{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"为了找出国产和进口LX80B盘条之间的差异,通过OM、SEM、EPMA以及拉伸试验对不同钢厂生产的LX80B盘条进行了内在质量和力学性能分析.试验结果表明:国产盘条B类、D类夹杂物数量是进口盘条的5倍;由于国产盘条均存在较严重的碳偏析,导致捻制发生分层断裂;盘条表面氧化铁皮均主要由Fe1-yO和Fe3 O4组成,但进口盘条氧化铁皮厚度大于国产盘条;盘条微观组织均以珠光体类组织为主,国产盘条中存在长条状或块状先共析Fe.C;由于珠光体片层间距波动较大,导致国产盘条力学性能波动增大.","authors":[{"authorName":"钱庆生","id":"dcbb9f1f-7237-4902-8d7f-028d2921f599","originalAuthorName":"钱庆生"},{"authorName":"王秀丽","id":"9a39099c-49cc-49d1-9dfb-34bc328b0b01","originalAuthorName":"王秀丽"},{"authorName":"丁文旭","id":"14329a0a-0545-4f41-a6c7-53070c1768e3","originalAuthorName":"丁文旭"},{"authorName":"倪建胜","id":"3b692f6d-0be6-4a0e-8966-ec9678686c82","originalAuthorName":"倪建胜"}],"doi":"10.13228/j.boyuan.issn1001-0963.20130457","fpage":"66","id":"c2616d69-93b2-4d53-a29a-84951de36f11","issue":"10","journal":{"abbrevTitle":"GTYJXB","coverImgSrc":"journal/img/cover/GTYJXB.jpg","id":"30","issnPpub":"1001-0963","publisherId":"GTYJXB","title":"钢铁研究学报"},"keywords":[{"id":"1d333af8-11f2-40f1-b536-cd26e6ddc907","keyword":"帘线钢","originalKeyword":"帘线钢"},{"id":"6f6ba5e8-08f6-4694-996b-22df2da8e78d","keyword":"内在质量","originalKeyword":"内在质量"},{"id":"f206039e-7c03-4a1d-ad75-08cf9170fb71","keyword":"力学性能","originalKeyword":"力学性能"}],"language":"zh","publisherId":"gtyjxb201410012","title":"钢帘线用LX80B盘条的内在质量和力学性能","volume":"26","year":"2014"},{"abstractinfo":"为了提高锡磷青铜带坯的质量,提出了在锡磷青铜带坯的水平连铸过程中施加交流电磁场的水平电磁连铸技术.使用电子探针和光学显微镜研究了在水平连铸过程中施加交流电磁场对锡磷青铜带坯组织的影响.结果表明:在水平连铸过程中施加18A的工频交流电磁场,可以使锡磷青铜带坯的晶粒组织得到明显细化、缩松和偏析得到明显减轻、锡磷青铜带坯的内在质量得到大幅改善,从而使带坯的均匀化退火时间从7 h缩短到5 h、石墨模具使用寿命从168h延长到336 h.","authors":[{"authorName":"回春华","id":"6e74c08d-b657-4796-ba17-92252d3b8fdb","originalAuthorName":"回春华"},{"authorName":"李廷举","id":"bfc0cbfb-97b1-46e0-803b-1c887974ead5","originalAuthorName":"李廷举"},{"authorName":"金文中","id":"aad38047-7ef2-42d5-9768-aad101d0d948","originalAuthorName":"金文中"},{"authorName":"郭进","id":"45d4e31f-b7fb-46a0-8532-61cc2510ffb8","originalAuthorName":"郭进"}],"doi":"","fpage":"721","id":"ffbfd637-5b25-4d72-b80f-563921f5de5e","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":"15d9418c-da39-4252-8096-a5d7d1882b6f","keyword":"锡磷青铜带坯","originalKeyword":"锡磷青铜带坯"},{"id":"b97f1f00-452d-45a8-a3fe-5959655c4b22","keyword":"水平电磁连铸","originalKeyword":"水平电磁连铸"},{"id":"da6d34e8-7540-4abe-bbba-d89ee9b2b732","keyword":"交流电磁场","originalKeyword":"交流电磁场"},{"id":"c149c9c5-2fb4-4443-b67b-e13c85beb0f3","keyword":"内在质量","originalKeyword":"内在质量"}],"language":"zh","publisherId":"xyjsclygc200804037","title":"锡磷青铜带坯的水平电磁连铸技术研究","volume":"37","year":"2008"},{"abstractinfo":"为了研究捣固焦炭对大高炉的适应性,在1050~1200℃使用焦炭连续热反应装置对A类顶装焦、B类捣固焦、C类捣固焦3类焦炭进行等温等反应的溶损反应.当焦炭的失重率分别达到30%,35%,40%时,停止反应,通过Ⅰ型转鼓检测焦炭的反应后强度.结果表明:捣固处理在一定程度上可以改善焦炭的热态性质;在1100~1 150℃时焦炭强度破坏程度最严重;等反应后强度与国家标准CSR存在差异性.","authors":[{"authorName":"姚怀伟","id":"793b3918-51ed-49dc-9a6c-3639895f4ae6","originalAuthorName":"姚怀伟"},{"authorName":"郑明东","id":"30e97a9b-ac46-4973-b194-bd669f8a7f0b","originalAuthorName":"郑明东"},{"authorName":"张小勇","id":"b6716f89-8946-4e99-9337-ecb1dcb1ea9b","originalAuthorName":"张小勇"},{"authorName":"吴光友","id":"9ea0e84c-ad8c-4b44-af11-69b24517a0d9","originalAuthorName":"吴光友"},{"authorName":"张献杰","id":"63f26bc8-edba-4f89-9cf0-d4a3b66bc5af","originalAuthorName":"张献杰"}],"doi":"","fpage":"16","id":"a0de2e6c-2cd0-4444-a1b8-f662c1f32439","issue":"12","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"8cc537c7-070b-4268-8cb8-5448f0b4a6e4","keyword":"焦炭","originalKeyword":"焦炭"},{"id":"ad53bc85-233e-459e-bbce-878f77678d30","keyword":"等反应","originalKeyword":"等反应"},{"id":"2c3aca18-cefe-464a-93c4-43550552f9f9","keyword":"反应后强度","originalKeyword":"反应后强度"}],"language":"zh","publisherId":"gt201312003","title":"捣固焦炭内在质量及等反应后强度指标","volume":"48","year":"2013"},{"abstractinfo":"本文以含内在矿物煤粉为研究对象,在滴管炉上制焦后进行热重试验,用几种常用动力学模型进行数据处理.结果发现,用经典模型处理含内在矿物煤焦的热重数据线性不好,收缩核模型和随机核化模型也不能成立;用随机孔模型处理这些热重数据只在反应初期吻合较好,中后期偏差较大;而不同氧气浓度下所有煤焦的结构因子曲线都吻合得很好,这说明不假定任何模型的结构因子法能较好地反映含内在矿物煤焦燃烧动力学过程.","authors":[{"authorName":"张洪","id":"3a6715ff-8733-4aad-92a7-208aabde23da","originalAuthorName":"张洪"},{"authorName":"李欢","id":"fd474a38-79a5-48cb-9b43-f3d1306f994e","originalAuthorName":"李欢"},{"authorName":"施海艳","id":"1f1e5fac-18c1-4240-9c71-d88424ca1bc2","originalAuthorName":"施海艳"},{"authorName":"姬莉","id":"a1a42e93-237e-4977-b9d2-93d19fe2b60f","originalAuthorName":"姬莉"},{"authorName":"李迎","id":"c7d69bdf-b46c-423f-86a2-40fba7fcb929","originalAuthorName":"李迎"}],"doi":"","fpage":"1435","id":"771cc24d-1fd5-4c58-8737-f297cf7642fc","issue":"8","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":"0c968b1b-aae6-4099-818f-4dd6bce2e64a","keyword":"矿物质","originalKeyword":"矿物质"},{"id":"ed26c070-cf10-4a74-9009-d9cbd4122851","keyword":"动力学","originalKeyword":"动力学"},{"id":"f5ed9a88-b502-49ac-bb5f-9b07fac27cd7","keyword":"模型","originalKeyword":"模型"},{"id":"9ebf381a-e87c-4c8b-9965-0e4555218659","keyword":"煤焦","originalKeyword":"煤焦"}],"language":"zh","publisherId":"gcrwlxb201008044","title":"含内在矿物煤焦燃烧反应动力学模型研究","volume":"31","year":"2010"},{"abstractinfo":"采用热重和傅里叶红外光谱联用(TG-FTIR)对去离子水、盐酸淋洗后的稻草样品和原样进行分析,探讨生物质内在金属盐对热解过程和产气组分的催化作用规律.结果表明:碱金属对稻草样品热解具有重要的催化作用,相反Ca等碱土金属抑制了纤维素的分解.红外检测的三种样品热解气体产物主要为CO2、CO、CH4、H2O和一些含C-O-C和C=O半挥发性有机物.经过水洗后CO2、CO产量减少,CH4和半挥发性有机物产量增加;而酸洗样品气体产量都明显低于其它两种样品.这些与稻草内在碱金属和碱土金属盐的不同催化作用有关.","authors":[{"authorName":"何立模","id":"bd484313-d6e4-4291-8ade-2ca7c19e5c9f","originalAuthorName":"何立模"},{"authorName":"胡松","id":"883b1ac0-5ad4-4ad1-9f2f-7f4981c94a34","originalAuthorName":"胡松"},{"authorName":"孙路石","id":"1ce0d239-e46a-4e75-8f2e-8d888b4a74c2","originalAuthorName":"孙路石"},{"authorName":"苏胜","id":"f6b33a86-aff6-43a1-a0de-b2edff9bbeb4","originalAuthorName":"苏胜"},{"authorName":"江龙","id":"e520da0e-9621-4132-b0d8-0cb396f983bd","originalAuthorName":"江龙"},{"authorName":"宋尧","id":"7791903f-fee8-4141-9ef1-faf86f7cd3ef","originalAuthorName":"宋尧"},{"authorName":"帅超","id":"6d674c78-2809-4d8e-b5c7-8524ed04b807","originalAuthorName":"帅超"},{"authorName":"向军","id":"dd430e38-b6e3-4f37-b0b6-a0702d271358","originalAuthorName":"向军"}],"doi":"","fpage":"2093","id":"e520a4e6-3e27-42e5-b73b-ba34513a85b5","issue":"10","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":"d30e3091-a12f-4ab6-8110-fc525895de2e","keyword":"稻草","originalKeyword":"稻草"},{"id":"16e6e773-9197-4aad-b8c0-d963f2ec19c5","keyword":"热解","originalKeyword":"热解"},{"id":"acf63e94-5922-4672-95c9-cc3325eb2c60","keyword":"热重博里叶红外光谱联用","originalKeyword":"热重博里叶红外光谱联用"},{"id":"da0d54a1-7879-491d-a06d-6ec0ea1a973e","keyword":"内在金属盐","originalKeyword":"内在金属盐"}],"language":"zh","publisherId":"gcrwlxb201410044","title":"基于TG-FTIR的生物质内在金属盐催化热解研究","volume":"35","year":"2014"},{"abstractinfo":"为深入研究煤燃烧与煤气化过程中煤中矿物的熔融变化行为对煤灰物理相变变化过程的内在影响规律,本文采用高温热显微镜、SEM—EDX等分析测试手段,实验研究了不同条件(煤燃烧与煤气化)下煤中矿物演变规律与煤灰物理相变变化行为间的内在联系和影响规律。研究结果表明:高铁含量的煤灰A在气化条件下发生初始熔融温度(Tin)及快速熔融温度(Tmax)要比其在燃烧条件下对应的温度分别低144℃和113℃,而低铁含量的煤灰B则对应气化条件下的丑。和Tmax分别比燃烧条件下的对应温度低25℃和62℃;不同气氛下灰中Fe的不同价态是导致这种差别的主要原因,高温下煤灰相变发生、发展过程中,灰中方铁石、铁铝榴石以及铁橄榄石等铁系矿物是引发煤灰发生初始熔融的主要矿物。","authors":[{"authorName":"乌晓江","id":"de5e14c8-21f7-4c77-a0db-1abcdb361b7a","originalAuthorName":"乌晓江"},{"authorName":"张忠孝","id":"d9dea848-8bdb-4455-ac5e-6619b043857e","originalAuthorName":"张忠孝"},{"authorName":"徐雪元","id":"c15a7112-2964-4567-86e0-60a312f11a67","originalAuthorName":"徐雪元"},{"authorName":"张建文","id":"de622cfd-496c-4395-9d6a-4ec139b11034","originalAuthorName":"张建文"},{"authorName":"刘建斌","id":"446dfbe0-977a-47f2-97bc-b1781f8b0ce8","originalAuthorName":"刘建斌"},{"authorName":"柳公权","id":"1bbbb2b7-f777-4962-99e2-b1d9f309b95a","originalAuthorName":"柳公权"},{"authorName":"周托","id":"351df4de-9f4b-4828-b569-2169fdbf37fe","originalAuthorName":"周托"},{"authorName":"陈玉爽","id":"61798172-7674-4caa-91d9-92b770ff424b","originalAuthorName":"陈玉爽"}],"doi":"","fpage":"1425","id":"97c2cfde-3af3-4866-9ba1-fb020bb66da6","issue":"8","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":"afdd6c66-f112-4f14-a388-b14a0db1ff60","keyword":"煤燃烧","originalKeyword":"煤燃烧"},{"id":"15e78cdf-11e2-4f9b-be8b-65492cc9ccd8","keyword":"煤气化","originalKeyword":"煤气化"},{"id":"ddf00d2c-4ec8-418b-9a15-7da3ea732bf5","keyword":"烧结","originalKeyword":"烧结"},{"id":"7123f006-663a-4df6-93b0-5c41c2ce80ab","keyword":"矿物质","originalKeyword":"矿物质"}],"language":"zh","publisherId":"gcrwlxb201108044","title":"铁系矿物对煤灰相变过程的内在影响规律研究","volume":"32","year":"2011"},{"abstractinfo":"基于铍(Be)冲击制粉颗粒的形貌特征,建立了一个描述Be粉颗粒尺寸分布的物理模型,该模型仅含一个物理意义明确的参数.模型中考虑了2种重要的内在影响机制:具有不同初始动能的颗粒在完成冲击后的存在状态应该遵从Maxwell-Boltzmann分布,即大颗粒具有高的能量,状态不稳定,在冲击过程中容易碎成小颗粒,这一影响可以用颗粒尺寸的负指数函数来描述;获得低表面能的倾向又使得颗粒尽可能具有大的体积,这一影响可以用颗粒尺寸的立方函数来描述.实际的颗粒尺寸分布是这2种影响竞争的结果.计算结果与实验数据符合得很好.","authors":[{"authorName":"何力军","id":"e9f34062-8544-4578-94a1-f415f5e9cbdb","originalAuthorName":"何力军"},{"authorName":"许德美","id":"81e903a9-7507-4631-ac36-d7fd782ede18","originalAuthorName":"许德美"},{"authorName":"胡楠","id":"6f800815-b65f-4b3d-9b14-6f2e924d504e","originalAuthorName":"胡楠"},{"authorName":"李婷婷","id":"f4782280-6d23-406b-a38e-9f0e5e3bbc5b","originalAuthorName":"李婷婷"},{"authorName":"钟景明","id":"37e5e7aa-84c7-482c-938c-d175d2ca6676","originalAuthorName":"钟景明"},{"authorName":"罗民","id":"15a705cc-e4c4-4e32-ae89-4a66446e4f39","originalAuthorName":"罗民"}],"doi":"","fpage":"567","id":"7fb7cc20-d0b8-4b7d-bef1-3980b92c2775","issue":"3","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":"499d12d5-ff1e-49e3-8e4c-fd417998f1d7","keyword":"Be粉","originalKeyword":"Be粉"},{"id":"4c36a3f9-c31d-4878-8402-9fc56f7d545e","keyword":"冲击研磨","originalKeyword":"冲击研磨"},{"id":"b2592015-924f-4b81-95af-aa7a7e4a4ab9","keyword":"颗粒尺寸分布","originalKeyword":"颗粒尺寸分布"},{"id":"39d63842-bc37-4968-b2cb-d88b888280da","keyword":"物理模型","originalKeyword":"物理模型"}],"language":"zh","publisherId":"xyjsclygc201403012","title":"铍冲击粉颗粒尺寸分布特征建模的内在机制分析","volume":"43","year":"2014"},{"abstractinfo":"使用Gleeble 3800热模拟试验机模拟 F460钢单道次焊接条件下焊接粗晶热影响区的热循环过程,通过光镜(OM )、扫描电镜(SEM )分析热影响区的显微组织、确定临界事件,通过ABAQUS软件计算临界解理断裂应力σf ,进而系统分析不同焊接热输入 E下韧脆转变温度变化的内在机理。结果表明:随着 E的提高,焊接粗晶热影响区显微组织依次为少量板条马氏体和大量细密的板条贝氏体,板条贝氏体较多的板条/粒状贝氏体,粒状贝氏体较多的板条/粒状贝氏体,粗大的粒状贝氏体。原始奥氏体晶粒、贝氏体团的最大尺寸随着 E的提高而变大。在完全解理断裂的冲击断口上,寻找停留在缺口尖端附近的残留裂纹,通过对比残留裂纹长度、原始奥氏体晶粒大小、贝氏体团尺寸,发现不同 E下解理断裂的临界事件尺寸都是贝氏体团大小,而临界事件尺寸越小,韧脆转变温度越低。此外,通过有限元模拟缺口尖端的应力分布得到σf ,σf 越大冲击韧度越好,随着 E的提高σf 降低,故进一步说明随着 E的提高韧脆转变温度 Tk 上升的内在机理。","authors":[{"authorName":"李静","id":"eb53c083-bb67-47ad-a99c-b178f0e71907","originalAuthorName":"李静"},{"authorName":"曹睿","id":"e5f003ca-6321-4911-b05b-223042d500ed","originalAuthorName":"曹睿"},{"authorName":"毛高军","id":"f82f5b41-25cf-426a-b216-13a7e20cfc95","originalAuthorName":"毛高军"},{"authorName":"刘东升","id":"003ac327-cabf-4828-bfc5-916fc6ad193e","originalAuthorName":"刘东升"},{"authorName":"陈剑虹","id":"c9633616-729a-4275-ae78-61381d708b2b","originalAuthorName":"陈剑虹"}],"doi":"10.11868/j.issn.1001-4381.2016.08.012","fpage":"70","id":"20f55fa2-f8e4-4eeb-b768-ed4d8ec490e8","issue":"8","journal":{"abbrevTitle":"CLGC","coverImgSrc":"journal/img/cover/CLGC.jpg","id":"9","issnPpub":"1001-4381","publisherId":"CLGC","title":"材料工程"},"keywords":[{"id":"04c66b53-0b7b-4536-97eb-389db3095bac","keyword":"F460钢","originalKeyword":"F460钢"},{"id":"cc68e34d-3ac3-44d2-90b7-aaded9630306","keyword":"焊接粗晶热影响区","originalKeyword":"焊接粗晶热影响区"},{"id":"6dbe4dd3-023e-421c-8115-651f4be1571c","keyword":"韧脆转变","originalKeyword":"韧脆转变"},{"id":"7b77baa2-c30b-4890-82c1-b471dc27af1e","keyword":"临界事件","originalKeyword":"临界事件"},{"id":"2a1ae14c-68f9-42e7-81c0-b0b168840d81","keyword":"解理断裂应力","originalKeyword":"解理断裂应力"}],"language":"zh","publisherId":"clgc201608013","title":"不同热输入下 F460钢焊接粗晶热影响区韧脆转变的内在机理","volume":"44","year":"2016"},{"abstractinfo":"采用机械抛光方法研制ER5356铝合金焊丝,从原材料化学成分、焊丝直径和圆度、焊丝强度和塑性、表面质量、翘距、松弛直径等方面研究了其对铝合金MIG焊丝质量的影响.结果表明,原材料的化学成分及内在品质是影响铝合金焊丝质量的关键因素.","authors":[{"authorName":"明珠","id":"15848d97-8768-4daa-a976-6d08a0cc5549","originalAuthorName":"明珠"},{"authorName":"王有祁","id":"06fcc8ec-d51b-49b7-a426-0a92ae7c3a05","originalAuthorName":"王有祁"},{"authorName":"甄立玲","id":"29a31d6d-60cb-4d57-91ce-a5b6d2a955e2","originalAuthorName":"甄立玲"},{"authorName":"齐果","id":"454c46be-46a1-4f69-9818-31f39dc30fae","originalAuthorName":"齐果"},{"authorName":"刘宏伟","id":"4845caa6-8890-42b5-afec-50b811f81089","originalAuthorName":"刘宏伟"},{"authorName":"陈东高","id":"013e05d0-76d7-4d08-9dcc-723456a73bb3","originalAuthorName":"陈东高"},{"authorName":"谭兵","id":"59a1f475-57f9-4e69-abf0-6e688ad6cbe9","originalAuthorName":"谭兵"},{"authorName":"陈巍","id":"3b33735f-17e0-4bf0-b418-31856ab1d167","originalAuthorName":"陈巍"}],"doi":"10.3969/j.issn.1004-244X.2010.05.024","fpage":"88","id":"07a91700-7ffd-4fe7-9ee9-b4e1856cfc4e","issue":"5","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":"ebc42f9e-c105-4c42-8a98-1cacd33b5440","keyword":"铝合金","originalKeyword":"铝合金"},{"id":"283086c6-c46d-44d4-b351-09a8ff57b1f0","keyword":"焊丝","originalKeyword":"焊丝"},{"id":"c03fda93-c267-4ff3-98de-c1a586a8b26e","keyword":"机械抛光","originalKeyword":"机械抛光"},{"id":"efc63323-f5ce-47ed-91d4-7214d2a5f5b7","keyword":"焊丝质量","originalKeyword":"焊丝质量"}],"language":"zh","publisherId":"bqclkxygc201005024","title":"影响铝合金MIG焊丝质量的因素分析","volume":"33","year":"2010"},{"abstractinfo":"综述了色谱技术作为现代高效分离分析技术在中药药效物质基础研究和中药质量控制中的重要作用.提出中药药效物质组学研究策略,以实现中药药效物质基础与作用机理研究的一体化,进而从深层次揭示和全面控制中药的内在质量.论述结果表明,现代色谱及其联用技术是中药质量研究的重要技术平台之一.","authors":[{"authorName":"李发美","id":"34092132-93bf-4bba-b937-0244a547d6af","originalAuthorName":"李发美"},{"authorName":"熊志立","id":"ca3a87d6-4147-4da8-a80c-9bcd9129614d","originalAuthorName":"熊志立"},{"authorName":"鹿秀梅","id":"8ad4b72d-e37a-4b8f-b6f0-78de38e2f726","originalAuthorName":"鹿秀梅"},{"authorName":"秦峰","id":"5063ec47-6af6-40ad-8bc7-acd8abb0ccf2","originalAuthorName":"秦峰"},{"authorName":"李小芩","id":"680a53ff-8409-4eb2-8edb-31dd0ecf1b2f","originalAuthorName":"李小芩"}],"doi":"10.3321/j.issn:1000-8713.2006.06.001","fpage":"537","id":"52901944-263a-4a87-9bba-bc1e857f40f2","issue":"6","journal":{"abbrevTitle":"SP","coverImgSrc":"journal/img/cover/SP.jpg","id":"58","issnPpub":"1000-8713","publisherId":"SP","title":"色谱 "},"keywords":[{"id":"7b37deb0-986a-4b9b-8481-27d21f59c038","keyword":"中药","originalKeyword":"中药"},{"id":"7b4e0bdc-5ed9-4755-a275-b2f0d8d926f0","keyword":"质量控制","originalKeyword":"质量控制"},{"id":"86f1abdc-4ddb-4dd9-897d-84cddff7c3cb","keyword":"色谱技术","originalKeyword":"色谱技术"},{"id":"9bfa7b36-f945-4275-af05-61e0eeaa934e","keyword":"中药药效物质组学","originalKeyword":"中药药效物质组学"},{"id":"0c29bb2d-29df-409b-a5fb-fbe53c089d12","keyword":"综述","originalKeyword":"综述"}],"language":"zh","publisherId":"sp200606001","title":"中药质量控制的研究策略和色谱技术","volume":"24","year":"2006"}],"totalpage":2350,"totalrecord":23497}