{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"人工神经网络方法已被引入高能物理实验领域并被广泛地应用于夸克胶子喷注的鉴别、电子强子分辨、顶夸克和Higgs粒子的寻找等等。本文采用了一种改良的共轭梯度优化算法并应用于高能物理实验中粒子的鉴别。在该应用中，此算法既能实现每步迭代时在搜索方向上获得最优步长，又能避免目标函数陷入局部收敛点，从而使目标函数快速收敛，提高了算法的有效性。分析结果表明，我们改进后的BP算法显著地提高了粒子物理数据分析中的粒子鉴别能力。","authors":[{"authorName":"王树旺","id":"3ff61ee9-251a-4bb1-b6b6-36b876e086a0","originalAuthorName":"王树旺"},{"authorName":"路永钢","id":"4129e74f-e0e2-403b-a6ab-ebadaa0a509f","originalAuthorName":"路永钢"},{"authorName":"陈旭荣","id":"fc329e97-9ac0-4859-88b6-d8bf0779bc63","originalAuthorName":"陈旭荣"}],"doi":"10.11804/NuclPhysRev.31.03.401","fpage":"401","id":"874ebbb9-3575-4709-be04-c850ce3d1178","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":"e5d42aae-fcf9-47a1-87a8-67fa124128c8","keyword":"BP神经网络","originalKeyword":"BP神经网络"},{"id":"8405d4ee-2322-402d-bd43-a71233fe023f","keyword":"共轭梯度法","originalKeyword":"共轭梯度法"},{"id":"a4e930f2-20e5-444a-bd03-856722178b1a","keyword":"步长优化","originalKeyword":"步长优化"},{"id":"d40c0771-d0a6-4181-aabe-9f073c9ef407","keyword":"粒子鉴别","originalKeyword":"粒子鉴别"}],"language":"zh","publisherId":"yzhwlpl201403018","title":"基于共轭梯度优化算法的BP神经网络在高能粒子鉴别等领域中的应用","volume":"","year":"2014"},{"abstractinfo":"研究了σ相对核电一回路主管道Z3CN20.09M不锈钢冲击韧性的影响,利用原位拉伸、显微硬度、断口形貌等手段分析了σ相的脆化机理.结果表明,σ相显著降低一回路主管道不锈钢的冲击韧性,时效处理Z3CN20.09M不锈钢中以σ相为主的由铁素体共析分解生成的(σ+γ2)结构的硬度远高于奥氏体基体,两者变形协调性差,(σ+γ2)结构阻碍位错滑移,提高材料强度,同时降低塑性;(σ+γ2)结构内部存在大量高能量σ/γ2和α/σ/γ2非共格界面,变形时应力在此处集中,成为潜在裂纹源,易萌生裂纹.高应变速率下,裂纹迅速在其内部产生、扩展是材料韧性降低、变脆的本质原因.","authors":[{"authorName":"王永强","id":"33ae0e6d-7d0e-40a8-9731-99002b859b00","originalAuthorName":"王永强"},{"authorName":"杨滨","id":"6ed5037a-76d8-4f5b-ab62-12cd1831c372","originalAuthorName":"杨滨"},{"authorName":"李娜","id":"45fd0cd5-6c05-4586-b8db-837f7bfd841c","originalAuthorName":"李娜"},{"authorName":"林苏华","id":"58e74a49-9692-4d6f-addb-96b66f552311","originalAuthorName":"林苏华"},{"authorName":"孙立","id":"3b0a2f73-d90c-4fef-ad78-7eeed9bbe414","originalAuthorName":"孙立"}],"doi":"10.11900/0412.1961.2015.00180","fpage":"17","id":"fd679267-84af-48ff-9ffe-10a2e5b1940b","issue":"1","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"2a648520-ccea-486b-b932-08cc6cf7121c","keyword":"Z3CN20.09M不锈钢","originalKeyword":"Z3CN20.09M不锈钢"},{"id":"7bcdc402-bf45-4c5b-8edd-04b39c7c0987","keyword":"σ相","originalKeyword":"σ相"},{"id":"20cf49a4-7da1-426e-b759-a30f85b8147e","keyword":"韧性","originalKeyword":"韧性"},{"id":"c88e60ab-593f-4253-bfdf-42a7ae191731","keyword":"脆化机理","originalKeyword":"脆化机理"}],"language":"zh","publisherId":"jsxb201601003","title":"σ在核电一回路主管道不锈钢中的脆化机理","volume":"52","year":"2016"},{"abstractinfo":"通过模拟压水堆一回路水环境,对304和316L两种不锈钢进行了在含锌10μg/kg,320℃高温溶液中浸泡1 000 h的腐蚀试验,并对试验后的试样氧化膜进行SEM和XPS分析.结果表明,304不锈钢的腐蚀增重率高于316L,且其氧化膜较316L疏松;两种试样均形成了富铁、锌内富铬的氧化膜;外层氧化膜以(Zn,Fe,Ni)(Fe,Cr)2O4为主,内层以ZnCr2O4为主,氧化膜与基体过渡层以Cr2O3为主.","authors":[{"authorName":"段振刚","id":"b3f551e1-58b2-40a4-897f-634eed2a485b","originalAuthorName":"段振刚"},{"authorName":"沈朝","id":"8eb271c0-c8ea-4a4f-9d90-542a8d81a0ec","originalAuthorName":"沈朝"},{"authorName":"张乐福","id":"2ddc7713-8cc8-4690-aa7c-1160d76aaa3a","originalAuthorName":"张乐福"},{"authorName":"王力","id":"b92e7d1a-a884-4dbc-b72a-bdc67b3280b1","originalAuthorName":"王力"},{"authorName":"徐雪莲","id":"c2373abd-17c6-4a6f-85d3-6e9978358022","originalAuthorName":"徐雪莲"},{"authorName":"石秀强","id":"e651a322-de49-4f31-8d5d-28c9d5aa49ed","originalAuthorName":"石秀强"}],"doi":"","fpage":"637","id":"79ffb6e6-c86c-45c2-8120-1f4108c99dfa","issue":"7","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"84077071-772c-4482-be14-8e298b27f001","keyword":"压水堆","originalKeyword":"压水堆"},{"id":"57fb701a-156e-4a68-945b-08a13555d689","keyword":"304不锈钢","originalKeyword":"304不锈钢"},{"id":"faf523c6-efaa-43ce-ae2f-8eb1607fe09c","keyword":"316L不锈钢","originalKeyword":"316L不锈钢"},{"id":"2715610a-11e6-4c59-9710-e87b08d6b47b","keyword":"含锌溶液","originalKeyword":"含锌溶液"},{"id":"cb312787-8b0f-4c66-baad-fa619fce8cd0","keyword":"XPS分析","originalKeyword":"XPS分析"}],"language":"zh","publisherId":"fsyfh201407003","title":"奥氏体不锈钢在含锌PWR一回路水中的均匀腐蚀行为","volume":"35","year":"2014"},{"abstractinfo":"

研究了s相对核电一回路主管道Z3CN20.09M不锈钢冲击韧性的影响, 利用原位拉伸、显微硬度、断口形貌等手段分析了s相的脆化机理. 结果表明, s相显著降低一回路主管道不锈钢的冲击韧性, 时效处理Z3CN20.09M不锈钢中以s相为主的由铁素体共析分解生成的(s+g₂)结构的硬度远高于奥氏体基体, 两者变形协调性差, (s+g₂)结构阻碍位错滑移, 提高材料强度, 同时降低塑性; (s+g₂)结构内部存在大量高能量s/g₂ 和a/s/g₂非共格界面, 变形时应力在此处集中, 成为潜在裂纹源, 易萌生裂纹. 高应变速率下, 裂纹迅速在其内部产生、扩展是材料韧性降低、变脆的本质原因.

","authors":[{"authorName":"王永强","id":"61c9cc84-a39f-4b96-9e71-7f400be12661","originalAuthorName":"王永强"},{"authorName":"杨滨","id":"1e6e0da0-ba1b-4bbf-b12f-4fd19c7fd72f","originalAuthorName":"杨滨"},{"authorName":"李娜","id":"73b45dcc-43d5-4cf9-9b22-7a38b1c9ea3a","originalAuthorName":"李娜"},{"authorName":"林苏华","id":"918d5df5-de4d-44ba-be0b-7de18652d7c3","originalAuthorName":"林苏华"},{"authorName":"孙立","id":"c885eee6-627e-4c69-826a-57b3dd7d2a89","originalAuthorName":"孙立"}],"categoryName":"","doi":"10.11900/0412.1961.2015.00180","fpage":"17","id":"44dba17e-1f12-4138-81e2-65298c39f468","issue":"1","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"f64f7a70-8448-4dd9-9f4e-b0f54465f73d","keyword":"Z3CN20.09M不锈钢","originalKeyword":"Z3CN20.09M不锈钢"},{"id":"cf28955a-4f17-46e4-a819-7a00674eeaeb","keyword":"s相","originalKeyword":"s相"},{"id":"4de66f7d-1e01-43c1-9f12-a7fa95ba12ae","keyword":"韧性","originalKeyword":"韧性"},{"id":"20fe452f-54e1-4cf0-8d4f-04d4982d0b6a","keyword":"脆化机理","originalKeyword":"脆化机理"}],"language":"zh","publisherId":"C20150180","title":"σ相在核电一回路主管道不锈钢中的脆化机理^*","volume":"52","year":"2016"},{"abstractinfo":"为研究AP1000一回路冷却剂中加锌对安全端同材焊接区域的影响,采用金相显微镜、扫描电镜(SEM)、能谱仪以及X射线光电子能谱仪(XPS)等测试方法,分析了316LN/316L不锈钢焊接接头在模拟压水堆一回路冷却剂加锌环境下的氧化特性.结果表明:焊接接头母材区、热影响区和焊缝区的金相组织之间存在明显的熔合线,母材区与热影响区均为奥氏体,且热影响区晶粒稍显粗大,焊缝区则有少量铁素体析出;未加锌环境中母材区氧化膜呈黑色,焊缝区氧化膜呈暗红色,氧化膜表面与焊缝区无明显差异;加锌10 μg/L母材区与焊缝区氧化膜均呈现黑色,比未加锌时焊接接头氧化物的颗粒更小,未加锌焊缝区的氧化膜比母材区更薄;加锌溶液中各区域氧化膜厚度趋于一致,比未加锌的减小近45％.","authors":[{"authorName":"辛长胜","id":"cec8da01-abc4-40c6-9d80-2d5023a4a01b","originalAuthorName":"辛长胜"},{"authorName":"海正银","id":"92aa7fba-bc79-4825-ba5c-9a467234b483","originalAuthorName":"海正银"},{"authorName":"王辉","id":"18a9196b-d30a-422b-9154-0ac47377a715","originalAuthorName":"王辉"},{"authorName":"胡勇","id":"e401e632-0afc-46a2-9f88-e6c3ef742fc5","originalAuthorName":"胡勇"},{"authorName":"曹林园","id":"95288850-8923-400a-863d-33307129f98c","originalAuthorName":"曹林园"},{"authorName":"王瑞阳","id":"34d0d819-8ce8-4c81-81fc-0b1ca973c0c3","originalAuthorName":"王瑞阳"}],"doi":"","fpage":"36","id":"1b5dd76f-28ff-4f5d-91d3-93bedb906a1d","issue":"4","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"6d2987b2-66e0-46b1-8266-5c661ffbe4c5","keyword":"不锈钢焊接接头","originalKeyword":"不锈钢焊接接头"},{"id":"1a641e19-dae5-48d5-a58a-35b4e94b122f","keyword":"腐蚀行为","originalKeyword":"腐蚀行为"},{"id":"af86ca32-2ee6-49a7-96eb-854a268042aa","keyword":"压水堆","originalKeyword":"压水堆"},{"id":"e63b5b31-e38f-45e0-9441-d6fce58ebb81","keyword":"加锌","originalKeyword":"加锌"},{"id":"c5ddb992-0fda-49ed-8d59-f61b9e6a867d","keyword":"氧化膜","originalKeyword":"氧化膜"}],"language":"zh","publisherId":"clbh201504011","title":"压水堆一回路冷却剂中加锌对不锈钢焊接接头腐蚀行为的影响","volume":"48","year":"2015"},{"abstractinfo":"通过模拟压水堆一回路水环境,对304奥氏体不锈钢在320℃含Zn分别为60和120 μg/kg两种高温溶液中进行了600 h的腐蚀实验,对腐蚀后的试样表面进行了X射线光电子能谱分析(XPS)分析.结果表明,试样在含锌溶液中形成了主要化学成分为Zn(Cr,Fe)2O4的致密氧化膜;提高溶液中Zn的浓度,试样的腐蚀速率降低,氧化膜中Fe含量增多.","authors":[{"authorName":"段振刚","id":"83e997c8-0fea-47bf-bdd9-6eec44d9ba79","originalAuthorName":"段振刚"},{"authorName":"张乐福","id":"a3ab97c0-1411-47e0-abe2-d02b683d9658","originalAuthorName":"张乐福"},{"authorName":"王力","id":"6e1bc4ba-a4b0-4869-bfda-f44541083d73","originalAuthorName":"王力"},{"authorName":"徐雪莲","id":"69ca1793-8e69-4d8d-9623-b44a1db4a53c","originalAuthorName":"徐雪莲"},{"authorName":"石秀强","id":"079a9884-0fd2-4016-9cbc-4cab25323dc9","originalAuthorName":"石秀强"}],"doi":"","fpage":"237","id":"934300e1-423f-49dd-a15a-7f969e3e2135","issue":"3","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报（英文）"},"keywords":[{"id":"70273d0c-2fcd-45a5-9667-28d9df60b9da","keyword":"Zn","originalKeyword":"Zn"},{"id":"4b5c12e9-b6b0-48ec-9dbe-ff1542ddd389","keyword":"304奥氏体不锈钢","originalKeyword":"304奥氏体不锈钢"},{"id":"d5d499d6-e7ec-4122-9420-55ea1fac67b5","keyword":"压水堆","originalKeyword":"压水堆"},{"id":"2c76c0d9-38f7-4171-adc9-7cd867dd5cb3","keyword":"氧化膜","originalKeyword":"氧化膜"},{"id":"7a8d2b0a-8f27-4efa-b963-bac9d327cc99","keyword":"XPS","originalKeyword":"XPS"}],"language":"zh","publisherId":"fskxyfhjs201403008","title":"模拟压水堆一回路水环境中Zn对304奥氏体不锈钢氧化膜成分的影响研究","volume":"26","year":"2014"},{"abstractinfo":"采用扫描电镜(SEM)、X射线衍射(XRD)、X射线光电子能谱(XPS)和透射电镜(TEM)分析了不同溶解氢含量下， 316L不锈钢在325℃的模拟压水堆一回路水中形成的氧化膜的形貌、结构和成份。实验结果表明， 316L不锈钢在溶解氢含量为零的高温高压水中形成外层富铁，内层富铬的双层氧化膜。随着水中溶解氢含量的升高，氧化膜外层的大颗粒氧化物尺寸减小，排列更加致密。而氧化膜的物相组成变化不明显，均主要是由尖晶石结构氧化物构成。XPS分析表明，随着水中溶解氢含量的升高，氧化膜厚度逐渐增加，且氧化膜中Ni含量升高，Cr含量降低。","authors":[{"authorName":"彭青姣","id":"9379d85a-2efb-4d2e-ba38-bc9664f8f4b0","originalAuthorName":"彭青姣"},{"authorName":"张志明","id":"e9b925c7-7777-45f1-8947-73b7270b4fb2","originalAuthorName":"张志明"},{"authorName":"王俭秋","id":"34680712-b2a5-4999-b041-3c7bdd5382e7","originalAuthorName":"王俭秋"},{"authorName":"韩恩厚","id":"98193cc6-207f-40ad-af02-14ac55c97ca4","originalAuthorName":"韩恩厚"},{"authorName":"柯伟","id":"d529b759-9cc1-41d7-b911-849e1d16faa5","originalAuthorName":"柯伟"}],"categoryName":"|","doi":"","fpage":"217","id":"5a96b217-7780-4bbd-bbcd-8e201712270a","issue":"3","journal":{"abbrevTitle":"ZGFSYFHXB","coverImgSrc":"journal/img/cover/中国腐蚀封面19-3期-01.jpg","id":"81","issnPpub":"1005-4537","publisherId":"ZGFSYFHXB","title":"中国腐蚀与防护学报"},"keywords":[{"id":"309693fa-a4ed-4dc4-ab75-e47ed7fdd200","keyword":"316L不锈钢","originalKeyword":"316L不锈钢"},{"id":"c9972f88-b2c5-4c9d-b1a9-fa806dbec9a7","keyword":"high-temperature and high-pressure water","originalKeyword":"high-temperature and high-pressure water"},{"id":"2c4b2857-0ff6-4274-9611-9dfc2ca1c280","keyword":"oxide film","originalKeyword":"oxide film"},{"id":"ee3cbb36-d783-42d7-9ac2-f6f9c5610ce6","keyword":"dissolved hydrogen","originalKeyword":"dissolved hydrogen"}],"language":"zh","publisherId":"1005-4537_2012_3_15","title":"溶解氢对316L不锈钢在模拟压水堆一回路水中氧化行为的影响","volume":"32","year":"2012"},{"abstractinfo":"采用十八胺对永固红F5R进行化学修饰,以Span-80为稳定剂,四氯乙烯为分散介质,制备了分散性和稳定性良好的电泳液.以此电泳液为囊芯,脲甲醛树脂为壁材,制备了一种红色电子墨水微胶囊,研究了投料比、合成温度、酸化时间和搅拌速度等对合成微胶囊的影响.结果表明,合成的微胶囊形貌呈规则球形,表面光滑,囊壁结构致密,强度较好,包覆率达到82%,囊芯含量达到76%.永固红F5R电泳液微胶囊具有明显的电场响应行为,可以作为柔板显示器的功能材料.","authors":[{"authorName":"倪卓","id":"e029822e-b1ed-424a-b43f-a3d2d95f646c","originalAuthorName":"倪卓"},{"authorName":"李丹","id":"f887ef04-3dc6-455f-86fc-9eaf77647b61","originalAuthorName":"李丹"},{"authorName":"钟玉莲","id":"6e3369c1-b82c-4882-b5ad-f92b613051e0","originalAuthorName":"钟玉莲"},{"authorName":"刘丽双","id":"d3c287ad-6acf-4232-8eae-a680e7e1a76f","originalAuthorName":"刘丽双"},{"authorName":"陈展明","id":"baa30c08-d528-444e-a1d0-a9e6d19f0be8","originalAuthorName":"陈展明"}],"doi":"","fpage":"101","id":"d12b9eff-6442-431e-95ec-d7cd2e3641e6","issue":"20","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"6e0a5c0b-b00d-482d-8087-7395d7978cd1","keyword":"电子墨水","originalKeyword":"电子墨水"},{"id":"992b930c-12f3-4576-8e3c-b39ae1c29e47","keyword":"微胶囊","originalKeyword":"微胶囊"},{"id":"e7f3811b-05f8-4d67-9e95-425b0fecdb1c","keyword":"永固红F5R","originalKeyword":"永固红F5R"},{"id":"aa0d839f-6344-4e50-88fd-9805b4855b0d","keyword":"电场响应","originalKeyword":"电场响应"}],"language":"zh","publisherId":"cldb200920030","title":"永固红F5R电泳液微胶囊的制备和表征","volume":"23","year":"2009"},{"abstractinfo":"利用扫描电镜(SEM)、X射线光电子谱技术(XPS)、和X射线衍射(XRD)技术,分析了国产锻造态316LNSS在加氢高温高压水中浸泡480h后表面氧化膜的形貌和化学成分.结果表明,氧化膜最外层主要分布两种不同尺寸的氧化物颗粒,大尺寸氧化物(～1 nnn)分布较为稀疏,而小尺寸氧化物(200～300 nm)分布非常紧密;锻造态316LNSS表面形成外层富Fe、内层富Cr的双层结构氧化膜,外层氧化膜主要由Fe3O4和少量氢氧化物(Ni(OH)2和CrOOH等)组成,内层氧化膜主要由富Cr尖晶石结构氧化物组成.同时讨论了316LNSS在模拟压水堆一回路水中的氧化机制.","authors":[{"authorName":"郭跃岭","id":"ffdf631d-3274-4755-9820-36a3e323f270","originalAuthorName":"郭跃岭"},{"authorName":"韩恩厚","id":"0adffe96-c3f6-4b8a-88ea-f8ba6be84688","originalAuthorName":"韩恩厚"},{"authorName":"王俭秋","id":"ffe8ddb2-5bee-4280-8305-957091509b17","originalAuthorName":"王俭秋"}],"doi":"10.11903/1002.6495.2014.268","fpage":"313","id":"fcfa9475-de44-45a7-a641-4f5480280e3b","issue":"4","journal":{"abbrevTitle":"FSXB","coverImgSrc":"journal/img/cover/腐蚀学报封面.jpg","id":"24","issnPpub":"2667-2669","publisherId":"FSXB","title":"腐蚀学报（英文）"},"keywords":[{"id":"705d9b46-44cd-4257-8937-fdc0a0db5540","keyword":"核电材料","originalKeyword":"核电材料"},{"id":"4a03db5c-7104-4baa-8651-2c2cf9e1fbcd","keyword":"不锈钢","originalKeyword":"不锈钢"},{"id":"55d9b18b-87df-42e5-b095-88f813d4f7ad","keyword":"锻造","originalKeyword":"锻造"},{"id":"e0edaa1a-32cd-4043-b178-70cdc24335f2","keyword":"氧化膜","originalKeyword":"氧化膜"},{"id":"94799b15-6b89-4d03-9af3-efe94c90884c","keyword":"腐蚀","originalKeyword":"腐蚀"},{"id":"c766c9b8-40d8-47c8-928c-6b2bc04ce37c","keyword":"高温高压水","originalKeyword":"高温高压水"}],"language":"zh","publisherId":"fskxyfhjs201504001","title":"锻造态316LN不锈钢在模拟压水堆一回路水中的初期氧化行为","volume":"27","year":"2015"},{"abstractinfo":"本试验主要研究目的是SBS改性剂、相容剂、稳定剂、剪切速率、剪切时间、发育时间对永古高速公路SBS改性沥青性能的影响.查阅该地区沥青路面资料,初步确定在相容剂掺量1.5％,稳定剂掺量1.5‰的前提下,通过对沥青软化点、25℃的针入度、5℃的延度、离析软化点差进行试验,对试验结果进行分析,最终确定SBS改性沥青的SBS改性剂掺量3.8％、相容剂掺量1.5％、稳定剂掺量2‰.在此SBS改性沥青的前提下,研究剪切速率、剪切时间、发育时间对SBS改性沥青的影响,在剪切时间30 min,发育时间90 min的前提下,继续对沥青软化点、25℃的针入度、5℃的延度进行试验,整理分析数据,得到最终的制备工艺为:剪切速率5500 r·min-1、剪切时间35 min、发育时间为120 min.得到结论为永古高速SBS改性沥青为:SBS改性剂掺量3.8％、相容剂掺量1.5％、稳定剂掺量2‰、剪切速率5500 r·min-1、剪切时间35 min、发育时间120 min.","authors":[{"authorName":"杨成","id":"49e1bb34-385e-450e-b15a-d087702dd672","originalAuthorName":"杨成"},{"authorName":"刘德仁","id":"5e1cc12a-3310-4b99-987e-685849267cce","originalAuthorName":"刘德仁"},{"authorName":"王旭","id":"3f7ebb88-9706-4ed1-a295-874f3dd09b5e","originalAuthorName":"王旭"},{"authorName":"刘国太","id":"b788fc37-667e-45b2-84cf-868fbfcd442e","originalAuthorName":"刘国太"}],"doi":"","fpage":"1956","id":"f7099de0-276a-4990-90b1-bf620a4ab25c","issue":"8","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报 "},"keywords":[{"id":"e07d0294-fda5-4a30-ae4d-66ec36aeb26e","keyword":"改性沥青","originalKeyword":"改性沥青"},{"id":"54db9649-1e0d-4ed1-81e9-84b273668a97","keyword":"SBS改性剂","originalKeyword":"SBS改性剂"},{"id":"45690fb2-dbab-4f89-ab83-bed0ff385565","keyword":"相容剂","originalKeyword":"相容剂"},{"id":"13cee48f-5a15-4e51-a5a2-3315010837ac","keyword":"稳定剂","originalKeyword":"稳定剂"},{"id":"4084d161-2ce7-4acd-9e1d-3c8c5bdc64d4","keyword":"生产工艺","originalKeyword":"生产工艺"}],"language":"zh","publisherId":"gsytb201408018","title":"永古高速公路SBS改性沥青试验研究","volume":"33","year":"2014"}],"totalpage":2348,"totalrecord":23471}