{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"对于近年来清华大学与美国合作研究组在原子核结构实验研究中有关奇A核的多声子γ振动带方面的进展进行了评述。研究人员通过有效的国际合作,识别了质量数A=100丰中子核区的奇A核103Nb,105Mo,107Tc和109Tc中的两声子γ振动带,这是迄今为止国际上在奇A核的结构研究中发现的仅有的4例这样的结构。对于实验方法、研究结果以及这些多声子γ振动带的特性进行了评述,并对目前在多声子带其他方面的研究及今后进一步的工作进行了概述。","authors":[{"authorName":"朱胜江","id":"351d1824-1773-4284-ae7b-857f5c79b8fc","originalAuthorName":"朱胜江"},{"authorName":"J.H. Hamilton","id":"2b64af43-63ed-4be2-9127-b50f81aae013","originalAuthorName":"J.H. Hamilton"},{"authorName":"A.V. Ramayya","id":"71a30d1c-05cd-403d-916d-a2638008ffbb","originalAuthorName":"A.V. Ramayya"},{"authorName":"王建国","id":"a67b1051-f9ad-4883-914f-a03b5930c1ae","originalAuthorName":"王建国"},{"authorName":"丁怀博","id":"8c15b317-80bf-4649-9be1-d06eec9b8332","originalAuthorName":"丁怀博"},{"authorName":"顾龙","id":"9c0b4e9b-ee98-4ab0-9c5d-bbbc084e7b61","originalAuthorName":"顾龙"},{"authorName":"J.K. Hwang","id":"76490e67-929f-488c-a15b-cf6b17e4e2ad","originalAuthorName":"J.K. Hwang"},{"authorName":"K. Li","id":"97e83ac4-ef0a-427a-a946-48265811c0c2","originalAuthorName":"K. Li"},{"authorName":"S.H. Liu","id":"a731b559-c15a-482b-838e-c03d3dfcb38c","originalAuthorName":"S.H. Liu"},{"authorName":"N.T. Brewer","id":"fa0d2aca-7d63-4772-bfeb-b04112917afe","originalAuthorName":"N.T. Brewer"},{"authorName":"Y.X. Luo","id":"25837386-b4af-42ee-8f5d-01b0de6afeeb","originalAuthorName":"Y.X. Luo"},{"authorName":"J.O. Rasmussen","id":"08612e95-a6c0-4ac3-81fd-ecf859f392a6","originalAuthorName":"J.O. Rasmussen"},{"authorName":"I.Y. Lee","id":"528b5ef4-10e7-46fb-b3e7-bce124abc3f5","originalAuthorName":"I.Y. Lee"},{"authorName":"徐强","id":"3181b716-1961-4c95-b492-ad817f6cbee5","originalAuthorName":"徐强"},{"authorName":"杨韵颐","id":"18784e9a-f605-472c-b561-6b7241cbf973","originalAuthorName":"杨韵颐"},{"authorName":"肖志刚","id":"1f14a5ec-4199-4870-bd25-2ed28b99b4fc","originalAuthorName":"肖志刚"},{"authorName":"李红洁","id":"e0a1a249-667a-4c41-ab25-8a1377634e8e","originalAuthorName":"李红洁"},{"authorName":"马文超","id":"287dd204-2890-4885-b085-a38cdd400785","originalAuthorName":"马文超"}],"doi":"10.11804/NuclPhysRev.30.02.099","fpage":"99","id":"774b6efe-091b-4538-8791-e0544c848ec5","issue":"2","journal":{"abbrevTitle":"YZHWLPL","coverImgSrc":"journal/img/cover/YZHWLPL.jpg","id":"78","issnPpub":"1007-4627","publisherId":"YZHWLPL","title":"原子核物理评论 "},"keywords":[{"id":"9a173975-8ec8-42b5-81f4-56a41bfd5526","keyword":"原子核结构","originalKeyword":"原子核结构"},{"id":"c902ed25-5acc-401c-8acf-83f3b474911c","keyword":"高自旋态","originalKeyword":"高自旋态"},{"id":"cf6cc1f7-9275-4471-9e14-a7f7f732f370","keyword":"多声子γ振动带","originalKeyword":"多声子γ振动带"},{"id":"0ad0b0fb-a955-4db5-b8f5-07fcfae9a3f1","keyword":"奇A核","originalKeyword":"奇A核"}],"language":"zh","publisherId":"yzhwlpl201302001","title":"奇A核的多声子γ振动带实验研究进展","volume":"","year":"2013"},{"abstractinfo":"硬质芯体及其包覆层构成的复合结构称为散射单元,散射单元按照特定的排列方式可以构成声子晶体.文章采用有限元方法分别计算了立方散射单元构成的一维声子晶体及简单立方结构三维声子晶体的振动特性,结果表明,两种声子晶体的振动带隙有较好的一致性,因此,对三维声子晶体振动带隙的研究可以简化为对一维声子晶体振动带隙的研究.叠加层数、芯体材料对一维声子晶体振动带隙的影响在文中进行了讨论.最后,声子晶体的振动特性测试结果验证了文中的结论.","authors":[{"authorName":"温激鸿","id":"bcb4a93e-be8d-48d4-a297-6d6b62f37984","originalAuthorName":"温激鸿"},{"authorName":"刘耀宗","id":"a0cddda2-ae0e-4999-ab7f-322429d7f08b","originalAuthorName":"刘耀宗"},{"authorName":"郁殿龙","id":"04eecafc-1452-46ec-a58b-0a4090b54b79","originalAuthorName":"郁殿龙"},{"authorName":"王刚","id":"195759f0-fb33-4c01-ac85-9bb048a8e676","originalAuthorName":"王刚"},{"authorName":"赵宏刚","id":"797f512f-5b3b-40d8-955f-f899b3b6b8de","originalAuthorName":"赵宏刚"}],"doi":"10.3969/j.issn.1000-985X.2004.03.019","fpage":"358","id":"b56181da-4889-4d4d-8602-49968370914a","issue":"3","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":"e8677626-b1e0-4edc-9912-ffcf6c57587f","keyword":"声子晶体","originalKeyword":"声子晶体"},{"id":"88ae2536-d728-4a02-886d-2a7856f101d3","keyword":"弹性波带隙","originalKeyword":"弹性波带隙"},{"id":"ec113776-05b3-4034-8956-629de239d426","keyword":"振动带隙","originalKeyword":"振动带隙"}],"language":"zh","publisherId":"rgjtxb98200403019","title":"基于散射单元的声子晶体振动带隙研究","volume":"33","year":"2004"},{"abstractinfo":"从弦的波动方程出发,采用传递矩阵法,分析了无限周期的布拉格型声子晶体弦的横向振动能带结构.研究表明布拉格型声子晶体弦具有横向振动带隙,弦内拉力对带隙特性有显著影响,可以方便地用于带隙调节.利用有限元软件和Matlab软件对有限周期的布拉格型声子晶体弦的横向振动传输特性分别进行了仿真和数值计算,结果表明带隙范围内表现出明显的振动衰减,不同拉力条件下的带隙变化也很好地验证了理论分析结果.","authors":[{"authorName":"舒海生","id":"8e4d284f-149b-4106-9dd3-b742c94c627f","originalAuthorName":"舒海生"},{"authorName":"董立强","id":"78d92b27-5797-4bc0-a77b-3b255e07d7a3","originalAuthorName":"董立强"},{"authorName":"李世丹","id":"29cb7ab8-ba05-4c5d-9717-ea805e6e94bd","originalAuthorName":"李世丹"},{"authorName":"刘伟","id":"e4ff9a4a-a226-4e7d-921d-035bc4789d42","originalAuthorName":"刘伟"},{"authorName":"林航","id":"7e1fd505-c56a-4d17-b39b-8704cd7d439e","originalAuthorName":"林航"}],"doi":"","fpage":"1918","id":"4e73de1a-6e37-4e31-b7a1-2eb1c885aa60","issue":"9","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":"5375493a-78db-48cd-a654-6df096d696ca","keyword":"声子晶体","originalKeyword":"声子晶体"},{"id":"c1f92e68-1aae-4ab2-b075-6756ce5aff11","keyword":"弦","originalKeyword":"弦"},{"id":"4dd98124-fe27-4a83-b8d1-50ecc7123ae7","keyword":"传递矩阵法","originalKeyword":"传递矩阵法"},{"id":"7507ff98-d8fd-4faa-b3ae-b3818c513d25","keyword":"能带结构","originalKeyword":"能带结构"},{"id":"5513142d-925f-4942-910f-e8b652916c09","keyword":"带隙","originalKeyword":"带隙"}],"language":"zh","publisherId":"rgjtxb98201309036","title":"布拉格型声子晶体弦的横向振动带隙研究","volume":"42","year":"2013"},{"abstractinfo":"基于平面波展开法研究二维声子晶体振动带隙的最佳参数特性,数值计算基体为硅橡胶散射体为铝时正方格子和三角格子二维声子晶体的XY模式和Z模式的带隙特性,得到三角格子声子晶体更易形成较宽振动带隙.改变散射体材料特性,模拟得到散射体密度大的材料能够形成较宽带隙.研究结论对于声子晶体应用制作提供理论参考.","authors":[{"authorName":"徐丽","id":"2bccd4ee-31b5-424e-b791-9859929d5488","originalAuthorName":"徐丽"}],"doi":"","fpage":"698","id":"c1352acc-f1b4-46c5-8086-280407cbd062","issue":"3","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":"551464b1-68b3-4bdc-bf89-2733144278a6","keyword":"声子晶体","originalKeyword":"声子晶体"},{"id":"078d967e-b403-425f-943d-688411d84a27","keyword":"带隙特性","originalKeyword":"带隙特性"},{"id":"0f335b06-4485-4583-be66-98578aabb480","keyword":"平面波展开法","originalKeyword":"平面波展开法"}],"language":"zh","publisherId":"rgjtxb98201403040","title":"二维声子晶体振动带隙的最佳参数分析","volume":"43","year":"2014"},{"abstractinfo":"声子晶体是一种具有弹性波带隙的周期性结构功能材料,振动频率在声子晶体带隙范围内的振动会被抑制或禁止传播,它所具有的这种弹性波带隙特性为减振技术的发展提供了一种新的可能.在介绍声子晶体的基本理论及特征的基础上,阐述了声子晶体在振动与噪声控制领域的研究现状及声子晶体在汽车减振降噪方面的应用.","authors":[{"authorName":"赵树恩","id":"d7cd5678-be86-45ca-8d57-43c4b58b3193","originalAuthorName":"赵树恩"},{"authorName":"李以农","id":"85291dbb-2318-4113-b6be-9f1727c737ad","originalAuthorName":"李以农"},{"authorName":"郑玲","id":"909c19de-559f-41f1-b079-008f8796217b","originalAuthorName":"郑玲"},{"authorName":"谢敏松","id":"a1a81181-c4f5-4967-af97-18189aa0f8c6","originalAuthorName":"谢敏松"}],"doi":"","fpage":"84","id":"3c35edfe-058f-4fa9-888a-80230e4c586d","issue":"4","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"a447802a-79c4-40c9-a7fe-024137b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