{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"目的 对比三氮唑( TA)和苯并三氮唑( BTA)两种缓蚀剂的缓蚀性能,明确两种缓蚀剂在铜表面的吸附类型,并从实验和分子模拟角度解释其吸附机理. 方法 采用动电位极化曲线法测试两种缓蚀剂的缓蚀效率,采用吸附等温拟合方法确定两种缓蚀剂的吸附类型,采用分子模拟中的量子化学计算方法计算两种缓蚀剂在铜表面的吸附能、形变电荷密度和分波态密度等参数,深入揭示其吸附机理. 结果 在不同浓度下,BTA的缓蚀效率均大于TA. 两种缓蚀剂浓度与覆盖度的关系符合Langmuir吸附模型,其吸附自由能介于-35~-37 kJ/mol之间. BTA在铜表面的吸附能绝对值(顶位为4. 41 eV,桥位为4. 36 eV)要大于TA的吸附能绝对值(3. 28 eV),吸附过程发生了明显的电荷转移,电子<span style=\"color:red\">云</span>处于两个成键原子之间,且N原子s,p轨道与Cu原子d轨道发生重叠. 中性和质子化形式的两种缓蚀剂分子均可在铜表面发生平行吸附. 结论 由于BTA在铜表面的吸附能力强于TA,因此BTA的缓蚀性能优于TA. 两种缓蚀剂在铜表面既能发生化学吸附,又能发生物理吸附. 化学吸附是由于N原子的s,p轨道与Cu原子d轨道相互作用所致,物理吸附是由于中性分子的范德华相互作用和质子化分子的静电相互作用所致.","authors":[{"authorName":"廉兵杰","id":"946fb0c5-2f81-4588-b6de-3faa3a69cbed","originalAuthorName":"廉兵杰"},{"authorName":"石泽民","id":"aef18016-557f-442c-96a6-1b86b5fb872b","originalAuthorName":"石泽民"},{"authorName":"徐慧","id":"9e4b0e1e-4f6b-45e9-bc4d-98987ef9a21e","originalAuthorName":"徐慧"},{"authorName":"赵起锋","id":"84d3195a-89c7-4c48-8167-c4e0617d0f0c","originalAuthorName":"赵起锋"},{"authorName":"王木立","id":"b3b2cd91-8de0-4b21-b507-037a3f8e06f0","originalAuthorName":"王木立"},{"authorName":"<span style=\"color:red\">姜</span><span style=\"color:red\">云</span><span style=\"color:red\">瑛</span>","id":"07d2008e-1493-48c6-88a4-cfad848be959","originalAuthorName":"姜云瑛"},{"authorName":"胡松青","id":"80f312ce-903a-4810-a192-e7e2dd4e97b7","originalAuthorName":"胡松青"}],"doi":"10.16490/j.cnki.issn.1001-3660.2015.12.004","fpage":"19","id":"339e6e9d-1240-4791-bcfb-9d560825324d","issue":"12","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术   "},"keywords":[{"id":"011f6d79-a128-4d51-b25c-84d9bea115f0","keyword":"唑类有机物","originalKeyword":"唑类有机物"},{"id":"dd53c746-2941-41a3-b111-74bdb6a19660","keyword":"缓蚀剂","originalKeyword":"缓蚀剂"},{"id":"ed683ca9-e2c3-468f-8048-a07e1aeac771","keyword":"吸附机理","originalKeyword":"吸附机理"},{"id":"455ae455-8e11-45ed-8552-cd569125c8ef","keyword":"动电位极化曲线","originalKeyword":"动电位极化曲线"},{"id":"5fe712a7-c06a-468c-a7ce-464d437bdb65","keyword":"密度泛函理论","originalKeyword":"密度泛函理论"},{"id":"e5b65b3f-2d46-4895-867d-a6ed546574d5","keyword":"分波态密度","originalKeyword":"分波态密度"}],"language":"zh","publisherId":"bmjs201512004","title":"唑类缓蚀剂在铜表面的吸附机理","volume":"44","year":"2015"},{"abstractinfo":"用超临界CO2萃取生姜根茎中的<span style=\"color:red\">姜</span>油树脂,并用气相色谱-质谱联用技术对其进行了成分分析.从<span style=\"color:red\">姜</span>油树脂中分析出77种化合物,其中挥发油成分50种,主要是α-<span style=\"color:red\">姜</span>烯(22.29%)、β-倍半水芹烯(8.58%)、α-法尼烯(3.93%)、β-没药烯(3.87%)和α-姜黄烯(2.63%)等倍半萜类化合物;<span style=\"color:red\">姜</span>辣素成分27种,主要成分为6-<span style=\"color:red\">姜</span>酚(9.38%)、6-<span style=\"color:red\">姜</span>烯酚(7.59%)和分析过程中由<span style=\"color:red\">姜</span>酚类或<span style=\"color:red\">姜</span>烯酚类化合物受热分解而形成的<span style=\"color:red\">姜</span>油酮(9.24%).在<span style=\"color:red\">姜</span>辣素成分中,6-异<span style=\"color:red\">姜</span>酚、(Z)-10-异<span style=\"color:red\">姜</span>烯酚和(E)-10-异<span style=\"color:red\">姜</span>烯酚3种化合物是新发现的未见报道的化合物.实验中对这3种新化合物进行了质谱裂解分析.","authors":[{"authorName":"战琨友","id":"18029250-7538-4dbd-a479-4a7c758cfe80","originalAuthorName":"战琨友"},{"authorName":"王超","id":"e25f333c-dd8d-45ed-9015-ba6126bcf7cd","originalAuthorName":"王超"},{"authorName":"徐坤","id":"e8424cb6-b0d4-46ed-8fa2-c673af3ec31c","originalAuthorName":"徐坤"},{"authorName":"尹洪宗","id":"ec76914e-8f6c-4f7e-afaf-bbc7cda8c69f","originalAuthorName":"尹洪宗"}],"doi":"10.3321/j.issn:1000-8713.2008.06.009","fpage":"692","id":"42c1bbc0-652a-433f-8e34-86f30b7f6523","issue":"6","journal":{"abbrevTitle":"SP","coverImgSrc":"journal/img/cover/SP.jpg","id":"58","issnPpub":"1000-8713","publisherId":"SP","title":"色谱 "},"keywords":[{"id":"e53773ad-891b-403b-8b22-f5b0686630e3","keyword":"超临界萃取","originalKeyword":"超临界萃取"},{"id":"286cbdc0-600d-40b3-affc-527a1b3253a4","keyword":"气相色谱-质谱联用技术","originalKeyword":"气相色谱-质谱联用技术"},{"id":"7ed48749-e650-4478-96ef-9741cba04e1c","keyword":"<span style=\"color:red\">姜</span>油树脂","originalKeyword":"姜油树脂"},{"id":"bf6fde50-9a7b-42f4-953e-bf1116bcbb98","keyword":"成分分析","originalKeyword":"成分分析"}],"language":"zh","publisherId":"sp200806009","title":"气相色谱-质谱技术分析<span style=\"color:red\">姜</span>油树脂中的挥发性及非挥发性成分","volume":"26","year":"2008"},{"abstractinfo":"为了比较几种自动化测云仪器的性能,中国气象局气象探测中心在南京信息工程大学的气象探测基地首次组织了一次为期近5个月的比对试验,试验仪器包括四台激光<span style=\"color:red\">云</span>高仪、两部红外测云仪、一台全天空成像仪以及一部毫米波<span style=\"color:red\">云</span>雷达.对其中大部分仪器取得的三个月<span style=\"color:red\">云</span>底高度数据进行了初步分析,结果表明:三台激光<span style=\"color:red\">云</span>高仪测量结果比较一致；两部红外测云仪在测量低云时一致性稍差；<span style=\"color:red\">云</span>雷达与激光<span style=\"color:red\">云</span>高仪测量的最低层云底高度数据一致性较差,但与红外测云仪的测量结果匹配较好.","authors":[{"authorName":"黄兴友","id":"ab1918ea-4979-44a9-bc78-6a184f16960f","originalAuthorName":"黄兴友"},{"authorName":"胡汉峰","id":"e31b1f2c-a61b-466b-a0e8-23915c86b389","originalAuthorName":"胡汉峰"},{"authorName":"夏俊荣","id":"f8fcf8ee-ece7-4b2b-9022-f14685b68fa8","originalAuthorName":"夏俊荣"},{"authorName":"卜令兵","id":"d2123620-5158-4198-aa7d-c86d5eaaa362","originalAuthorName":"卜令兵"},{"authorName":"张雪芬","id":"f5e54ac7-727f-4888-aaf6-bb7be02faf50","originalAuthorName":"张雪芬"},{"authorName":"雷勇","id":"65805f0d-18fe-4259-9178-d3380e50a32f","originalAuthorName":"雷勇"},{"authorName":"黄建松","id":"f8f737b5-899d-4bb5-a695-4f2ce0acc798","originalAuthorName":"黄建松"},{"authorName":"王巍巍","id":"263663b2-cd8b-402d-aa28-a1281907f1ce","originalAuthorName":"王巍巍"},{"authorName":"吴迪","id":"f9cb8422-eb40-4180-8dba-b1dbece6c1c0","originalAuthorName":"吴迪"},{"authorName":"蒋昌华","id":"2fab0bdb-dbb3-4248-89ea-8cd2cf0113d8","originalAuthorName":"蒋昌华"}],"doi":"10.3969/j.issn.1007-5461.2013.01.013","fpage":"73","id":"9958e720-9dba-4430-bfc1-dce894108b82","issue":"1","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":"515e85eb-4059-4f54-808a-baed98faaab2","keyword":"大气光学","originalKeyword":"大气光学"},{"id":"08f03b33-4a9d-4eb8-95c9-db91bcd5e415","keyword":"<span style=\"color:red\">云</span>底高","originalKeyword":"云底高"},{"id":"e161ff5d-2d6c-45c4-9da4-02a4841c291e","keyword":"激光<span style=\"color:red\">云</span>高仪","originalKeyword":"激光云高仪"},{"id":"5dfeb526-9cc5-4ba1-97c6-934661e00f12","keyword":"红外测云仪","originalKeyword":"红外测云仪"},{"id":"e3470aec-3087-4fbe-859f-07adb1c6dc67","keyword":"<span style=\"color:red\">云</span>雷达","originalKeyword":"云雷达"}],"language":"zh","publisherId":"lzdzxb201301013","title":"<span style=\"color:red\">云</span>底高度的激光<span style=\"color:red\">云</span>高仪、红外测云仪以及<span style=\"color:red\">云</span>雷达观测比对分析","volume":"30","year":"2013"},{"abstractinfo":"招平断裂南段的夏甸-<span style=\"color:red\">姜</span>家窑金矿床受断裂产状变化、断层泥、脉岩、次级断裂复合控制.矿体多赋存于蚀变分带明显、产状由缓变陡处、脉岩的下盘,并具北东侧伏及尖灭再现规律.","authors":[{"authorName":"王慧","id":"7fb4a685-ee01-4317-819a-300c21af4083","originalAuthorName":"王慧"},{"authorName":"丛成双","id":"061afad7-97f4-4639-b4cd-68988fd1f17e","originalAuthorName":"丛成双"},{"authorName":"丛培章","id":"c090b397-22b7-4f56-ba4e-2c18ca877e09","originalAuthorName":"丛培章"}],"doi":"10.3969/j.issn.1001-1277.2003.08.004","fpage":"12","id":"8bf4c3f0-63ec-49ae-a9a0-0667a8411238","issue":"8","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"10e6b959-ddde-4db4-b855-31927c89ad94","keyword":"赋存规律","originalKeyword":"赋存规律"},{"id":"cc25cee2-8e48-436f-99af-04df19dba09c","keyword":"控矿规律","originalKeyword":"控矿规律"},{"id":"6575bbc0-457d-43a2-88fc-6b2f84731b46","keyword":"夏甸-<span style=\"color:red\">姜</span>家窑金矿床","originalKeyword":"夏甸-姜家窑金矿床"}],"language":"zh","publisherId":"huangj200308004","title":"夏甸—<span style=\"color:red\">姜</span>家窑金矿床矿体赋存规律及控矿规律研究","volume":"24","year":"2003"},{"abstractinfo":"<span style=\"color:red\">姜</span>家窑金矿根据国内外矿山竖井提升现状,经过较详细地理论计算,自行设计出提升容器及配套系统,在该矿得到了应用,并取得了竖井小断面(1.8m×2.7m),卷扬机小型号(φ1.2m双卷筒卷扬机)、提升能力大(达到300～470t/d)的可喜成果,为矿山竖井开拓设计和竖井改造提供了一条可借鉴的经验.","authors":[{"authorName":"郭建军","id":"783308e8-87b6-40f3-9c39-7feb3a63137e","originalAuthorName":"郭建军"},{"authorName":"马玉山","id":"b94224e7-ec93-4950-896c-062c77ba65e2","originalAuthorName":"马玉山"},{"authorName":"贾汉义","id":"ada19182-f707-40f2-80b0-796996b18f85","originalAuthorName":"贾汉义"},{"authorName":"李勇","id":"36bfaa12-893d-443b-b747-041645e6db4e","originalAuthorName":"李勇"}],"doi":"10.3969/j.issn.1001-1277.2002.06.007","fpage":"21","id":"321851a5-c603-4614-8ce4-0bd2be6f3478","issue":"6","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"869cd681-9122-4747-ba4f-9ac4614bdc37","keyword":"竖井","originalKeyword":"竖井"},{"id":"5d0ede2b-afe1-4b9c-9648-37d619c8edb8","keyword":"提升容器","originalKeyword":"提升容器"},{"id":"43140e8c-cc3b-48d2-aa61-b07004268c15","keyword":"配套系统","originalKeyword":"配套系统"},{"id":"8430467d-ad62-43e8-aea9-26e36a7d5c72","keyword":"研究","originalKeyword":"研究"},{"id":"394bd3ab-4dde-451f-947f-57d830b95fb9","keyword":"应用","originalKeyword":"应用"}],"language":"zh","publisherId":"huangj200206007","title":"<span style=\"color:red\">姜</span>家窑金矿盲竖井提升容器及配套系统的研究与应用","volume":"23","year":"2002"},{"abstractinfo":"为了合理利用<span style=\"color:red\">云</span>铜渣,采用ITmk3工艺获得高质量粒铁,在实验室条件下进行了一系列的基础研究.通过比较试样全铁质量和熔分得到的粒铁质量,得到了金属铁的收得率,结合化学分析方法,分别得到了试样还原后的金属化率以及熔分后金属铁中的碳质量分数,研究了各个因素对以上指标的影响规律,形成了对<span style=\"color:red\">云</span>铜渣合理还原熔分的工艺路线,得到如下结论:渣熔化是形成粒铁的必要条件,铁的聚合程度取决于渣铁分离熔化之前铁的渗碳质量分数.渣中SiO2的存在是渣相低熔点的根本原因,碱度改变时<span style=\"color:red\">云</span>铜渣的熔化区间会发生变化,但对熔化开始温度的影响不显著.当碱度大于0.4后,添加CaO能显著地提高云铜渣的还原性能.","authors":[{"authorName":"何鹏","id":"dbab97f5-d12b-4a0a-bad0-a959625d6185","originalAuthorName":"何鹏"},{"authorName":"张俊","id":"d83fb0b5-604e-42e2-9c21-05d815abb339","originalAuthorName":"张俊"},{"authorName":"严定鎏","id":"858533e8-e701-4864-8fb8-af36b4f5ef2f","originalAuthorName":"严定鎏"}],"doi":"10.13228/j.boyuan.issn1006-9356.20160096","fpage":"33","id":"782f7e45-0426-4cf2-b982-c59def030561","issue":"2","journal":{"abbrevTitle":"ZGYJ","coverImgSrc":"journal/img/cover/ZGYJ.jpg","id":"87","issnPpub":"1006-9356","publisherId":"ZGYJ","title":"中国冶金"},"keywords":[{"id":"ddcf7b2d-9641-4743-9350-5b22fc2aa278","keyword":"铜渣","originalKeyword":"铜渣"},{"id":"3f5d464c-f42b-4dc2-ba77-4bacbda434a6","keyword":"还原熔分","originalKeyword":"还原熔分"},{"id":"d9a3b998-0a4a-47a8-b6a4-627dfffb5032","keyword":"渗碳","originalKeyword":"渗碳"},{"id":"6a3f5d91-7e3a-4681-a996-c8999f34749a","keyword":"粒铁","originalKeyword":"粒铁"}],"language":"zh","publisherId":"zgyj201702007","title":"<span style=\"color:red\">云</span>铜铜渣还原熔分试验分析","volume":"27","year":"2017"},{"abstractinfo":"采用熵权法和<span style=\"color:red\">云</span>模型判定岩爆等级。选用岩石的单轴抗压强度σc、单轴抗拉强度σt、切向应力σθ、岩石的压拉比σc/σt、岩石的应力系数σθ/σc和岩石的弹性变形指数Wet作为岩爆等级判定的因素建立岩爆评价指标体系。以收集到209组工程中的实际岩爆情况及数据作为样本进行分析计算，建立岩爆等级判定的熵权?<span style=\"color:red\">云</span>模型。运用该分析模型分析岩爆评价指标体系中评价指标的敏感性，并对收集到的工程实例岩爆情况进行判定，将结果与 Bayes、KNN 和随机森林方法的判定结果进行比较。研究表明：评价指标体系中指标敏感性由大到小的顺序为：sq/sc、sq、Wet、sc/st、st、sc；熵权?<span style=\"color:red\">云</span>模型的判别准确率比Bayes、K最邻近结点算法(KNN)和随机森林(RF)方法高。","authors":[{"authorName":"周科平","id":"8edaa450-0471-486c-b107-6def1b6b93eb","originalAuthorName":"周科平"},{"authorName":"林允","id":"170e43b7-c3d2-4763-953f-abb08d133d44","originalAuthorName":"林允"},{"authorName":"邓红卫","id":"1d1b4f8c-61fb-420b-8814-3c85ac78b77e","originalAuthorName":"邓红卫"},{"authorName":"李杰林","id":"f04d7317-af61-4dd1-92eb-36e5d145d100","originalAuthorName":"李杰林"},{"authorName":"刘传举","id":"7d94fca1-8e97-49a9-aeb5-d9f2663586ff","originalAuthorName":"刘传举"}],"doi":"10.1016/S1003-6326(16)64313-3","fpage":"1995","id":"2c99e462-3b7c-4947-813f-a2fd53be1405","issue":"7","journal":{"abbrevTitle":"ZGYSJSXBEN","coverImgSrc":"journal/img/cover/ZGYSJSXBEN.jpg","id":"757390d2-7d95-4517-96f1-e467ce1bff63","issnPpub":"1003-6326","publisherId":"ZGYSJSXBEN","title":"中国有色金属学报(英文版)"},"keywords":[{"id":"b1a4d730-1df8-49f8-b133-2679edbf14f2","keyword":"岩爆","originalKeyword":"岩爆"},{"id":"f408e56a-fc94-44f0-a1bb-7dbe6c0cb2a9","keyword":"预测","originalKeyword":"预测"},{"id":"9dca115a-e778-44cb-afdb-6bc22a07526b","keyword":"<span style=\"color:red\">云</span>模型","originalKeyword":"云模型"},{"id":"f50a9767-9867-4cb7-8c23-bd038e9fe007","keyword":"熵权","originalKeyword":"熵权"},{"id":"59e9e456-de5b-4bba-ad36-4ff8f66bfc3a","keyword":"敏感性","originalKeyword":"敏感性"}],"language":"zh","publisherId":"zgysjsxb-e201607031","title":"熵权-<span style=\"color:red\">云</span>模型对岩爆等级的预测","volume":"26","year":"2016"},{"abstractinfo":"夏甸—<span style=\"color:red\">姜</span>家窑测区位于招平断裂带中段. 招平断裂带在该区段大致沿玲珑花岗岩与胶东群变质岩接触带展布,总体走向42°,倾向SE,倾角37°~52°. 主要金矿体赋存于招平断裂带主裂面下盘黄铁绢英岩化碎裂岩和黄铁绢英岩化花岗岩中. 本次地表构造地球化学测量面积约12 .6 km2 ,采集样品352件,测试元素包括Au、Ag、Cu、Pb、Zn、As、Sb、Hg、Mo、Bi、Mn等19种. Au元素异常与Ag和As元素异常有普遍套合性,与Cu、Pb、Zn、Sb元素异常呈局部套合性. 结合多元统计分析,测定针对深部矿体预测的构造地球化学标志Au-Ag-As,元素组合异常以及斜交参考因子得分Y( i,3)异常和Y( i,7)异常. 在现采矿区深、边部所对应的地表区域圈定出深部隐伏矿体找矿靶位4处.","authors":[{"authorName":"阚靖","id":"02776e6c-2d0c-4c48-9b41-3f220a253ca9","originalAuthorName":"阚靖"},{"authorName":"杨欣鹏","id":"1e620d36-2b91-439c-8108-8d9427ea3a83","originalAuthorName":"杨欣鹏"},{"authorName":"向胤合","id":"271df6c2-7de4-4d5b-9d30-39a2d41bd08c","originalAuthorName":"向胤合"},{"authorName":"杨斌","id":"e652f160-2b33-4865-9ec8-cd5b20be1c70","originalAuthorName":"杨斌"},{"authorName":"梁琴琴","id":"379efe08-608a-4ad3-8de7-d34b22d6060a","originalAuthorName":"梁琴琴"},{"authorName":"陈燕","id":"ecc028b7-a4da-442a-8686-2fa957658c26","originalAuthorName":"陈燕"},{"authorName":"刘庚寅","id":"c88839aa-3014-437a-865d-28f32b2129f0","originalAuthorName":"刘庚寅"}],"doi":"10.11792/hj20150504","fpage":"12","id":"75a62c02-8a0a-4531-8687-f60251820855","issue":"5","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"2f556708-0107-46c4-9134-903d60144569","keyword":"找矿预测","originalKeyword":"找矿预测"},{"id":"ea5d46b4-7b4d-453f-a06d-5d2092637c8b","keyword":"构造地球化学","originalKeyword":"构造地球化学"},{"id":"ee6028e8-5ceb-4284-9a19-0c36b7511af1","keyword":"多元统计分析","originalKeyword":"多元统计分析"},{"id":"99bc456f-c949-4921-8d8b-7ca4d12537e3","keyword":"夏甸—<span style=\"color:red\">姜</span>家窑测区","originalKeyword":"夏甸—姜家窑测区"},{"id":"35ec4729-d34c-4d49-bc6b-967a77e01731","keyword":"招平断裂带","originalKeyword":"招平断裂带"}],"language":"zh","publisherId":"huangj201505004","title":"招平断裂带夏甸—<span style=\"color:red\">姜</span>家窑段构造地球化学找矿预测","volume":"36","year":"2015"},{"abstractinfo":"在对连铸坯质量现状及导致铸坯质量问题因素分析的基础上,将“<span style=\"color:red\">云</span>制造”的概念引入连铸坯质量控制中,提出了将连铸过程中影响铸坯质量的工艺参数、条件进行综合、优化,实现虚拟对现实的映射的方法,并对连铸坯质量控制的<span style=\"color:red\">云</span>制造技术平台体系构建等进行探讨.连铸坯质量控制的<span style=\"color:red\">云</span>制造技术平台是一种新的理念,实现<span style=\"color:red\">云</span>制造对连铸质量进行控制,可以资源共享,降低铸坯质量缺陷率,减少生产成本.","authors":[{"authorName":"郝秀霞","id":"e4f837f2-4207-4b42-beae-eea536861be0","originalAuthorName":"郝秀霞"},{"authorName":"胡大超","id":"f2945666-e08f-4e2d-8d97-4ece1ea438fd","originalAuthorName":"胡大超"}],"doi":"10.13228/j.boyuan.issn1005-4006.20140031","fpage":"40","id":"4925c6f2-4b99-4573-8f56-798531830e1b","issue":"5","journal":{"abbrevTitle":"LZ","coverImgSrc":"journal/img/cover/LZ.jpg","id":"52","issnPpub":"1005-4006","publisherId":"LZ","title":"连铸"},"keywords":[{"id":"833c115d-9858-45b7-b809-43f27bdf269b","keyword":"<span style=\"color:red\">云</span>制造","originalKeyword":"云制造"},{"id":"c2152555-7aeb-4ed0-9f2f-2c2f019e7df0","keyword":"连铸","originalKeyword":"连铸"},{"id":"5bcb412e-7e32-46b9-8a16-60dfb34a32ad","keyword":"铸坯","originalKeyword":"铸坯"},{"id":"ec410040-c2b7-4e3e-b7d7-162d1c2eccbd","keyword":"质量问题","originalKeyword":"质量问题"}],"language":"zh","publisherId":"lz201405010","title":"基于<span style=\"color:red\">云</span>制造技术平台的连铸坯质量控制的研究","volume":"","year":"2014"},{"abstractinfo":"本文研究了一种能测量微细尺度流体温度场的激光<span style=\"color:red\">云</span>纹技术.激光<span style=\"color:red\">云</span>纹法利用莫尔条纹的位移量或者位相变化来计算光线穿过位相物体时产生的偏转角,并由此获得流体的温度梯度和温度场分布.激光<span style=\"color:red\">云</span>纹技术具有灵敏度高,空间分辨率高,稳定性好,实时观测等优点.本文介绍了激光<span style=\"color:red\">云</span>纹法的测量原理、实验技术,并利用该方法测量了加热细丝自然对流的微细尺度温度场分布.","authors":[{"authorName":"张鸿凌","id":"153d98b8-6297-49a9-9f6d-7ea9b1fac3de","originalAuthorName":"张鸿凌"},{"authorName":"宋耀祖","id":"96757aef-c173-42c8-8471-f79df9092f41","originalAuthorName":"宋耀祖"},{"authorName":"张香春","id":"95517c17-35a5-4464-8ed6-217eb5d2a793","originalAuthorName":"张香春"}],"doi":"","fpage":"496","id":"808effb1-fc76-4e17-a824-79d4dd1aab4f","issue":"3","journal":{"abbrevTitle":"GCRWLXB","coverImgSrc":"journal/img/cover/GCRWLXB.jpg","id":"32","issnPpub":"0253-231X","publisherId":"GCRWLXB","title":"工程热物理学报   "},"keywords":[{"id":"8b8344ec-781c-4e7e-a94c-f4e9e79b58b0","keyword":"微尺度传热","originalKeyword":"微尺度传热"},{"id":"5cc1034e-f039-4f66-ac79-9f6875332b58","keyword":"温度测量","originalKeyword":"温度测量"},{"id":"bb190bcd-e4e9-4d81-ad26-e811b4cdec94","keyword":"流场显示","originalKeyword":"流场显示"},{"id":"da83c396-e27b-4af5-96ef-0c9485aa2311","keyword":"激光<span style=\"color:red\">云</span>纹","originalKeyword":"激光云纹"},{"id":"4e26aa59-26b3-445d-9b7f-327888a00544","keyword":"傅立叶变换","originalKeyword":"傅立叶变换"}],"language":"zh","publisherId":"gcrwlxb200303040","title":"测量微细尺度流体温度场的傅立叶变换激光<span style=\"color:red\">云</span>纹技术","volume":"24","year":"2003"}],"totalpage":18,"totalrecord":176}