{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"以含二氮杂萘酮结构的新型聚芳醚砜酮(PPESK)为底膜材料,以硅橡胶为涂层材料,制备了中空纤维气体分离复合膜.重点考察了N-甲基吡咯烷酮(NMP)/乙醇(EtOH)θ<span style=\"color:red\">组成</span>对气体分离膜性能的影响.结果表明,NMP/EtOHθ<span style=\"color:red\">组成</span>对膜性能有较明显的影响,采用略低于NMP/EtOHθ<span style=\"color:red\">组成</span>的铸膜液制备的膜分离性能较好.","authors":[{"authorName":"王志鹏","id":"55ee27ec-d6b5-4bfb-b681-ee2496bf84d9","originalAuthorName":"王志鹏"},{"authorName":"杨大令","id":"cae83cb0-b6da-4361-8d42-6ba2df1c91ff","originalAuthorName":"杨大令"},{"authorName":"张守海","id":"1e8ca542-df1d-430a-9345-42d8cbfbeebc","originalAuthorName":"张守海"},{"authorName":"富海涛","id":"6e79d03b-ad16-42a3-935d-c63ac92af1a1","originalAuthorName":"富海涛"},{"authorName":"蹇锡高","id":"88a74f18-44f1-458b-952b-da73b4352336","originalAuthorName":"蹇锡高"}],"doi":"10.3969/j.issn.1007-8924.2008.02.002","fpage":"9","id":"d9987c41-5d43-478a-8acc-e201cc551ec5","issue":"2","journal":{"abbrevTitle":"MKXYJS","coverImgSrc":"journal/img/cover/MKXYJS.jpg","id":"54","issnPpub":"1007-8924","publisherId":"MKXYJS","title":"膜科学与技术   "},"keywords":[{"id":"99950fa5-b556-4f4e-8a86-3bca6cafa536","keyword":"聚芳醚砜酮","originalKeyword":"聚芳醚砜酮"},{"id":"4d1d0452-bba3-4e29-b5d3-60b812359cfc","keyword":"θ<span style=\"color:red\">组成</span>","originalKeyword":"θ组成"},{"id":"4758c7aa-ab11-412a-bfaa-fdbdc58e7508","keyword":"气体分离","originalKeyword":"气体分离"},{"id":"d0c7abc4-d0ca-49e1-b2ec-a5b14f0106fa","keyword":"复合膜","originalKeyword":"复合膜"}],"language":"zh","publisherId":"mkxyjs200802002","title":"NMP/EtOH θ<span style=\"color:red\">组成</span>对PPESK气体分离膜性能的影响","volume":"28","year":"2008"},{"abstractinfo":"共聚合在理论研究和在生产实践中都具有重要的意义,共聚物<span style=\"color:red\">组成</span>及其控制是最重要的内容,其中有一些难点需要深入解析.文中在推导中引入竞聚率,得到共聚物<span style=\"color:red\">组成</span>的(物质的)量比微分方程、(物质的)量分率微分方程及质量分率微分方程;解释共聚的类型及意义;介绍计算关键点(f1,F1)绘制共聚物<span style=\"color:red\">组成</span>曲线简图的方法;由共聚物<span style=\"color:red\">组成</span>的积分方程绘图来解释共聚物<span style=\"color:red\">组成</span>的控制方法及原理.","authors":[{"authorName":"赵殊","id":"913824e7-48b6-4606-9dc0-4373199caccf","originalAuthorName":"赵殊"}],"doi":"","fpage":"164","id":"677a9a60-7ddc-4284-978e-f33e2f8fe09b","issue":"11","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"bde70817-c894-4342-b399-3877343dcad4","keyword":"共聚物<span style=\"color:red\">组成</span>","originalKeyword":"共聚物组成"},{"id":"2e96a27e-ee2e-4cc8-b5fe-3b8fbb795d5c","keyword":"竞聚率","originalKeyword":"竞聚率"},{"id":"d3ad5d7c-a986-4f1b-86b0-92102b485726","keyword":"量比","originalKeyword":"量比"},{"id":"973861f0-f2b0-4b7a-ae77-00be4b179ed6","keyword":"量分率","originalKeyword":"量分率"},{"id":"43cbb1d8-a55f-4bfc-9066-496a77cd8e91","keyword":"质量分率","originalKeyword":"质量分率"},{"id":"ef42c23a-7f9b-42f0-a47f-78a4b8c9360f","keyword":"微分方程","originalKeyword":"微分方程"},{"id":"58fb83cf-a589-4b95-b9b5-769cbdc90255","keyword":"积分方程","originalKeyword":"积分方程"},{"id":"afd221c7-07f0-4a65-8736-b775287f1219","keyword":"<span style=\"color:red\">组成</span>曲线","originalKeyword":"组成曲线"},{"id":"98f8d6a5-7e46-4221-bb70-0ff32a405300","keyword":"<span style=\"color:red\">组成</span>控制","originalKeyword":"组成控制"}],"language":"zh","publisherId":"gfzclkxygc201311038","title":"共聚物<span style=\"color:red\">组成</span>及其控制","volume":"29","year":"2013"},{"abstractinfo":"简要介绍了涂料用溶剂的<span style=\"color:red\">组成</span>及作用.涂料用溶剂多为混合溶剂,由真溶剂、助剂和稀释剂<span style=\"color:red\">组成</span>.阐述了其选用原则,并通过分析不同性能的溶剂对漆膜性能的影响,提出了涂料用溶剂的配方原则.","authors":[{"authorName":"周润根","id":"63b8dad7-e69d-4226-a4a7-7d818ab87337","originalAuthorName":"周润根"}],"doi":"10.3969/j.issn.1004-227X.1999.01.010","fpage":"33","id":"4706ac03-8dcd-434e-a7ad-39a8edd51614","issue":"1","journal":{"abbrevTitle":"DDYTS","coverImgSrc":"journal/img/cover/DDYTS.jpg","id":"21","issnPpub":"1004-227X","publisherId":"DDYTS","title":"电镀与涂饰   "},"keywords":[{"id":"fb78eb3b-712d-427b-a624-33adc477d48b","keyword":"溶剂","originalKeyword":"溶剂"},{"id":"4cb77509-a9ff-4606-bf23-8acb450d3517","keyword":"涂料","originalKeyword":"涂料"},{"id":"f1ded458-e18d-44bb-9c9b-d486e5e448f3","keyword":"<span style=\"color:red\">组成</span>","originalKeyword":"组成"},{"id":"d79aa624-628b-49be-a199-8e1f28438800","keyword":"性能","originalKeyword":"性能"}],"language":"zh","publisherId":"ddyts199901010","title":"涂料用溶剂的<span style=\"color:red\">组成</span>与性能","volume":"18","year":"1999"},{"abstractinfo":"电子墨水是一种新型的柔性显示材料,是由具有化学相容性的多相材料<span style=\"color:red\">组成</span>的.本文在介绍电子墨水显示原理的基础上,着重介绍了各<span style=\"color:red\">组成</span>部分,即电泳颗粒、分散介质、染料、电荷控制剂和稳定剂的作用及材料的选择,论述了电子墨水微胶囊的制备方法及存在的问题,并评述了电子墨水的研究进展.","authors":[{"authorName":"郭慧林","id":"7563cf2d-7e02-406e-8e8e-15f1cce61098","originalAuthorName":"郭慧林"},{"authorName":"王允韬","id":"08feb020-990c-43df-85e4-c3257fc6b0d6","originalAuthorName":"王允韬"},{"authorName":"刘曙","id":"05220822-641a-4c19-af8e-db12e8ced130","originalAuthorName":"刘曙"},{"authorName":"赵乾","id":"be051cbf-0df9-42bc-b7bb-f07c4f947cff","originalAuthorName":"赵乾"},{"authorName":"赵晓鹏","id":"a4c7a730-621b-45be-8a6d-85e95a2b477f","originalAuthorName":"赵晓鹏"}],"doi":"","fpage":"386","id":"54a14f71-db18-4e32-9af5-05a7f40f0e90","issue":"4","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"932e9847-23df-4c5c-b088-da6d6454c882","keyword":"电子墨水","originalKeyword":"电子墨水"},{"id":"4191c782-2e7a-42bf-a260-19fd81df7226","keyword":"微胶囊","originalKeyword":"微胶囊"},{"id":"d138ea29-5ad9-410c-be83-a8a3691fdea3","keyword":"电泳显示","originalKeyword":"电泳显示"}],"language":"zh","publisherId":"gncl200304010","title":"电子墨水的<span style=\"color:red\">组成</span>及制备方法","volume":"34","year":"2003"},{"abstractinfo":"本文采用X射线荧光光谱仪(XRF)、X射线衍射仪(XRD)、激光粒度仪、综合热分析仪(DTA/TG)、场发射扫描电镜(FE-SEM)以及透射电镜(TEM)等测试手段对福建龙岩高岭土进行了<span style=\"color:red\">组成</span>及结构的研究.结果表明:龙岩高岭土的矿物<span style=\"color:red\">组成</span>主要由高岭石、多水高岭石和伊利石<span style=\"color:red\">组成</span>.一定量伊利石的存在是龙岩高岭土的化学<span style=\"color:red\">组成</span>中含有较高K2O组分的直接原因,这导致其耐火度不高.龙岩高岭土的显微结构为片状和管状混合结构,多水高岭石呈管状,结晶程度最差;高岭石呈不规则薄片状,结晶程度较差;伊利石呈板片状,晶化程度最好.","authors":[{"authorName":"包镇红","id":"b5ca8f79-6bde-4010-b536-2d6a9b8e6f1d","originalAuthorName":"包镇红"},{"authorName":"苗立锋","id":"5edf2ff8-65c8-4b77-ab7f-67e3444b2953","originalAuthorName":"苗立锋"},{"authorName":"江伟辉","id":"c238ade0-6b0f-4870-a693-bd7454163942","originalAuthorName":"江伟辉"}],"doi":"","fpage":"1130","id":"ccadc493-2bab-4408-a2ca-c3539658ffe9","issue":"5","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"10bd9c31-8725-4f7d-b6be-720687fb8d08","keyword":"高岭土","originalKeyword":"高岭土"},{"id":"1678ed4a-28e4-4ed5-adf2-4d291b3fa279","keyword":"矿物<span style=\"color:red\">组成</span>","originalKeyword":"矿物组成"},{"id":"ac8eeab7-95a6-4012-ac2d-52df295e54b2","keyword":"显微结构","originalKeyword":"显微结构"},{"id":"bf8a2ea0-de4c-4158-9c66-4dc01830c515","keyword":"伊利石","originalKeyword":"伊利石"}],"language":"zh","publisherId":"gsytb201405026","title":"龙岩高岭土的<span style=\"color:red\">组成</span>与结构研究","volume":"33","year":"2014"},{"abstractinfo":"超高性能混凝土作为一种性能优异的水泥基材料,已经得到广泛的关注.本文就UHPC常用原材料<span style=\"color:red\">组成</span>对其流动性及强度发展的影响进行了研究.结果表明水胶比对UHPC性能的影响最大,且随着水胶比增大,UHPC新拌物流动性增加,强度逐渐减小；在标养情况下,硅灰掺量对其强度影响最小；其他材料<span style=\"color:red\">组成</span>对UHPC的影响表现为石英粉掺量40％、砂灰比1.0及减水剂掺量2.5％时,试件强度最高.","authors":[{"authorName":"史才军","id":"ed60e3ee-ec20-4716-8815-2191b300c717","originalAuthorName":"史才军"},{"authorName":"肖江帆","id":"c835dbfb-51ba-47bb-b036-224728eb8574","originalAuthorName":"肖江帆"},{"authorName":"曹张","id":"da32b6fc-997a-43c3-9887-a71e3a464b6d","originalAuthorName":"曹张"},{"authorName":"王德辉","id":"606e62b9-8e42-4776-9d62-25ccfd4441b1","originalAuthorName":"王德辉"},{"authorName":"吴泽媚","id":"8a9c67cd-e007-425a-abd1-caa65ba3a1cc","originalAuthorName":"吴泽媚"},{"authorName":"欧志华","id":"d708d9da-f324-4095-a2e2-edd6096211c9","originalAuthorName":"欧志华"}],"doi":"","fpage":"1005","id":"a106037e-f576-4275-af6a-462678389480","issue":"6","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"5c513a86-53bd-4ef7-a660-13a95ac7eba8","keyword":"超高性能混凝土","originalKeyword":"超高性能混凝土"},{"id":"35e29db1-21a8-4f69-bf6e-783bf6a3fe63","keyword":"材料<span style=\"color:red\">组成</span>","originalKeyword":"材料组成"},{"id":"87cd4e74-911a-4ef4-82c2-d57e76f6ec33","keyword":"流动性","originalKeyword":"流动性"},{"id":"8b5162b3-1f65-4a22-b83e-6839094ffa3a","keyword":"强度","originalKeyword":"强度"}],"language":"zh","publisherId":"gsytb201306002","title":"材料<span style=\"color:red\">组成</span>对UHPC性能的影响","volume":"32","year":"2013"},{"abstractinfo":"用ATR-FT-IR和XPS研究了聚氨酯脲以及聚二甲基硅氧烷(PDMS)改性聚氨酯脲的表面<span style=\"color:red\">组成</span>和结构,发现与空气接触面和与模板接触面含有的PDMS和聚四亚甲基醚(PTMO)软段浓度远远大于其本体浓度,并且与空气接触面比与模板接触面含有更多的PDMS和PTMO段.将聚氨酯脲水合至3个星期,其表面<span style=\"color:red\">组成</span>和氢键未发生任何变化.","authors":[{"authorName":"武利民","id":"742c03be-36a2-4e5e-a119-d0f73de613c9","originalAuthorName":"武利民"},{"authorName":"李丹","id":"d034eff9-3241-4f25-b9be-3b9974869832","originalAuthorName":"李丹"},{"authorName":"游波","id":"a17671c3-ea0c-4db1-89da-262f57d314c9","originalAuthorName":"游波"},{"authorName":"钱峰","id":"175fe09b-5c60-4b7d-bb8a-9833cd5a2f85","originalAuthorName":"钱峰"}],"doi":"","fpage":"118","id":"ac7f99ef-2410-45dd-b47b-bc151e86306e","issue":"2","journal":{"abbrevTitle":"GFZCLKXYGC","coverImgSrc":"journal/img/cover/GFZCLKXYGC.jpg","id":"31","issnPpub":"1000-7555","publisherId":"GFZCLKXYGC","title":"高分子材料科学与工程"},"keywords":[{"id":"d9f709a6-3e1c-42f8-8cb8-106b0a80b524","keyword":"与空气接触面","originalKeyword":"与空气接触面"},{"id":"f2971a98-0835-4826-908c-d5981c819e67","keyword":"与模板接触面","originalKeyword":"与模板接触面"},{"id":"a5eaddd8-48a7-48ec-963b-fe17a91ae27f","keyword":"氢键","originalKeyword":"氢键"},{"id":"1248a462-736a-4706-8e5e-a24f385b3e99","keyword":"衰减全反射谱","originalKeyword":"衰减全反射谱"},{"id":"61c7a574-0f9c-4f5b-9ef9-87037555e2dc","keyword":"聚氨酯脲","originalKeyword":"聚氨酯脲"},{"id":"f08d6ed3-6d40-4300-b99a-5ad5e26b85df","keyword":"X射线光电子谱","originalKeyword":"X射线光电子谱"}],"language":"zh","publisherId":"gfzclkxygc200002035","title":"聚氨酯脲的表面<span style=\"color:red\">组成</span>及结构","volume":"16","year":"2000"},{"abstractinfo":"采集柳林县城扬尘及空气颗粒物其他污染源(煤烟尘、土壤风沙尘、建筑水泥尘、机动车尾气尘)样品,测定了元素、离子、碳化学组分,并与其他城市的扬尘化学组分进行比较.结果表明,柳林细粒子(PM2.5)扬尘和粗粒子(PM10)扬尘的化学<span style=\"color:red\">组成</span>为:常量元素(32.66％、43.65％) ＞TC(17.49％、15.13％)＞离子组分(4.68％、2.79％)＞微量元素(1.52％、1.43％).柳林粗粒子扬尘化学<span style=\"color:red\">组成</span>与其他城市相差较大:TC含量高于其他4个城市,SO42-、Ca、Fe含量总体较低.分歧系数计算结果为:细粒子CDm,,k=0.42,粗粒子CDmk=0.46,均大于0.2,说明扬尘与土壤风沙尘的化学<span style=\"color:red\">组成</span>相似程度不高,受人类活动的影响较大.总之,土壤风沙尘、建筑水泥尘、煤烟尘是影响柳林扬尘的主要因素,煤炭使用、煤炭运输和机动车尾气尘对柳林扬尘也有一定影响.","authors":[{"authorName":"王海京","id":"3ae15a3e-08d2-4bfc-90a4-dc45afcb714b","originalAuthorName":"王海京"},{"authorName":"武媛媛","id":"76a67dc5-65f3-45eb-8bb2-75fd9852f0e5","originalAuthorName":"武媛媛"},{"authorName":"彭林","id":"b10dc62f-d96d-425a-987b-17fcf0cfad6d","originalAuthorName":"彭林"},{"authorName":"李颖慧","id":"3ac8e01a-35d4-4ace-a7c9-53ec0e726476","originalAuthorName":"李颖慧"},{"authorName":"李如梅","id":"d4a2371d-bec8-4b94-a323-1ccc9e029f44","originalAuthorName":"李如梅"},{"authorName":"牟玲","id":"bb60b3a8-122c-4706-aa3e-5747ed287f89","originalAuthorName":"牟玲"}],"doi":"10.7524/j.issn.0254-6108.2017.04.2016081706","fpage":"799","id":"22d0e5f0-0589-4b7e-b465-8989447a9f19","issue":"4","journal":{"abbrevTitle":"HJHX","coverImgSrc":"journal/img/cover/HJHX.jpg","id":"43","issnPpub":"0254-6108","publisherId":"HJHX","title":"环境化学   "},"keywords":[{"id":"ae9e6f91-0d5b-4136-9eff-64acd5fba1b9","keyword":"扬尘","originalKeyword":"扬尘"},{"id":"8214457b-2cf2-40ae-8b7b-8f38515bbb2a","keyword":"化学<span style=\"color:red\">组成</span>","originalKeyword":"化学组成"},{"id":"aa074f20-6a1f-4d95-b63b-86ce1783c05c","keyword":"分歧系数","originalKeyword":"分歧系数"}],"language":"zh","publisherId":"hjhx201704013","title":"柳林城市扬尘化学<span style=\"color:red\">组成</span>特征","volume":"36","year":"2017"},{"abstractinfo":"用本钢现有矿石原料及辅助材料,通过改变配碳量使烧结矿中FeO含量发生变化,其它化学成分保持不变；利用矿相学研究手段分析了FeO含量的变化对烧结矿矿物<span style=\"color:red\">组成</span>和显微结构的影响,并根据矿相结构找出本钢三烧结车间在现有原料条件下烧结矿中FeO含量的适宜值.","authors":[{"authorName":"戴树平","id":"e27dfb3a-6c71-4e61-9abe-1b4a6d02d5f4","originalAuthorName":"戴树平"},{"authorName":"周雷","id":"87783af9-3471-4559-a8a3-630e055f87f2","originalAuthorName":"周雷"}],"doi":"10.3969/j.issn.1000-6826.2011.06.011","fpage":"32","id":"529f0f1a-05f4-4c30-a30c-537bb87bbd7f","issue":"6","journal":{"abbrevTitle":"JSSJ","coverImgSrc":"journal/img/cover/3abe017a-2574-4821-8152-4ae974ef0471.jpg","id":"47","issnPpub":"1000-6826","publisherId":"JSSJ","title":"金属世界"},"keywords":[{"id":"37ae35eb-7468-48c3-bb77-42317c3099fd","keyword":"","originalKeyword":""}],"language":"zh","publisherId":"jssj201106011","title":"FeO含量对烧结矿矿物<span style=\"color:red\">组成</span>","volume":"","year":"2011"},{"abstractinfo":"用同样的原料和配方合成醇酸树脂因醇解工艺不同会得到不同的结果.人们对醇解工艺和醇解产物的研究大都停留在实验数据阶段,没有为分析和设计醇酸树脂提供醇解产物的计算方法.为了配合采用高分子反应统计理论分析和设计醇酸树脂的配方和生产工艺,文中给出醇解产物<span style=\"color:red\">组成</span>的计算方法及适用范围.此方法计算所得结果虽然与实验数据有误差,但此误差导致醇酸树脂分析或设计的最终误差远小于试验或生产正常的质量波动,因而是可接受的.","authors":[{"authorName":"许继光","id":"b53748aa-dc2d-4b70-a6ea-10f09ee729e1","originalAuthorName":"许继光"}],"doi":"","fpage":"19","id":"b57b1416-09cb-43eb-9d18-9ed7676141ef","issue":"3","journal":{"abbrevTitle":"TLGY","coverImgSrc":"journal/img/cover/TLGY.jpg","id":"61","issnPpub":"0253-4312","publisherId":"TLGY","title":"涂料工业   "},"keywords":[{"id":"66b33798-5c8c-4186-abe8-97bd177840a8","keyword":"醇酸树脂","originalKeyword":"醇酸树脂"},{"id":"11c9ce99-68c6-4407-8195-c5099dfca234","keyword":"醇解产物","originalKeyword":"醇解产物"},{"id":"485c26b8-1e53-4baf-a2bb-f1c17c8b8151","keyword":"化学反应统计理论","originalKeyword":"化学反应统计理论"}],"language":"zh","publisherId":"tlgy201603004","title":"醇解产物<span style=\"color:red\">组成</span>的计算","volume":"46","year":"2016"}],"totalpage":1778,"totalrecord":17773}