材料期刊网

1.西安交通大学材料学院,陕西西安710049;西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

2.西安交通大学材料学院,陕西西安710049

3.西安交通大学材料学院,陕西西安710049

4.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

5.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

6.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

7.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

8.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

1.西安交通大学材料学院,陕西西安710049;西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

2.西安交通大学材料学院,陕西西安710049

3.西安交通大学材料学院,陕西西安710049

4.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

5.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

6.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

7.西安航天复合材料研究所,西安超码科技有限公司,陕西西安710025

{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"建立了掺杂情况下多层有机电致发光器件激子复合发光的理论模型,复合发光区由于掺杂层的引入发生了漂移,发光区的位置及宽度主要由陷阱电荷浓度来确定,且复合区宽度会随着掺杂浓度、电场强度、温度的变化而改变.轻度掺杂时,由于载流子空间排列的无序性,降低了载流子迁移率,复合区宽度变窄;重掺杂时(＞0.5 mol%),则由于能量分布的无序性,增大了载流子迁移速度,使复合区域加宽.电场增强使电子和空穴迁移速度相差较大,引起复合区变窄;但当电场增大到1.6MV/cm时,很多陷阱电荷受到激发,产生激子的区域增多,所以复合区宽度反而增宽.低温时(T＜350 K),复合区宽度增加;但当温度升高时(T＞350 K),载流子浓度与载流子迁移率两者竞争的结果使复合区宽度减小.","authors":[{"authorName":"许雪梅","id":"91194490-5715-46dc-90c1-3d5d556ed811","originalAuthorName":"许雪梅"},{"authorName":"吴爱军","id":"10167f39-97c6-4c4f-b5da-6ecdd1435ef6","originalAuthorName":"吴爱军"},{"authorName":"吴建好","id":"b8d5cb1b-dc90-4cb7-a8ce-63f52969fcb1","originalAuthorName":"吴建好"},{"authorName":"王华","id":"8a691b60-5f60-4856-8e52-08d79e380352","originalAuthorName":"王华"},{"authorName":"李维","id":"3eabaa8b-7741-443b-be7e-ec00c38744ec","originalAuthorName":"李维"},{"authorName":"刘茜倩","id":"ec4e39bd-4b90-47ea-a3f4-b0fdded30596","originalAuthorName":"刘茜倩"},{"authorName":"叶俊华","id":"74446c4c-b18d-4de5-8947-2039cb70bf4d","originalAuthorName":"叶俊华"}],"doi":"","fpage":"142","id":"e6b60332-8da1-46ab-a303-db25ca36b61b","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":"82cc2f2c-d7b5-4a29-8bec-95150d9665d5","keyword":"掺杂","originalKeyword":"掺杂"},{"id":"1a813fe9-8f95-4e1d-95a9-c3d6581ca8e2","keyword":"有机电致发光","originalKeyword":"有机电致发光"},{"id":"c76c3145-b36a-4adb-be9b-58847a76815e","keyword":"复合效率","originalKeyword":"复合效率"},{"id":"f62889fc-5db1-4b12-afa5-6fe081116624","keyword":"复合区域","originalKeyword":"复合区域"}],"language":"zh","publisherId":"cldb2007z2050","title":"掺杂情况下多层有机电致发光器件复合区域研究","volume":"21","year":"2007"},{"abstractinfo":"介绍了一种可同时实现定位(驱动)与可控阻尼的磁流变复合液压执行器的原理及系统结构,研究了在入口压力较高时磁流变阀不可能完全理想关闭情况下桥式磁流变阀路的效率问题,建立了基于桥式磁流变阀路的磁流变复合液压执行器定位(驱动)时的效率模型.","authors":[{"authorName":"王代华","id":"2e08c8c6-a47c-419b-a19c-dece4b3b9d17","originalAuthorName":"王代华"},{"authorName":"艾红霞","id":"0de38217-c6d0-41bb-afad-1d799941e4f5","originalAuthorName":"艾红霞"}],"doi":"","fpage":"1183","id":"98efcb13-9d36-462f-a67f-3e27ee046b00","issue":"7","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"cb04d139-2106-4d92-869e-b45a7d8c9937","keyword":"磁流变阀","originalKeyword":"磁流变阀"},{"id":"28d1e4a1-5309-4270-bbe2-0305640506ef","keyword":"圆环形阻尼间隙","originalKeyword":"圆环形阻尼间隙"},{"id":"8dad2ec5-9136-46c0-bd10-6470ee8c80d8","keyword":"圆盘形阻尼间隙","originalKeyword":"圆盘形阻尼间隙"},{"id":"de97eceb-4746-46d6-84fd-48dae8ac2984","keyword":"磁流变复合液压执行器","originalKeyword":"磁流变复合液压执行器"},{"id":"46de4e2d-c115-4626-a1e2-3487589d73f3","keyword":"执行器效率","originalKeyword":"执行器效率"}],"language":"zh","publisherId":"gncl200607051","title":"磁流变复合液压执行器及其效率研究","volume":"37","year":"2006"},{"abstractinfo":"为了提高树脂基复合材料烧蚀中的热阻塞效应,同时避免因为加入过量树脂引起的复合材料脆性较大的问题,本文提出了引入可分解纤维改性的方法来解决这一矛盾.通过比较,筛选出了分解性质与酚醛树脂相似的可分解纤维,制备了改性纤维/酚醛复合材料.电弧风洞烧蚀试验结果显示,20 mm厚的改性纤维/酚醛在最高热面温度1 300℃、总加热时间600 s的条件下背面温升比相同条件下高硅氧/酚醛低约40℃,表现出很好的烧蚀防热性能,与材料设计的初衷相符.因此,引入可分解纤维的方法是一种有效改善复合材料性能的方法.","authors":[{"authorName":"郭梅梅","id":"5c35c99f-cc34-42ba-b6e7-0fa613aa6a20","originalAuthorName":"郭梅梅"},{"authorName":"匡松连","id":"1170daa6-d09d-4db9-b3d1-9d6c3466858d","originalAuthorName":"匡松连"},{"authorName":"华小玲","id":"1c883c4a-1ede-49e3-8557-68eebcbf73c7","originalAuthorName":"华小玲"},{"authorName":"张宗强","id":"7b8f4ee7-8280-4ad0-8c45-5f6eac5c0cd1","originalAuthorName":"张宗强"}],"doi":"10.3969/j.issn.1007-2330.2012.02.014","fpage":"58","id":"a7e50fff-b0c5-4693-aa05-e7d688fc5f2d","issue":"2","journal":{"abbrevTitle":"YHCLGY","coverImgSrc":"journal/img/cover/YHCLGY.jpg","id":"77","issnPpub":"1007-2330","publisherId":"YHCLGY","title":"宇航材料工艺 "},"keywords":[{"id":"c5cd12af-d9a6-44c4-9d41-c1d134fa273e","keyword":"树脂基复合材料","originalKeyword":"树脂基复合材料"},{"id":"69176fa5-a1c7-4e44-a8ff-07ec0dabedf6","keyword":"热阻塞效应","originalKeyword":"热阻塞效应"},{"id":"bde914a5-db04-436f-9d58-684a28f34592","keyword":"防热","originalKeyword":"防热"}],"language":"zh","publisherId":"yhclgy201202014","title":"树脂基复合材料的分解防热效率","volume":"42","year":"2012"},{"abstractinfo":"建立了单层有机电致发光器件复合区域和外量子效率的模型,讨论了外加电压与器件厚度对复合区域和外量子效率的影响.结果表明:(1)器件的复合区域宽度随着电场强度的增加而减小;(2)随着外加电压的升高,器件的外量子效率先增加后减小.","authors":[{"authorName":"赵楚军","id":"b9a86d97-7f4c-4af1-8a7c-1ec096891bed","originalAuthorName":"赵楚军"},{"authorName":"李宏建","id":"e0c2788d-1510-4874-a01f-e92fbcf7bf45","originalAuthorName":"李宏建"},{"authorName":"崔昊扬","id":"a656f5ce-6d1a-4f99-b668-b3469453d795","originalAuthorName":"崔昊扬"},{"authorName":"代国章","id":"473ef3c4-4a8c-4cbc-b702-46be22e3428c","originalAuthorName":"代国章"},{"authorName":"黄永辉","id":"f67882d5-8ce6-4461-9022-b3e48b918fd2","originalAuthorName":"黄永辉"},{"authorName":"谢强","id":"65c35928-b5d4-4578-ba6d-a78075be0b6e","originalAuthorName":"谢强"},{"authorName":"彭景翠","id":"cd94a7ca-889e-41c8-82c8-a4c37e075141","originalAuthorName":"彭景翠"}],"doi":"","fpage":"325","id":"ba9f32e3-5f39-47ec-82cd-507259709154","issue":"z1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"3b6f6767-d256-4e43-9fd2-db1712064eb2","keyword":"复合区域","originalKeyword":"复合区域"},{"id":"bfe55ef3-9963-46a1-96ea-ac27e05522d4","keyword":"外量子效率","originalKeyword":"外量子效率"},{"id":"c8ca9821-ab31-4bc6-af20-c1b61c461392","keyword":"OLEDs","originalKeyword":"OLEDs"}],"language":"zh","publisherId":"gncl2004z1078","title":"单层有机发光二极管中复合区域和外量子效率的研究","volume":"35","year":"2004"},{"abstractinfo":"影响LED出光效率的关键因素是芯片顶部的封装材料,芯片顶部封装要求材料具有高透光率、高折射率和高抗老化能力.对纳米MgO和纳米ZnO进行表面改性处理,并按一定的比例加入到环氧树脂中,制备出LED顶部封装材料,既提高了LED的出光效率又简化了封装工艺.结果表明,在纳米ZnO和纳米MgO的共同作用下,L ED的出光效率相对于纯环氧封装提高了10.57％,相对于有机硅树脂双层结构封装提高了11.14％,同时提高了LED封装材料的光学稳定性.","authors":[{"authorName":"巩静","id":"ae892bae-8e2c-438d-930e-60e363a66bdd","originalAuthorName":"巩静"},{"authorName":"文瀚颖","id":"077e9f97-d1ff-49ea-bac0-01b38ad2161e","originalAuthorName":"文瀚颖"},{"authorName":"牟其伍","id":"1b7a9558-ae48-4e53-923c-dd5ea0a9bc49","originalAuthorName":"牟其伍"},{"authorName":"吕亚楠","id":"e3222454-ab86-433b-9303-ec3927e1f611","originalAuthorName":"吕亚楠"},{"authorName":"李巧梅","id":"2f221f0a-9ef5-412b-a231-3a44547a25d4","originalAuthorName":"李巧梅"}],"doi":"10.11896/j.issn.1005-023X.2016.08.003","fpage":"13","id":"bed045fe-d5e1-46cf-9f02-76817c34d255","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":"229b6cf4-eacb-4038-9a9f-e3d4b4ea6f4b","keyword":"环氧树脂","originalKeyword":"环氧树脂"},{"id":"1789bdd3-f246-4e60-bd64-a8f3df4ba862","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"7d6a88f1-23b5-4150-b97c-0a4798a9b0a1","keyword":"出光率","originalKeyword":"出光率"},{"id":"6d46bfd3-0ac8-4690-b8a4-db0fc6b4bb2b","keyword":"折射率","originalKeyword":"折射率"},{"id":"94e14040-3f22-4d9a-9acf-d13de8e87098","keyword":"抗紫外老化","originalKeyword":"抗紫外老化"}],"language":"zh","publisherId":"cldb201608003","title":"ZnO/MgO/环氧树脂基复合材料对LED出光效率的影响","volume":"30","year":"2016"},{"abstractinfo":"负电子亲和势材料具有较窄的禁带宽度、功函数低,在OLED的工作电场强范围内可以发射电子,同时在吸收有机材料所发光子能量后可以产生光电子发射,再次注入有机层,提高了电子注入效率.介绍了负电子亲和势材料的形成,理论上分析了其对有机半导体能级的影响以及如何改善有机电致发光器件中电子注入水平,从而提高发光效率.","authors":[{"authorName":"袁桃利","id":"8e7b8912-9cc6-447d-8d92-3faa47e22015","originalAuthorName":"袁桃利"},{"authorName":"王秀峰","id":"7e8b1cd0-9223-414f-9425-37febed70622","originalAuthorName":"王秀峰"},{"authorName":"牟强","id":"afa84681-dad4-4a32-beac-1f48da33d204","originalAuthorName":"牟强"}],"doi":"","fpage":"14","id":"5a8d8a9b-a9ca-419b-9ae2-b9b866465b9b","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":"9622a556-a3fc-4d23-bfab-4eab5602b78d","keyword":"负电子亲和势","originalKeyword":"负电子亲和势"},{"id":"3c920ab3-6463-4ea2-8b3d-547dce715e4d","keyword":"功函数","originalKeyword":"功函数"},{"id":"1cc02afe-e2c8-4b21-8ca1-0e86d011a23c","keyword":"发光效率","originalKeyword":"发光效率"},{"id":"ec65f027-e8f0-451b-842d-4e888b59a4da","keyword":"光电子","originalKeyword":"光电子"}],"language":"zh","publisherId":"cldb200808004","title":"OLED中NEA材料复合阴极影响电子注入效率的作用机理","volume":"22","year":"2008"},{"abstractinfo":"提出一种以承载效率最高作为目标的新设计方法,对复合材料加筋板的承载能力进行优化.讨论了不同压缩与弯曲刚度的匹配模式与加筋板临界失稳载荷的关系.将伞局失稳载荷、局部失稳载荷与静载荷的接近程度作为结构承载效率的量化标准,通过静载荷的控制,使结构的稳定性向着效率最高的方向优化.以宏观的加筋板压缩与弯曲刚度参数作为设计变量,构建了一种可用于结构效率优化的代理模型,避免了局部最优点的出现,更便于数值寻优.通过有限元分析验证,优化后壁板的临界失稳载荷与所施加的静载荷基本一致,反映出较高的效率,从而验证了该方法的可靠性.","authors":[{"authorName":"赵群","id":"178f2092-6de5-4295-bd02-93015d0f0755","originalAuthorName":"赵群"},{"authorName":"丁运亮","id":"659667c1-6e2f-4bfc-8a24-9c38f637ce9e","originalAuthorName":"丁运亮"},{"authorName":"金海波","id":"f21fce0f-348c-439c-86e5-29015c577356","originalAuthorName":"金海波"}],"doi":"","fpage":"169","id":"aa2336de-a052-4604-a77a-6d232837baf8","issue":"3","journal":{"abbrevTitle":"FHCLXB","coverImgSrc":"journal/img/cover/FHCLXB.jpg","id":"26","issnPpub":"1000-3851","publisherId":"FHCLXB","title":"复合材料学报"},"keywords":[{"id":"5d894c7b-70ec-4862-924b-0ba9ae16bbaa","keyword":"复合材料","originalKeyword":"复合材料"},{"id":"049c1c27-41f9-42a8-a24c-f415f1f767ab","keyword":"加筋板","originalKeyword":"加筋板"},{"id":"5da73707-ab5f-4c8c-a24c-47500def59cd","keyword":"稳定性","originalKeyword":"稳定性"},{"id":"d89f1632-58f1-4c5c-be3f-fca6dc05b7fa","keyword":"承载效率","originalKeyword":"承载效率"},{"id":"ac59fe62-6f27-4139-975c-86b6b7098c6d","keyword":"压缩刚度","originalKeyword":"压缩刚度"},{"id":"63803d95-43ad-425e-99ce-bec2cbcdee80","keyword":"弯曲刚度","originalKeyword":"弯曲刚度"}],"language":"zh","publisherId":"fhclxb201003028","title":"一种基于复合材料加筋板结构效率的稳定性优化方法","volume":"27","year":"2010"},{"abstractinfo":"制备了一系列CdS纳米晶/石墨烯(CdS/GR)复合物,并在可见光照条件下评价了其光催化降解亚甲基蓝的光催化效率和抗光腐蚀行为.研究表明,石墨烯的引入加速了CdS纳米晶(NCs)光生电子的迁移速率,抑制了其光生电子-空穴的复合,有效改善了其光催化降解有机污染物的性能.CdS/GR复合物中的石墨烯含量显著影响其光催化效率,其中石墨烯含量为4.6％的光催化剂效率最高,其光电流是CdS NCs的2.3倍.利用光电化学和X射线衍射技术进一步证实,石墨烯的引入抑制了CdS NCs光腐蚀的发生,提高了CdS/GR复合物的光催化稳定性.","authors":[{"authorName":"严佳佳","id":"416aac98-1f58-4b95-b81f-31c94c204de6","originalAuthorName":"严佳佳"},{"authorName":"王坤","id":"0ae553b5-92d5-4ca0-aae7-95023809f515","originalAuthorName":"王坤"},{"authorName":"许晖","id":"f60e7105-c55b-40ae-ae34-262fb8bd6eec","originalAuthorName":"许晖"},{"authorName":"钱静","id":"dad83b81-939f-47e2-80c4-bdfa6d43a07b","originalAuthorName":"钱静"},{"authorName":"刘巍","id":"92d5b220-39cc-42f8-b6cc-4bd80c457109","originalAuthorName":"刘巍"},{"authorName":"杨兴旺","id":"73bebe8b-432e-47c8-82fe-3e2b61063ed1","originalAuthorName":"杨兴旺"},{"authorName":"李华明","id":"6a8af557-2adb-454d-9808-74b3cd141027","originalAuthorName":"李华明"}],"doi":"10.1016/S1872-2067(12)60677-9","fpage":"1876","id":"3a1e38b9-61e4-40d7-a9d6-539dbb9c72f8","issue":"10","journal":{"abbrevTitle":"CHXB","coverImgSrc":"journal/img/cover/CHXB.jpg","id":"18","issnPpub":"0253-9837","publisherId":"CHXB","title":"催化学报 "},"keywords":[{"id":"ccb34a4d-583e-4129-94ba-f939fe42c600","keyword":"硫化镉纳米晶","originalKeyword":"硫化镉纳米晶"},{"id":"06056b32-1d3a-41c2-9d01-9ef70da32a1b","keyword":"石墨烯纳米复合物","originalKeyword":"石墨烯纳米复合物"},{"id":"53cc406b-22e7-4889-9665-d3ba41531c8f","keyword":"抗光腐蚀","originalKeyword":"抗光腐蚀"},{"id":"b52d1cee-0086-45fd-841b-88a86a28d2e6","keyword":"光催化","originalKeyword":"光催化"},{"id":"22064503-13d2-4a25-9d8d-1fd0711066b3","keyword":"亚甲基蓝降解","originalKeyword":"亚甲基蓝降解"}],"language":"zh","publisherId":"cuihuaxb201310012","title":"CdS/石墨烯纳米复合物的可见光催化效率和抗光腐蚀行为","volume":"34","year":"2013"},{"abstractinfo":"利用热重分析法研究了稀土氧化物CeO2和其复合催化剂对煤粉燃烧特性的影响.研究了稀土氧化物及其复合催化剂的添加量、配比对煤粉燃烧特性的影响.结果表明:CeO2可以促进烟煤挥发分析出和燃烧,改善其燃烧性能,CeO2添加质量分数为4％时其催化效果最为显著；不同催化剂对无烟煤燃烧的催化效果各异,MnO2有利于挥发分析出,而CeO2促进了残碳的燃烧,其催化作用不同于烟煤；Ce-Fe-Mn系复合催化剂催化效果优于单组分催化剂,其中CeFeMn(3∶1∶1)的催化效果最佳.利用Coats-Redfern动力学模型分析了煤粉燃烧活化能、指前因子等动力学参数,添加CeFeMn(3∶1∶1)的煤粉反应速率常数较大,催化效果显著.","authors":[{"authorName":"张建良","id":"b8e57f04-721f-4cd8-a624-7742e141aabe","originalAuthorName":"张建良"},{"authorName":"汤云腾","id":"367aeea5-3c55-479d-bd65-52e2a2a916c0","originalAuthorName":"汤云腾"},{"authorName":"王广伟","id":"2440564a-9677-43bc-8341-7d87e4be2318","originalAuthorName":"王广伟"},{"authorName":"左海滨","id":"76958ef1-1854-479b-b6fa-1a32c3acdcea","originalAuthorName":"左海滨"}],"doi":"","fpage":"81","id":"9e918aa3-dd1b-4ffc-8c72-e77c0db04241","issue":"9","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"e64dfddb-279e-4fd4-a0c1-a8f67c83ec73","keyword":"煤粉","originalKeyword":"煤粉"},{"id":"8bfd82ad-3af3-4e39-af00-817997ee7d86","keyword":"CeO2","originalKeyword":"CeO2"},{"id":"6d5c1e5b-a0e3-46fc-ba16-d49651d72b2d","keyword":"催化剂","originalKeyword":"催化剂"},{"id":"f950488e-b8b9-4074-b482-5bf11e836e5d","keyword":"燃烧特性","originalKeyword":"燃烧特性"},{"id":"2c58fd97-1d57-4c85-b205-c64f8cec4c92","keyword":"热重分析","originalKeyword":"热重分析"},{"id":"2081a427-371a-4471-a14c-b9999cbb1ddd","keyword":"动力学","originalKeyword":"动力学"}],"language":"zh","publisherId":"gt201309015","title":"CeO2及其复合催化剂对煤粉燃烧效率的影响","volume":"48","year":"2013"},{"abstractinfo":"利用实验测量和Monte Carlo模拟的方法,研究了RIBLL的传输效率.分析了影响传输效率的主要因素,发现碎片的动量分布形式对传输效率的模拟结果有重要的影响.另外通过比较,发现大部分碎片传输效率的模拟结果稍大于实验测量结果,两者最大相差约几十倍,这可以帮助估算次级束流强度,指导实验设计.","authors":[{"authorName":"章学恒","id":"c82c2d21-e592-40fe-bf37-e9fc3b618223","originalAuthorName":"章学恒"},{"authorName":"孙志宇","id":"f7a7581a-a033-44f2-bf3a-7787831a2e38","originalAuthorName":"孙志宇"},{"authorName":"王猛","id":"f5f5ccd9-9756-4ff1-b6d4-f3264b572c33","originalAuthorName":"王猛"},{"authorName":"陈志强","id":"8611d5a0-e2c2-4209-a9b3-344d1bbd32c8","originalAuthorName":"陈志强"},{"authorName":"胡正国","id":"9e16ff70-3b15-4782-a942-15d2caf8a30b","originalAuthorName":"胡正国"},{"authorName":"王建松","id":"2d1a2dc9-b844-435e-80f4-d4e1dd29e982","originalAuthorName":"王建松"},{"authorName":"毛瑞士","id":"2c6981aa-3a3e-4254-96f2-129eb484dea6","originalAuthorName":"毛瑞士"},{"authorName":"张雪荧","id":"7d1ef53e-b380-4673-a8e7-78c55e72040a","originalAuthorName":"张雪荧"},{"authorName":"赵铁成","id":"9c87bceb-ab0c-436a-a200-d31cd41f61b6","originalAuthorName":"赵铁成"},{"authorName":"李琛","id":"5a8a64be-a983-4694-9310-a3d1b5c37f42","originalAuthorName":"李琛"},{"authorName":"徐瑚珊","id":"e91d2024-c096-4306-be44-69faa6400353","originalAuthorName":"徐瑚珊"},{"authorName":"肖国青","id":"9a423fba-e3f1-4f2b-99b1-1cd225d92a57","originalAuthorName":"肖国青"},{"authorName":"袁小华","id":"698fa213-7d1b-46d1-aa52-c7c0da3ac5e6","originalAuthorName":"袁小华"},{"authorName":"徐志国","id":"e3e64c31-45f6-4150-836e-96772a2c8ff6","originalAuthorName":"徐志国"},{"authorName":"陈若富","id":"e99071a2-b9f3-4bee-9732-c6adafe3f22b","originalAuthorName":"陈若富"},{"authorName":"郭忠言","id":"be3d5f13-20f7-4664-95aa-b318eb6ca29f","originalAuthorName":"郭忠言"},{"authorName":"王玥","id":"8ce2f105-165e-406d-a84c-ea0fa8736262","originalAuthorName":"王玥"},{"authorName":"黄天衡","id":"e4ddf9e4-8a50-4dd8-aff2-6fd1b18e2a62","originalAuthorName":"黄天衡"},{"authorName":"张宏斌","id":"ab590c52-4810-43ce-b0ab-176c046ce053","originalAuthorName":"张宏斌"}],"doi":"","fpage":"203","id":"a16158e4-4023-4d5a-9436-abd42c3ad748","issue":"3","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":"cbde528c-a5e2-48c5-8ce1-afa3cdf6ec2e","keyword":"RIBLL","originalKeyword":"RIBLL"},{"id":"2b516902-7e10-499e-82ba-89030751b69e","keyword":"传输效率","originalKeyword":"传输效率"},{"id":"6fc51a2c-9f6d-48a1-a186-41e6111350ca","keyword":"MoCADl","originalKeyword":"MoCADl"},{"id":"03b09bf9-ae9c-4f59-ac40-ff79253b8ba0","keyword":"LISE++","originalKeyword":"LISE++"}],"language":"zh","publisherId":"yzhwlpl200903006","title":"RIBLL传输效率研究","volume":"26","year":"2009"}],"totalpage":3928,"totalrecord":39275}