlO3衬底上脉冲激光淀积的SrTiO3,叉指电容电极为金.测量了谐振器77K下的压控谐振性能.谐振频率在6GHz左右,70V偏压下的压控频率范围大于180MHz.在10～40V内,谐振频率与偏置电压之间呈良好的线性关系,谐振器的有载Q值为60～90.","authors":[{"authorName":"曹春海","id":"74b57993-a3eb-46e6-9131-cc1b8f1a71f2","originalAuthorName":"曹春海"},{"authorName":"徐筱乐","id":"d08bd2f4-7d75-4ee6-afeb-36829c879ecb","originalAuthorName":"徐筱乐"},{"authorName":"何世明","id":"01dde40d-02d5-4b9a-b002-8b88f88368c8","originalAuthorName":"何世明"},{"authorName":"周建明","id":"4dea7ada-3c00-47cf-8a2e-c8b011257a53","originalAuthorName":"周建明"},{"authorName":"刘兴钊","id":"641355ee-702d-4ee1-bf6f-b0b2f42f8164","originalAuthorName":"刘兴钊"},{"authorName":"王烨","id":"dfd59df6-f3fa-4900-ac10-40797387fcd3","originalAuthorName":"王烨"},{"authorName":"李言容","id":"5cd7f8bc-317d-4e2b-aba3-d3c49f6d8d42","originalAuthorName":"李言容"},{"authorName":"李拂晓","id":"7c332e2e-8136-4d0c-95ef-5a85fdcb6c3b","originalAuthorName":"李拂晓"}],"doi":"10.3969/j.issn.1000-3258.2005.03.012","fpage":"251","id":"98e7536c-2f46-4a71-b50d-12b0b8809973","issue":"3","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"af3765f3-823c-4bf8-a84e-ced0520f3998","keyword":"铁电材料","originalKeyword":"铁电材料"},{"id":"cd5e84ac-1edf-41ed-99ec-a9acb102095a","keyword":"压控器件","originalKeyword":"压控器件"},{"id":"33ceddb9-c50c-40b8-8e45-5655f1b66178","keyword":"微波谐振器","originalKeyword":"微波谐振器"}],"language":"zh","publisherId":"dwwlxb200503012","title":"铁电压控谐振器的研究","volume":"27","year":"2005"},{"abstractinfo":"宽带的高节数高温超导滤波器一直是滤波器设计和制作的难点.主要原因是强耦合的设计要求使得谐振器间距过小,制作精度难以达到.本文使用H型强耦合谐振器设计和制作了中心频率1335 MHz、相对带宽28%的14节高陡峭度超导滤波器.H型谐振器具有耦合系数高和结构紧凑、对称的性质.高的耦合系数使得H型谐振器适合用于宽带滤波器的设计;紧凑、对称的结构使得高节数的高性能宽带滤波器的实现成为可能.高温超导滤波器在无调谐情况下测试结果为S21<0.33 dB,S11<-11.3 dB,带外抑制超过70dB,矩形系数达到1.3,测试结果与设计结果符合得很好.","authors":[{"authorName":"陈炜","id":"0e60ba6e-c360-4a69-9297-a144d736f1ab","originalAuthorName":"陈炜"},{"authorName":"曹必松","id":"73fbc4dd-a322-4996-aebe-488dd14c3e9f","originalAuthorName":"曹必松"},{"authorName":"张晓平","id":"9255b73a-be4f-4817-810b-cb5899659e05","originalAuthorName":"张晓平"},{"authorName":"魏斌","id":"43dc16da-24bf-48ec-b6b2-eb9d3b9d2f15","originalAuthorName":"魏斌"},{"authorName":"郭旭波","id":"d5ff1707-ca6a-4861-94c3-e0a5e927a018","originalAuthorName":"郭旭波"},{"authorName":"彭慧丽","id":"66883f73-d236-45a3-83f7-9e280dc6e64a","originalAuthorName":"彭慧丽"},{"authorName":"金世超","id":"c312fe58-47d5-4a6d-9a25-b96cff05066e","originalAuthorName":"金世超"},{"authorName":"张盈","id":"1be191cd-dd63-41da-ba69-8067f5e4c301","originalAuthorName":"张盈"},{"authorName":"卢新祥","id":"c79a3ba4-ec5a-44f1-a8e6-7554177d21e9","originalAuthorName":"卢新祥"}],"doi":"","fpage":"127","id":"3e05f352-af20-449f-9321-8a92051b4602","issue":"2","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"e5ed6603-37df-4795-ab35-1b763a87185d","keyword":"高温超导滤波器","originalKeyword":"高温超导滤波器"},{"id":"a96fc4c2-8e43-4c58-8ce3-b700f1d3252b","keyword":"H型谐振器","originalKeyword":"H型谐振器"},{"id":"2af3271a-f6e2-408a-a309-b311508a9aeb","keyword":"宽带","originalKeyword":"宽带"}],"language":"zh","publisherId":"dwwlxb200902008","title":"基于H型谐振器的L波段宽带高温超导滤波器设计","volume":"31","year":"2009"},{"abstractinfo":"薄膜体声波滤波器作为一种发展高频滤波器的全新解决方案,比声表面波滤波器(SAWF)、陶瓷介质滤波器具有更高的Q值,低的损耗和在高频时具备更高的功率承受能力.介绍了薄膜体声波谐振器的研究历史和研究概况,薄膜体声波谐振器的原理和3种典型结构,具体阐述了薄膜体声波谐振器的关键技术及其材料体系的要求.","authors":[{"authorName":"谢和平","id":"01ef45f7-93f4-4d8e-ae36-e5d64fb11468","originalAuthorName":"谢和平"},{"authorName":"张树人","id":"b1f6695b-39ca-4c3d-b88d-18629128b95d","originalAuthorName":"张树人"},{"authorName":"杨成韬","id":"cd5781b2-6a67-4e82-9cd3-4c9bf91b413e","originalAuthorName":"杨成韬"},{"authorName":"张洪伟","id":"7712e119-d3c0-4104-a321-6024691e6ec1","originalAuthorName":"张洪伟"},{"authorName":"叶井红","id":"9ca1a414-18f5-41ff-8c76-57f53f4547ee","originalAuthorName":"叶井红"}],"doi":"","fpage":"330","id":"c4893602-8cba-4829-8184-8a89b2c11a7e","issue":"z2","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"0df6f7b7-2646-49b3-b771-6118ef1e9119","keyword":"微电子机械系统","originalKeyword":"微电子机械系统"},{"id":"1598bf03-6396-4c58-a3be-0e94e5677f3a","keyword":"薄膜体声波谐振器","originalKeyword":"薄膜体声波谐振器"},{"id":"5e16aed2-9067-415d-b906-c59a904c8e97","keyword":"SMR结构","originalKeyword":"SMR结构"},{"id":"bf04c25e-b5b1-412e-80c4-8234e4b13f23","keyword":"悬空结构","originalKeyword":"悬空结构"}],"language":"zh","publisherId":"cldb2006z2096","title":"薄膜体声波谐振器的研究进展","volume":"20","year":"2006"},{"abstractinfo":"高温超导滤波器已在移动通信、射电天文、雷达探测等多个领域获得了重要应用．当前高温超导滤波器的研究和应用主要集中于10GHz以下的频段，针对超高频段（〉10GHz）高温超导滤波器的研究很少．本文设计优化了具有无载Q值高、耦合强、尺寸短等特点的H型阶跃阻抗谐振器，并讨论了超高频段滤波器端口激发源的电容效应对滤波器响应的影响，最后采用优化的H型谐振器，应用去嵌入（De-Embed）设计方法消除端口效应，设计了中心频率为16GHz，相对带宽12．5％的6节高温超导滤波器．研制的超导滤波器在未经调谐的情况下，测试结果与仿真结果符合得很好，插入损耗小于0．3dB，反射损耗优于-14dB，带外抑制达到了-70dB．","authors":[{"authorName":"李启荣","id":"0b9f29b3-c8d8-4c32-b37d-17d25519cbbe","originalAuthorName":"李启荣"},{"authorName":"魏斌","id":"b7572374-5ca6-4486-beaf-6746530a8710","originalAuthorName":"魏斌"},{"authorName":"张晓平","id":"3846e66a-9ea9-4dfe-afa0-6d09f3fa5fdc","originalAuthorName":"张晓平"},{"authorName":"郭旭波","id":"6b3bce45-04cc-430f-bc0a-bf5581c8cdb2","originalAuthorName":"郭旭波"},{"authorName":"应志军","id":"551e7d0c-012e-4b5d-8c52-644020ce12a1","originalAuthorName":"应志军"},{"authorName":"冯骋","id":"dcfa4d7d-870e-4b95-b910-882731041838","originalAuthorName":"冯骋"},{"authorName":"曹必松","id":"2b8bd5e2-5e89-4495-b511-d19bf5614a3f","originalAuthorName":"曹必松"}],"doi":"","fpage":"86","id":"ec13270e-cf48-41cf-8db2-bef9bba5812c","issue":"2","journal":{"abbrevTitle":"DWWLXB","coverImgSrc":"journal/img/cover/DWWLXB.jpg","id":"19","issnPpub":"1000-3258","publisherId":"DWWLXB","title":"低温物理学报 "},"keywords":[{"id":"e200733d-fa1a-4153-adf1-0f5619f28c4d","keyword":"高温超导滤波器","originalKeyword":"高温超导滤波器"},{"id":"b0652811-2bb9-4c7a-b15f-7e9dae79dde2","keyword":"Ku波段","originalKeyword":"Ku波段"},{"id":"b6ad07ab-fd75-491d-b1a7-62502a41c4fe","keyword":"H型谐振器","originalKeyword":"H型谐振器"}],"language":"zh","publisherId":"dwwlxb201202002","title":"基于H型谐振器的Ku波段高温超导滤波器设计","volume":"34","year":"2012"},{"abstractinfo":"研究了石英晶体谐振器在强磁场影响下频率变化的原因.结果表明石英晶体谐振器的磁性支架在受到磁场的影响下产生相应的应力,该应力沿石英晶片的边缘作用于石英晶体引起谐振器频率的变化.该实验结果对如何减小磁场对石英晶体谐振器的影响有一定的参考价值.","authors":[{"authorName":"李辉","id":"3b95ac5d-2427-47ac-a5f8-aff40e3683ea","originalAuthorName":"李辉"},{"authorName":"陈向东","id":"c72a4fd2-92c7-4709-9028-a05dea22658c","originalAuthorName":"陈向东"},{"authorName":"杜广涛","id":"8d7b2068-f877-4c88-a285-56783d0e37fa","originalAuthorName":"杜广涛"}],"doi":"","fpage":"383","id":"5de3deb4-98ec-44ac-baca-63f925c78f1c","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":"e2db5a8e-5c0f-4bb4-9afc-a830a9a1d5f6","keyword":"石英晶体谐振器","originalKeyword":"石英晶体谐振器"},{"id":"c15e6d65-44fe-4791-b8eb-29948d33e4a2","keyword":"磁场","originalKeyword":"磁场"},{"id":"c8d6ca02-f26e-4a78-a1cb-72cb2a1022c5","keyword":"力-频效应","originalKeyword":"力-频效应"}],"language":"zh","publisherId":"rgjtxb98201102019","title":"石英谐振器在强磁场中的磁-敏特性","volume":"40","year":"2011"}],"totalpage":1125,"totalrecord":11244}