{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"超疏水材料作为一种新型智能仿生材料，因优良的疏水、疏冰性能，在电力、航天等领域防冰除冰中得到了广泛应用，但在公路交通领域尚处于探索起步阶段。介绍了近年来国内外路面除冰技术存在的不足，分析了超疏水主动除冰技术在路面应用中的优势；概述了超疏水材料浸润性的基本理论；从促进液滴滚落、影响水滴结晶进程、降低冰附着力等方面，论证了超疏水材料在路面除冰应用中的可行性；从改变材料化学组成与粗糙度两个方面，分析了影响“冰-路”附着力的主要因素；在此基础上，介绍了超疏水材料制备与超疏水公路路面处治技术，综述了国内外冰与路面材料之间附着力的几种检测方法，主要包括：落杆撞击试验、水平剪切试验、重力式砝码剪切试验。在总结前人研究成果的基础上，本研究自行设计了摆锤试验以及劈裂试验，进一步验证了超疏水-防覆冰技术能有效降低“冰-路”附着力；并归纳了目前公路路面超疏水-防覆冰技术存在的问题，提出了未来研究发展的方向。","authors":[{"authorName":"高英力","id":"edbe0128-d058-4d12-af93-af1ce15946de","originalAuthorName":"高英力"},{"authorName":"代凯明","id":"612d5eed-c617-4af1-8372-9f9ec3ee1703","originalAuthorName":"代凯明"},{"authorName":"黄亮","id":"f9a97dfd-9ca5-4201-ad8c-efdc30cc1f00","originalAuthorName":"黄亮"},{"authorName":"郑策策","id":"22164d15-ee3d-4df7-961a-04b0c11b1ba4","originalAuthorName":"郑策策"},{"authorName":"<span style=\"color:red\">辛</span><span style=\"color:red\">太</span><span style=\"color:red\">磊</span>","id":"3a0504e8-ef11-4dad-9284-e5b01640a641","originalAuthorName":"辛太磊"}],"doi":"10.11896/j.issn.1005-023X.2017.01.014","fpage":"103","id":"8370c0a5-2fc9-4ed4-87ab-1dc096317303","issue":"1","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"8f413821-afb1-4a58-838c-f5cf0258e669","keyword":"超疏水","originalKeyword":"超疏水"},{"id":"f74fe5ca-355e-4fdf-bbcb-637d2c8b607c","keyword":"防覆冰","originalKeyword":"防覆冰"},{"id":"8d2d7a8f-dbe9-4ca8-8e54-5ef5289bf6d0","keyword":"路面","originalKeyword":"路面"}],"language":"zh","publisherId":"cldb201701015","title":"超疏水-防覆冰技术在公路路面中的研究应用进展?","volume":"31","year":"2017"},{"abstractinfo":"评述了<span style=\"color:red\">太</span>赫兹射线成像的进展情况.<span style=\"color:red\">太</span>赫兹(THz)辐射介于微波和红外之间.与微波、X射线、核磁共振(NMR)成像相比,<span style=\"color:red\">太</span>赫兹成像不仅能给出物体的密度信息,而且能给出频率域的信息,以及在光频、微波和X射线范围内所不能给出的材料的转动、振动信息.<span style=\"color:red\">太</span>赫兹射线与其他频段的电磁波相比,它能量低,不会造成对生物样品的电离损伤,而且<span style=\"color:red\">太</span>赫兹射线很容易穿过介电材料,因而可以用于产品的安全监测.因此<span style=\"color:red\">太</span>赫兹成像技术在生物学、工业安全监测等方面有可能带来新的关键性的突破.","authors":[{"authorName":"张蕾","id":"b1849ef3-da90-4fad-b3c1-32d7698eb572","originalAuthorName":"张蕾"},{"authorName":"徐新龙","id":"628db18d-0bd4-4344-b0f0-1835be54851d","originalAuthorName":"徐新龙"},{"authorName":"李福利","id":"4eab3194-6236-423f-a9d9-f45018bc6a02","originalAuthorName":"李福利"}],"doi":"10.3969/j.issn.1007-5461.2005.02.001","fpage":"129","id":"99263617-cd67-4eef-aec2-179e546483b4","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":"bd9ff55b-4448-43e5-921d-b01c46e4e9a3","keyword":"<span style=\"color:red\">太</span>赫兹成像","originalKeyword":"太赫兹成像"},{"id":"25a8dd22-2385-42bc-85b8-b1e2f0ceb22e","keyword":"扫描成像","originalKeyword":"扫描成像"},{"id":"915c6d25-07e8-44bc-b8b3-9a5c6c1e3fca","keyword":"实时成像","originalKeyword":"实时成像"},{"id":"792f3c35-1865-4070-aee0-894755820b05","keyword":"近场成像","originalKeyword":"近场成像"},{"id":"c9ad3714-57c7-4c8c-985e-65c5c6295dc8","keyword":"<span style=\"color:red\">太</span>赫兹CT","originalKeyword":"太赫兹CT"}],"language":"zh","publisherId":"lzdzxb200502001","title":"<span style=\"color:red\">太</span>赫兹(THz)成像的进展概况","volume":"22","year":"2005"},{"abstractinfo":"根据介质材料在<span style=\"color:red\">太</span>赫兹波下的性质可以制作可调控<span style=\"color:red\">太</span>赫兹波的特异性器件,研究导电薄膜对<span style=\"color:red\">太</span>赫兹波的吸收.通过分析硅衬底纳米导电薄膜在<span style=\"color:red\">太</span>赫兹波下的光学性质,设计材料参数可实现<span style=\"color:red\">太</span>赫兹波段下的宽频无色散吸收.通过<span style=\"color:red\">太</span>赫兹时域光谱系统对设计制作的材料进行探究,验证其具有与理论预计中完全一致的宽频无色散吸收效果,达到50％理论上的最大吸收率.","authors":[{"authorName":"田发","id":"a9be9282-9ae9-4dd0-aca9-1f70a4d74c0a","originalAuthorName":"田发"},{"authorName":"殷强","id":"ddec00c2-9e42-461a-93b3-1bb33a050973","originalAuthorName":"殷强"},{"authorName":"李肃成","id":"4e91aa92-2516-4fa7-b6da-18ce0773d000","originalAuthorName":"李肃成"},{"authorName":"陆伟新","id":"7e329261-a557-49bd-af20-4977239276a1","originalAuthorName":"陆伟新"},{"authorName":"侯波","id":"8556b952-3fdf-4bf7-8b77-53059654a32b","originalAuthorName":"侯波"},{"authorName":"顾邦明","id":"c816628d-5c94-4490-81e1-3d8857824dcf","originalAuthorName":"顾邦明"}],"doi":"","fpage":"121","id":"81a8f839-e977-49ec-af2d-d583541d1bed","issue":"2","journal":{"abbrevTitle":"BQCLKXYGC","coverImgSrc":"journal/img/cover/BQCLKXYGC.jpg","id":"4","issnPpub":"1004-244X","publisherId":"BQCLKXYGC","title":"兵器材料科学与工程   "},"keywords":[{"id":"eb5b7441-422f-4847-a759-f634c16c724f","keyword":"新型材料","originalKeyword":"新型材料"},{"id":"d3b4d300-3e35-4144-bcc6-d5961b985b6e","keyword":"宽频吸收","originalKeyword":"宽频吸收"},{"id":"000d89c7-a6bc-4079-b783-9ace627c5715","keyword":"<span style=\"color:red\">太</span>赫兹波","originalKeyword":"太赫兹波"},{"id":"3289bb40-53e8-45d3-9281-1c072f238786","keyword":"纳米导电薄膜","originalKeyword":"纳米导电薄膜"},{"id":"87db66d6-5270-4401-953c-25b72988e8a6","keyword":"透射率","originalKeyword":"透射率"},{"id":"5800882b-1f77-44fa-8e3b-1177f3219f7d","keyword":"复合介质","originalKeyword":"复合介质"}],"language":"zh","publisherId":"bqclkxygc201602030","title":"新型<span style=\"color:red\">太</span>赫兹波段宽带吸收材料","volume":"39","year":"2016"},{"abstractinfo":"介绍了分形的基本概念和分形盒维算法.提出了一种新的<span style=\"color:red\">太</span>赫兹光谱识别方法.实验中测得了两种中药的<span style=\"color:red\">太</span>赫兹光谱,算出了它们的盒维数并进行了比较.通过这种方法使不同的药品得到了很好的鉴别.","authors":[{"authorName":"张平","id":"29a8a301-2c2d-4233-897d-d1bb659342cd","originalAuthorName":"张平"},{"authorName":"王新柯","id":"a39816fb-8a43-4d23-8e1c-4da965dbc795","originalAuthorName":"王新柯"},{"authorName":"李海涛","id":"2d289df6-1509-4368-8be3-0bc2e0eb77f5","originalAuthorName":"李海涛"},{"authorName":"李宇晔","id":"ad5fb2b1-49a4-419a-b200-6bd7360db304","originalAuthorName":"李宇晔"},{"authorName":"耿玉珍","id":"d939bf21-4aeb-43c0-93b6-813857006831","originalAuthorName":"耿玉珍"},{"authorName":"李福利","id":"049bd0aa-422a-48ce-83cf-2ccb056e2527","originalAuthorName":"李福利"}],"doi":"10.3969/j.issn.1007-5461.2007.06.003","fpage":"672","id":"3d3f83b2-21a8-4c46-a53c-1a9c5ad6d52f","issue":"6","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":"6504c689-f602-420f-bf6c-87865d6fb591","keyword":"光谱学","originalKeyword":"光谱学"},{"id":"481cb517-f5a2-40e5-8cd3-825d13faa42c","keyword":"分形","originalKeyword":"分形"},{"id":"b9c0b825-f154-4295-81c3-42575496d94b","keyword":"盒维数","originalKeyword":"盒维数"},{"id":"065ef79c-ca26-4940-9e9b-8ed154f418aa","keyword":"<span style=\"color:red\">太</span>赫兹光谱识别","originalKeyword":"太赫兹光谱识别"}],"language":"zh","publisherId":"lzdzxb200706003","title":"基于分形理论的<span style=\"color:red\">太</span>赫兹光谱识别","volume":"24","year":"2007"},{"abstractinfo":"阐述<span style=\"color:red\">太</span>赫兹波吸收材料研究的重要性,介绍<span style=\"color:red\">太</span>赫兹波吸收材料用基础材料(高分子材料、碳材料、半导体材料、金属薄膜)在<span style=\"color:red\">太</span>赫兹波段吸收性能的研究进展,并对<span style=\"color:red\">太</span>赫兹波吸收材料的发展提出展望.","authors":[{"authorName":"武新","id":"70258ae8-06a7-4244-b855-c897e7fed7ed","originalAuthorName":"武新"},{"authorName":"王晓","id":"bb344007-efc6-46af-828a-ce989e995ac2","originalAuthorName":"王晓"},{"authorName":"苗成","id":"16e9f015-1f2e-4273-9c74-b3196af477e4","originalAuthorName":"苗成"},{"authorName":"武海玲","id":"4320f3bb-4c29-486e-a9ca-6e137bc9a0dc","originalAuthorName":"武海玲"},{"authorName":"李树涛","id":"7375a604-37be-4d69-a3f7-84d2624a90af","originalAuthorName":"李树涛"},{"authorName":"杨伟苓","id":"e3176774-0022-4c0b-90c4-f01c3d00ab00","originalAuthorName":"杨伟苓"},{"authorName":"李国飞","id":"6e37d37d-f856-4b49-8717-44c3f6e040c3","originalAuthorName":"李国飞"},{"authorName":"吕绯","id":"00ce34e9-2dc0-407d-b2e5-069f6e1c10e3","originalAuthorName":"吕绯"}],"doi":"","fpage":"130","id":"c5e2dc3c-6df1-4841-b237-c112be24c18f","issue":"2","journal":{"abbrevTitle":"BQCLKXYGC","coverImgSrc":"journal/img/cover/BQCLKXYGC.jpg","id":"4","issnPpub":"1004-244X","publisherId":"BQCLKXYGC","title":"兵器材料科学与工程   "},"keywords":[{"id":"b2471630-fb47-4798-8e1d-b5eb842bcded","keyword":"<span style=\"color:red\">太</span>赫兹波","originalKeyword":"太赫兹波"},{"id":"9d5552ba-2b92-4672-ad1a-a886ae1d983d","keyword":"材料","originalKeyword":"材料"},{"id":"f636a7ad-e85c-482d-8c9e-ac7c6db3b414","keyword":"吸收","originalKeyword":"吸收"},{"id":"84d59669-9c90-4e37-adbc-87dc37afdb2a","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"bqclkxygc201302041","title":"材料在<span style=\"color:red\">太</span>赫兹波段吸收性能的研究进展","volume":"","year":"2013"},{"abstractinfo":"找到了一个能够用矩阵法计算的新序参量,此参量既能给出有限数量格点时一维伊<span style=\"color:red\">辛</span>模型中存在相变,又能给出无限数量格点时相变消失的结果.利用此序参量求出了一个计算相变点的简洁近似公式.","authors":[{"authorName":"田树旬","id":"c54330c7-9418-4f19-acea-4ace4901156e","originalAuthorName":"田树旬"}],"doi":"","fpage":"153","id":"195b84dc-2cf1-4ff5-b5ae-051891ff69c7","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":"0b5100e5-1efb-4313-97d0-d8d72c94e4c6","keyword":"一维伊<span style=\"color:red\">辛</span>模型","originalKeyword":"一维伊辛模型"},{"id":"c92d5079-f68f-46e1-af35-edaf1223ca05","keyword":"相变","originalKeyword":"相变"},{"id":"58ac394a-4d55-4608-a4e5-f6519942b55b","keyword":"矩阵法","originalKeyword":"矩阵法"}],"language":"zh","publisherId":"dwwlxb201502013","title":"一维伊<span style=\"color:red\">辛</span>模型的相变-Ⅱ","volume":"37","year":"2015"},{"abstractinfo":"对几种建筑材料(土、石、砖、水泥、木片)的穿透特性进行实验研究,得到了这几种建筑材料的折射率曲线与吸收系数曲线.实验表明,<span style=\"color:red\">太</span>赫兹辐射对土、石、砖、水泥、木材等建筑材料有较高的透射率.这为把<span style=\"color:red\">太</span>赫兹辐射用于安检提供了依据.","authors":[{"authorName":"任荣东","id":"f633cb98-c6ca-4d18-b04a-cf9811c1865a","originalAuthorName":"任荣东"},{"authorName":"王新柯","id":"9e65ceea-6ff0-4820-b5bc-e4c337fc6222","originalAuthorName":"王新柯"},{"authorName":"赵国忠","id":"35e472a7-9b56-48ea-8341-b5d5d62a6259","originalAuthorName":"赵国忠"},{"authorName":"耿玉珍","id":"01156294-7b3f-4ae5-8f97-9fb7f7e11c93","originalAuthorName":"耿玉珍"},{"authorName":"李福利","id":"39dc7f7d-ceb1-4044-a259-7f9a92acf12e","originalAuthorName":"李福利"}],"doi":"10.3969/j.issn.1007-5461.2006.04.024","fpage":"555","id":"908bcd43-bf44-4d38-8b97-2eaa48f5916c","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":"d5ae1493-7674-46a1-ba2b-c2a6fd1594ba","keyword":"光谱学","originalKeyword":"光谱学"},{"id":"1d9e6634-7d4d-4ae4-8997-8b3ec5516b2c","keyword":"<span style=\"color:red\">太</span>赫兹辐射","originalKeyword":"太赫兹辐射"},{"id":"fe508787-1832-4c48-bd5e-bb3a65a7d449","keyword":"<span style=\"color:red\">太</span>赫兹光谱","originalKeyword":"太赫兹光谱"},{"id":"e96e7539-ffe4-4227-b133-ec1ee05927a9","keyword":"安全检查","originalKeyword":"安全检查"},{"id":"5869d436-080f-46e6-a7d5-f06eb17219b7","keyword":"建筑材料","originalKeyword":"建筑材料"}],"language":"zh","publisherId":"lzdzxb200604024","title":"建筑材料的<span style=\"color:red\">太</span>赫兹谱实验研究","volume":"23","year":"2006"},{"abstractinfo":"对几种结晶化合物(石膏、蓝矾、绿矾、芒硝和明矾)的吸收性进行了实验研究,得到了这几种结晶化合物的折射率曲线和吸收曲线.实验表明,蓝矾、芒硝、明矾等结晶化合物对<span style=\"color:red\">太</span>赫兹辐射吸收很大,这为<span style=\"color:red\">太</span>赫兹波段吸波材料的研制方面提供了可能的依据.","authors":[{"authorName":"刘艳艳","id":"1dbda0eb-c9f0-4989-a21c-8f6d5de85719","originalAuthorName":"刘艳艳"},{"authorName":"陈艳江","id":"4d228cd7-42a9-4010-ae5e-a7a1438bb338","originalAuthorName":"陈艳江"},{"authorName":"武凤萍","id":"0e0ebd70-55da-4aa6-8b6f-4b788bf1999a","originalAuthorName":"武凤萍"},{"authorName":"耿玉珍","id":"19401f64-0afd-4582-aa58-51181f03a5eb","originalAuthorName":"耿玉珍"},{"authorName":"张存林","id":"29ab3e02-ec6c-4884-8663-9ffb10dd4b7f","originalAuthorName":"张存林"},{"authorName":"李福利","id":"546caafc-b87f-4285-8d62-2149b96fe9f3","originalAuthorName":"李福利"}],"doi":"10.3969/j.issn.1007-5461.2009.02.001","fpage":"129","id":"022453d6-4b5b-4b35-906c-d23a88c6c170","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":"f93913a8-df0f-4b45-b26f-5b23404e2f13","keyword":"光谱学","originalKeyword":"光谱学"},{"id":"c7c7c890-0709-4088-aa54-b5a8a7b097e3","keyword":"<span style=\"color:red\">太</span>赫兹辐射","originalKeyword":"太赫兹辐射"},{"id":"b5767b13-163a-4dc5-987e-c34a368b58aa","keyword":"<span style=\"color:red\">太</span>赫兹光谱","originalKeyword":"太赫兹光谱"},{"id":"d8c2df6d-f49d-4c85-ba7e-00cc10a9f684","keyword":"结晶化合物","originalKeyword":"结晶化合物"},{"id":"bbb61e1f-0141-49d3-afc0-2c116c374ec2","keyword":"吸波材料","originalKeyword":"吸波材料"}],"language":"zh","publisherId":"lzdzxb200902001","title":"结晶化合物的<span style=\"color:red\">太</span>赫兹光谱实验研究","volume":"26","year":"2009"},{"abstractinfo":"采用拉、压循环试验测试了Az31镁合金的包<span style=\"color:red\">辛</span>格效应(BE),并研究了BE的机制.测试结果表明:压缩预变形后反向拉伸出现明显的BE.而拉伸预变形后反向压缩出现反包<span style=\"color:red\">辛</span>格效应(RBE);且包<span style=\"color:red\">辛</span>格效应比反包<span style=\"color:red\">辛</span>格效应明显.循环拉、压加载过程中的显微组织和晶体取向演化研究结果表明,出现包<span style=\"color:red\">辛</span>格效应是由于预压缩时改变晶粒取向与反向拉伸时去孪生效应共同作用的结果:预拉伸变形虽然不改变晶粒取向,但使轴比c/a值降低,使反向压缩时发生孪生更加困难,从而导致反包<span style=\"color:red\">辛</span>格效应.","authors":[{"authorName":"盛光敏","id":"c9ab42e2-2133-4cf1-ab4a-f92cc2f52699","originalAuthorName":"盛光敏"},{"authorName":"张功庭","id":"4605e58a-d0ef-4a22-a466-7cbece4f00cf","originalAuthorName":"张功庭"},{"authorName":"阎春","id":"7536391b-61f0-4385-a48a-b623a665c2e2","originalAuthorName":"阎春"}],"doi":"","fpage":"615","id":"ab54f077-129d-4907-8e84-e186d56d0401","issue":"4","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":"887c88d8-addc-42b0-b5f8-3e8cce9ff9e4","keyword":"AZ31镁合金","originalKeyword":"AZ31镁合金"},{"id":"caaeb69c-6323-40aa-aad7-462028c304ac","keyword":"包<span style=\"color:red\">辛</span>格效应","originalKeyword":"包辛格效应"},{"id":"47dcb88d-9b03-4a4f-b086-3a302ae69d87","keyword":"反包<span style=\"color:red\">辛</span>格效应","originalKeyword":"反包辛格效应"},{"id":"bfa9e8d6-f85c-4007-9b4c-a423e595353f","keyword":"晶粒取向","originalKeyword":"晶粒取向"}],"language":"zh","publisherId":"xyjsclygc201104011","title":"AZ31镁合金包<span style=\"color:red\">辛</span>格效应研究","volume":"40","year":"2011"},{"abstractinfo":"本文介绍了一款高速、低噪声超导热电子测辐射热计(hot electron bolometer,HEB)的<span style=\"color:red\">太</span>赫兹检测系统,实验结果显示其有效提高了中频带宽(7.4GHz),减小了噪声温度(@0.65THz,系统在最佳偏置点的双边带(DSB)噪声温度为1185 K).同时,用此款超导HEB<span style=\"color:red\">太</span>赫兹检测系统验证了改进后的傅里叶变换光谱仪(FTS)系统的稳定性及可靠性.","authors":[{"authorName":"张鹤","id":"1cee2202-7954-468f-8785-f300ee02cb7c","originalAuthorName":"张鹤"},{"authorName":"陈健","id":"bd53aede-5180-4cae-aa35-4564f6afa6f8","originalAuthorName":"陈健"},{"authorName":"姜寿禄","id":"56e166b0-427b-4d3f-9dce-9a0de0c728e5","originalAuthorName":"姜寿禄"},{"authorName":"康琳","id":"0eee1714-8c43-4638-9e41-35ef4c067d97","originalAuthorName":"康琳"},{"authorName":"许伟伟","id":"f9521894-90a2-4bf3-bc34-bbbb77f0f911","originalAuthorName":"许伟伟"},{"authorName":"金飚兵","id":"89b1b2e8-16ee-4804-99f5-4750bebb8acf","originalAuthorName":"金飚兵"},{"authorName":"吴培亨","id":"62f82688-fe71-4d65-bf6c-25dcc2e3fe73","originalAuthorName":"吴培亨"}],"doi":"","fpage":"445","id":"7c344b66-1ad3-4752-865f-3e9b119560e3","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":"32011517-faf2-4940-b0d5-f19bc10971dd","keyword":"超导 HEB<span style=\"color:red\">太</span>赫兹检测系统","originalKeyword":"超导 HEB太赫兹检测系统"},{"id":"ca5a5915-290c-453c-9954-56dce9b1c404","keyword":"高速","originalKeyword":"高速"},{"id":"11880789-029b-4e2f-a1da-78643d582fe9","keyword":"低噪声","originalKeyword":"低噪声"}],"language":"zh","publisherId":"dwwlxb201406007","title":"高速、低噪声超导HEB<span style=\"color:red\">太</span>赫兹检测系统","volume":"36","year":"2014"}],"totalpage":37,"totalrecord":365}