稀土学报(英文版), 2004, 22(3): 353-356.
吴世华 1, , 张守民 2, , 黄维平 3, , 李保庆 4, {"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"黑炭作为大气PM,5的核心组分,可以通过大气的干湿沉降进入到土壤,从而对土壤中有机污染物的迁移转化产生一定的影响.而土壤中普遍存在的矿物会与黑炭发生一定的界面作用.因此,明确这种作用对污染物迁移转化的影响,会为科学合理评价污染物的生态环境风险提供理论依据.本文以针铁矿和蒙脱石为矿物代表,以泰乐菌素(TYL)为有机污染物的代表,系统研究了针铁矿/蒙脱石与黑炭复合物对TYL的吸附特性.吸附动力学、吸附等温线、以及pH和离子强度的实验表明,黑炭与针铁矿/蒙脱石复合后其对TYL的吸附能力明显高于单独的针铁矿和蒙脱石;黑炭与针铁矿复合物(FeOOH-BC)和黑炭与蒙脱石复合物(MT-BC)对TYL的吸附动力学可以用拉格朗日二级动力学模型较好地拟合;吸附等温线用线性模型和Freundlich模型拟合的效果相对较好;pH和离子强度的实验表明,溶液pH和离子强度可以明显地影响FeOOH-BC和MT-BC对TYL的吸附;FeOOH-BC对TYL的吸附主要是氢键作用、范德华力和表面络合作用,而MT-BC对TYL吸附机理则主要是静电作用和离子交换.","authors":[{"authorName":"尹永远","id":"beab9314-e77b-496f-a29e-6a95e21be86f","originalAuthorName":"尹永远"},{"authorName":"郭学涛","id":"e81ada83-d0c8-47b2-9526-a37cdbc0b48f","originalAuthorName":"郭学涛"},{"authorName":"杨琛","id":"e5b28a1f-7949-4962-8d65-376778a0d4c9","originalAuthorName":"杨琛"},{"authorName":"高良敏","id":"9687dab1-151f-42c3-85fd-223b3e0a14e3","originalAuthorName":"高良敏"},{"authorName":"胡友彪","id":"626d6606-0c2c-43b7-9e84-ad17e2d78dc7","originalAuthorName":"胡友彪"}],"doi":"10.7524/j.issn.0254-6108.2017.03.2016070402","fpage":"572","id":"e46d4ac4-ebb1-4898-8e30-c1c2821b1a32","issue":"3","journal":{"abbrevTitle":"HJHX","coverImgSrc":"journal/img/cover/HJHX.jpg","id":"43","issnPpub":"0254-6108","publisherId":"HJHX","title":"环境化学 "},"keywords":[{"id":"01349442-3245-4c49-857a-89f8b291c12f","keyword":"黑炭","originalKeyword":"黑炭"},{"id":"cb0c11b4-e4a9-474a-9ed5-949ba820b392","keyword":"针铁矿","originalKeyword":"针铁矿"},{"id":"f8e2bedd-1f91-4a47-a808-012dfcceef9a","keyword":"蒙脱石","originalKeyword":"蒙脱石"},{"id":"1c6e8b36-22fb-4086-8c28-6d7c3d00c406","keyword":"泰乐菌素","originalKeyword":"泰乐菌素"},{"id":"e5c8ba35-9a30-4e39-adae-3974836d4cde","keyword":"吸附","originalKeyword":"吸附"}],"language":"zh","publisherId":"hjhx201703014","title":"针铁矿/蒙脱石与黑炭复合物对泰乐菌素的吸附","volume":"36","year":"2017"},{"abstractinfo":"高硅 SiCp/Al 复合材料化学镀镍是其表面金属化的关键步骤,化学镀前的敏化工艺易造成该复合材料表面Al 合金的过度腐蚀,形成腐蚀孔洞缺陷,金属化后的试样表面粗糙度增加,并对后续的钎焊工艺产生不利影响.本文采用 SnCl2+HCl 溶液对高硅SiCp/Al复合材料进行敏化处理,研究了敏化时间和敏化液浓度对试样表面质量的影响.结果表明,敏化0.5 min 后试样表面 Al 合金腐蚀程度小,沉积的Sn(OH)2颗粒数量少.敏化1.5 min 以上,试样表面Sn(OH)2颗粒数量多,但 Al 合金完全腐蚀,留下大而深的腐蚀孔洞;降低敏化液浓度也不能明显提高敏化试样的表面质量.敏化1.0 min 后,试样表面 Al 合金连续分布,无大而深的腐蚀孔洞,Sn(OH)2颗粒数量适中.经过1 min敏化的高硅 SiCp/Al 复合材料试样表面化学镀层质量良好.","authors":[{"authorName":"方萌","id":"8ec50ea9-4310-4d7d-8631-1da104e67081","originalAuthorName":"方萌"},{"authorName":"胡玲","id":"74f68218-58e3-403c-be85-3d9b4c76b284","originalAuthorName":"胡玲"},{"authorName":"杨磊","id":"c6473f52-c9cb-471a-9a33-16c06dd83562","originalAuthorName":"杨磊"},{"authorName":"史常东","id":"afcecbb1-a64b-4361-aedc-416e10f4b761","originalAuthorName":"史常东"},{"authorName":"吴玉程","id":"d105852f-9aab-498c-883a-42f2dbf6fac6","originalAuthorName":"吴玉程"},{"authorName":"汤文明","id":"96bfa2ad-fcb7-47f7-a998-dcbda82757b4","originalAuthorName":"汤文明"}],"doi":"10.3969/j.issn.1001-9731.2015.11.029","fpage":"11135","id":"94480d56-81eb-454e-9eab-cd7cb89143eb","issue":"11","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"c906b60c-6e54-4af4-9143-baa963e5d63d","keyword":"电子封装材料","originalKeyword":"电子封装材料"},{"id":"ac75d2f3-c1dd-4cf5-a0dd-bbcf9b4701af","keyword":"高硅 SiCp/Al复合材料","originalKeyword":"高硅 SiCp/Al复合材料"},{"id":"b46341cc-710d-44eb-9420-7c9d878a445b","keyword":"化学镀","originalKeyword":"化学镀"},{"id":"d266d919-c512-47f1-b773-0094d6076bd6","keyword":"敏化","originalKeyword":"敏化"},{"id":"87815d9b-2fc9-4e03-9c15-64f89273fee3","keyword":"腐蚀","originalKeyword":"腐蚀"}],"language":"zh","publisherId":"gncl201511029","title":"高硅SiCp/Al复合材料的表面敏化?","volume":"","year":"2015"},{"abstractinfo":"本文利用ICP-MS对新石器时代良渚文化瑶山遗址出土的古玉器进行了稀土元素分析,并与产于新疆和阗玉石矿的软玉进行了对比.结果表明,瑶山古玉器的稀土元素配分型式、特征比值均明显不同于和阗玉,说明良渚文化玉器的玉石应选自当地,这与李约瑟[1]教授认为中国古玉器都源于新疆和阗的论点不同.","authors":[{"authorName":"程军","id":"df11cd90-e42f-4d33-8560-930bd68cf4b6","originalAuthorName":"程军"},{"authorName":"杨学明","id":"ec6af27d-8d18-444f-bdd8-0c9ede0521de","originalAuthorName":"杨学明"},{"authorName":"杨晓勇","id":"51059075-40a5-4c5a-b4af-c2753cc4eeae","originalAuthorName":"杨晓勇"},{"authorName":"王昌燧","id":"5e3bc9aa-d0a9-4d64-bffc-0f3bf4912fdd","originalAuthorName":"王昌燧"},{"authorName":"王巨宽","id":"61e04d89-3410-403b-a3d3-61752ee2ca28","originalAuthorName":"王巨宽"}],"doi":"10.3969/j.issn.1004-0277.2000.04.001","fpage":"1","id":"45b88bd9-ec35-4673-9f2f-a746585745e5","issue":"4","journal":{"abbrevTitle":"XT","coverImgSrc":"journal/img/cover/XT.jpg","id":"65","issnPpub":"1004-0277","publisherId":"XT","title":"稀土"},"keywords":[{"id":"b1b6ed7f-32fc-42c5-8963-a86428683be0","keyword":"良渚玉器","originalKeyword":"良渚玉器"},{"id":"00dec08a-fd0d-4565-a908-75727ca85276","keyword":"ICP-MS","originalKeyword":"ICP-MS"},{"id":"751275f6-81cd-4336-bf38-afbb46d61c79","keyword":"稀土元素(REE)","originalKeyword":"稀土元素(REE)"},{"id":"aa2b6775-5773-4d97-80fa-f3ec13f2f608","keyword":"产地分析","originalKeyword":"产地分析"}],"language":"zh","publisherId":"xitu200004001","title":"良渚文化玉器的稀土元素特征及其考古学意义","volume":"21","year":"2000"},{"abstractinfo":"纯铝薄膜被广泛用作TFT LCD的金属电极,但纯铝薄膜在热工艺中容易产生小丘,对TFT的阵列工艺的良率有较大影响.本文用磁控溅射的方法在不同温度下沉积纯铝薄膜作为薄膜晶体管的栅极,并通过电学检测、扫描电子显微镜和应力测试等方法对不同温度下沉积的纯铝薄膜的小丘生长情况进行了研究.实验结果表明:纯铝成膜温度提高,薄膜的晶粒尺寸增大,退火后产生小丘的密度和尺寸明显降低,温度应力曲线中屈服点温度也相应提高.量产中适当提高成膜温度,可以有效抑制小丘的发生,提高TFT阵列工艺的量产良率.","authors":[{"authorName":"刘晓伟","id":"e7ec8238-4fd5-4796-b243-48cc3e655bec","originalAuthorName":"刘晓伟"},{"authorName":"郭会斌","id":"38ac1689-b9d3-409f-8ac3-7e961916cd3e","originalAuthorName":"郭会斌"},{"authorName":"李梁梁","id":"05052344-d434-45b7-abe6-731b779fbcf7","originalAuthorName":"李梁梁"},{"authorName":"郭总杰","id":"90b081c6-647c-4d5a-ab02-32c720813ac4","originalAuthorName":"郭总杰"},{"authorName":"郝昭慧","id":"bad08ea1-d1cf-4af8-a258-9dac3a7b5afe","originalAuthorName":"郝昭慧"}],"doi":"10.3788/YJYXS20142904.0548","fpage":"548","id":"84058314-62d4-463c-b3d0-7ec2b24effe9","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"a141c7e7-37a4-4d78-af66-17c05d3c5490","keyword":"薄膜晶体管阵列工艺","originalKeyword":"薄膜晶体管阵列工艺"},{"id":"a4def192-a88d-4e61-8959-efa4416beb54","keyword":"磁控溅射","originalKeyword":"磁控溅射"},{"id":"54f7d821-4319-4122-ba1f-a291183215a2","keyword":"纯铝薄膜","originalKeyword":"纯铝薄膜"},{"id":"29e29a67-00f5-4994-97df-7f6401009faf","keyword":"小丘","originalKeyword":"小丘"},{"id":"2c4a0738-7bd1-4e65-899f-0d0b9d01f48f","keyword":"量产良率","originalKeyword":"量产良率"}],"language":"zh","publisherId":"yjyxs201404013","title":"磁控溅射成膜温度对纯铝薄膜小丘生长以及薄膜晶体管阵列工艺良率的影响","volume":"29","year":"2014"},{"abstractinfo":"在KH2PO4-Na2HPO4介质中, 氯化十六烷基吡啶增敏剂存在下, 铈(Ⅳ)对高碘酸钾氧化孔雀绿的反应具有阻抑作用, 据此建立一种测定痕量铈的新方法.考察反应的最佳条件, 测定了反应动力学参数.本法在表面活性剂存在下, 其灵敏度提高9倍.线性范围为0~104 μg·L-1, 检出限为1.22×10-7 g·L-1.此法用于大米, 人发等样品中铈的测定, 结果满意.","authors":[{"authorName":"郭飞君","id":"9ca1c9b1-7515-42b5-ac21-07470938ecec","originalAuthorName":"郭飞君"},{"authorName":"王晓菊","id":"f6cf2f59-84ec-401a-8566-a04418d41b10","originalAuthorName":"王晓菊"},{"authorName":"赵仑","id":"59fdf683-a90b-46b5-bf61-4ca71e1727e8","originalAuthorName":"赵仑"}],"doi":"10.3969/j.issn.0258-7076.2008.03.026","fpage":"395","id":"ab35c5f5-1ce6-40b1-bb16-6d3931d826f1","issue":"3","journal":{"abbrevTitle":"XYJS","coverImgSrc":"journal/img/cover/XYJS.jpg","id":"67","issnPpub":"0258-7076","publisherId":"XYJS","title":"稀有金属"},"keywords":[{"id":"52d1779b-a3d5-4b7b-bedf-46efd2871ed5","keyword":"阻抑动力学分光光度法","originalKeyword":"阻抑动力学分光光度法"},{"id":"77c94d8b-2885-4c9f-89fb-1b5e17a9a858","keyword":"铈","originalKeyword":"铈"},{"id":"6649d6ac-e3fd-45b9-8b13-648b57fb45b8","keyword":"孔雀绿","originalKeyword":"孔雀绿"},{"id":"2aadd975-23c7-41ff-b89c-8ec80fe15283","keyword":"高碘酸钾","originalKeyword":"高碘酸钾"},{"id":"5d55306f-f80d-4702-9b90-48c730e41a80","keyword":"氯化十六烷基吡啶","originalKeyword":"氯化十六烷基吡啶"}],"language":"zh","publisherId":"xyjs200803026","title":"表面活性剂增敏阻抑动力学光度法测定痕量铈——孔雀绿-高碘酸钾反应体系","volume":"32","year":"2008"},{"abstractinfo":"本实验设计了一种简单有效的一体化大尺度染料敏化太阳能电池(DSC)模块, 开孔率(有效面积与总面积之比)高达85%, 远高于传统的串联和并联模块设计. 该设计采用在光阳极导电玻璃表面电镀镍栅极和对电极导电玻璃表面电镀镍薄膜修饰来降低电池传输电阻. 有效面积为510 mm2的电池模块光电转换效率η达到3.00%(AM 1.5, 100 mW/cm2), 填充因子(FF)为0.594, 与未镀镍的样品(η为0.537%, FF为0.251)相比, 性能显著提高. 并利用阻抗谱对大面积性能改善进行了解释, 还利用SEM、XRD等分析了电镀镍薄膜的质量.","authors":[{"authorName":"马辉","id":"8392c900-faf2-4319-968f-aa0a5a2fdc11","originalAuthorName":"马辉"},{"authorName":"刘志勇","id":"f25db39e-6f2d-4b3f-a5a3-34b80369e97c","originalAuthorName":"刘志勇"},{"authorName":"鲁玉明","id":"f5053526-795d-4cff-a737-1ca91088fcba","originalAuthorName":"鲁玉明"},{"authorName":"金晓艳","id":"6a2d9d14-71bf-4496-a38d-6e73a9696bf9","originalAuthorName":"金晓艳"},{"authorName":"蔡传兵","id":"3a79d2d1-d7ad-44cc-acbd-d855351f539e","originalAuthorName":"蔡传兵"}],"categoryName":"|","doi":"10.3724/SP.J.1077.2011.01261","fpage":"1261","id":"c482112d-7b3d-455a-8f35-a38510ccc300","issue":"12","journal":{"abbrevTitle":"WJCLXB","coverImgSrc":"journal/img/cover/WJCLXB.jpg","id":"62","issnPpub":"1000-324X","publisherId":"WJCLXB","title":"无机材料学报"},"keywords":[{"id":"f259e800-3e63-4355-9b1f-a913ef9f29d4","keyword":"染料敏化太阳能电池","originalKeyword":"染料敏化太阳能电池"},{"id":"2633a731-4525-4d00-b14f-024e6e755ec2","keyword":" large area","originalKeyword":" large area"},{"id":"8feb6a2a-af39-469b-84e1-d1d2ce2fbf92","keyword":" module design","originalKeyword":" module design"},{"id":"9ca39a41-fc16-4710-a6cf-b5b61ce8fe93","keyword":" aperture ratio","originalKeyword":" aperture ratio"},{"id":"e967893a-7916-4780-8d94-e779f2417948","keyword":" electroplating nickel grid","originalKeyword":" electroplating nickel grid"}],"language":"zh","publisherId":"1000-324X_2011_12_1","title":"高开孔率染料敏化太阳能电池一体化模块及其性能优化","volume":"26","year":"2011"},{"abstractinfo":"本实验设计了一种简单有效的一体化大尺度染料敏化太阳能电池(DSC)模块,开孔率(有效面积与总面积之比)高达85%,远高于传统的串联和并联模块设计.该设计采用在光阳极导电玻璃表面电镀镍栅极和对电极导电玻璃表面电镀镍薄膜修饰来降低电池传输电阻.有效面积为510 mm2的电池模块光电转换效率η达到3.00%(AM l.5,1 00 mW/cm2),填充因子(FF)为0.594,与未镀镍的样品(η为0.537%,FF为0.251)相比,性能显著提高.并利用阻抗谱对大面积性能改善进行了解释,还利用SEM、XRD等分析了电镀镍薄膜的质量.","authors":[{"authorName":"马辉","id":"d0a55116-e06e-4b12-a6bf-7eb8b4effbeb","originalAuthorName":"马辉"},{"authorName":"刘志勇","id":"76264763-18d9-4be0-8672-122eb8a5770f","originalAuthorName":"刘志勇"},{"authorName":"鲁玉明","id":"bea51462-51ed-4843-a157-923029149433","originalAuthorName":"鲁玉明"},{"authorName":"金晓艳","id":"969f3a0c-ff0e-42a9-a6ec-ea00147246b5","originalAuthorName":"金晓艳"},{"authorName":"蔡传兵","id":"b897230b-87b8-403a-b902-e94ff56af46e","originalAuthorName":"蔡传兵"}],"doi":"10.3724/SP.J.1077.2011.01261","fpage":"1261","id":"26befb64-7ad0-41e4-9578-711a41b71c8d","issue":"12","journal":{"abbrevTitle":"WJCLXB","coverImgSrc":"journal/img/cover/WJCLXB.jpg","id":"62","issnPpub":"1000-324X","publisherId":"WJCLXB","title":"无机材料学报"},"keywords":[{"id":"d39ad2d3-d4a3-4bfe-bc80-4affc73db078","keyword":"染料敏化太阳能电池","originalKeyword":"染料敏化太阳能电池"},{"id":"277a9351-a69d-4ae8-a990-2e9aa6341ac8","keyword":"大面积","originalKeyword":"大面积"},{"id":"c3d4bda2-4b1a-4659-a0b7-763da081a06f","keyword":"模块设计","originalKeyword":"模块设计"},{"id":"dcb6c80e-570e-411a-9e4e-3a2239fb4f6f","keyword":"开孔率","originalKeyword":"开孔率"},{"id":"0dfdb482-10a5-4da4-afda-75537144fafb","keyword":"镍栅极","originalKeyword":"镍栅极"}],"language":"zh","publisherId":"wjclxb201112005","title":"高开孔率染料敏化太阳能电池一体化模块及其性能优化","volume":"25","year":"2011"},{"abstractinfo":"TiO2压敏陶瓷的压敏电压低、非线性系数高、介电常数大、制备工艺简单,在电子、通信、航天航空等高新技术产业的低压保护中具有广阔的应用前景.主要从粉体制备工艺、叠层方式烧结、烧结氛围、烧结温度及保温时间、掺杂物质及浓度等方面归纳总结了TiO2压敏陶瓷的研究状况,并展望了其今后的研究趋势.","authors":[{"authorName":"巩云云","id":"e4bfa27a-b366-4198-b634-64a4c4aeb3c5","originalAuthorName":"巩云云"},{"authorName":"初瑞清","id":"a3d1b92d-c8bd-4bd4-8a5a-ebb90d20f6d6","originalAuthorName":"初瑞清"},{"authorName":"徐志军","id":"9dd0fd03-d904-4ee1-88b5-6e72865ec170","originalAuthorName":"徐志军"},{"authorName":"马帅","id":"56e562b6-ec0f-4ac7-a3c0-1a797887e998","originalAuthorName":"马帅"},{"authorName":"郝继功","id":"77e4d318-1b3d-4523-b7aa-6e8709526238","originalAuthorName":"郝继功"},{"authorName":"李国荣","id":"647ef615-dfa5-46bf-aab5-30b2aa04afdb","originalAuthorName":"李国荣"}],"doi":"","fpage":"107","id":"802c3cde-6695-4a33-bf32-ce19f5ad15cd","issue":"11","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"4d253098-f50b-4c87-be1e-72b95333086a","keyword":"二氧化钛","originalKeyword":"二氧化钛"},{"id":"61f3fac7-d63d-4b31-820c-30b677caabaf","keyword":"压敏陶瓷","originalKeyword":"压敏陶瓷"},{"id":"2da2936d-9391-460f-b831-a4320e049b48","keyword":"制备工艺","originalKeyword":"制备工艺"},{"id":"7cfca81d-280b-4589-9b77-e849f88f10ef","keyword":"掺杂","originalKeyword":"掺杂"}],"language":"zh","publisherId":"cldb201411020","title":"TiO2压敏陶瓷的研究进展","volume":"28","year":"2014"},{"abstractinfo":"用化学沉淀法合成微细的氧化铟气敏粉体,选用几种稀有贵金属掺杂氧化铟粉体,用D/maxrA X射线衍射仪测定粉体相结构,用RQ-2型气敏特性测试仪测试氧化铟气敏元件的气敏特性,绘制了掺杂后氧化铟粉体对几种气体的灵敏度-温度曲线.结果表明,氧化铟气敏材料电阻值适中,响应恢复快,气体灵敏度高,可对多种气体实行专一检测或同时检测.","authors":[{"authorName":"刘秉涛","id":"886a3b06-9781-4feb-abfb-8edb657f2b2c","originalAuthorName":"刘秉涛"},{"authorName":"姜安玺","id":"e015736b-df42-4141-8f52-596c2f2c0f58","originalAuthorName":"姜安玺"},{"authorName":"徐甲强","id":"664db8de-f699-47ff-878b-90acf0cc268f","originalAuthorName":"徐甲强"}],"doi":"","fpage":"1093","id":"0f64e300-a232-4448-8650-b5b711ef0ae8","issue":"10","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":"8116f049-47aa-4be3-8f2a-a6cf06ee1f3e","keyword":"氧化铟","originalKeyword":"氧化铟"},{"id":"7166cb4e-7722-475d-b3dd-7975b0f8150b","keyword":"气敏材料","originalKeyword":"气敏材料"},{"id":"44634eb7-2004-492a-9c25-e380d9b8d5f9","keyword":"制备","originalKeyword":"制备"},{"id":"59d57161-b5ef-4a83-a93a-2b6dc54534e9","keyword":"特性","originalKeyword":"特性"}],"language":"zh","publisherId":"xyjsclygc200410021","title":"氧化铟气敏材料的制备与特性","volume":"33","year":"2004"},{"abstractinfo":"采用溶胶-凝胶工艺制备了用于汽车新型传感器的氧敏薄膜材料,包括过渡金属氧化物(MoOx、TiOx、CrOx)、钙钛矿型(SrTiO3/LaNiO3、LaNiO3、LaCrO3)和类钙钛矿型(La1-xMxNiO4)纳米粒子薄膜.结果表明,与传统氧传感器用的ZrO2、TiO2半导体材料相比,这三类材料的阻温系数小,敏感度高,响应速度快","authors":[{"authorName":"徐明霞","id":"57680372-a771-4fd6-b5b5-620cb4d4fcf0","originalAuthorName":"徐明霞"},{"authorName":"刘丽月","id":"e6f2c50f-dff2-4c55-b4c4-233d866c8f9e","originalAuthorName":"刘丽月"},{"authorName":"郑嘹赢","id":"b3d5e626-0561-4329-a838-6a97f9b88352","originalAuthorName":"郑嘹赢"},{"authorName":"樊丽莹","id":"b2e43768-4192-44c4-ac10-ddc9db6bb05c","originalAuthorName":"樊丽莹"},{"authorName":"徐廷献","id":"46e7665b-21bc-4fff-b25c-9b0fea984bb6","originalAuthorName":"徐廷献"}],"doi":"10.3321/j.issn:1005-3093.2001.01.003","fpage":"17","id":"5c53f44d-8877-44bc-b221-3842dc47a673","issue":"1","journal":{"abbrevTitle":"CLYJXB","coverImgSrc":"journal/img/cover/CLYJXB.jpg","id":"16","issnPpub":"1005-3093","publisherId":"CLYJXB","title":"材料研究学报"},"keywords":[{"id":"0f6f8cd7-9667-4cfe-af7f-a92defc1d4b8","keyword":"薄膜材料","originalKeyword":"薄膜材料"},{"id":"67cd8bdc-9764-4a73-8b26-b61103bd656f","keyword":"氧敏特性","originalKeyword":"氧敏特性"},{"id":"e8776be4-c079-46a2-8ab5-04efd3bb7b48","keyword":"纳米粒子","originalKeyword":"纳米粒子"},{"id":"85ddaece-2a66-4089-b692-9efb14a1528d","keyword":"溶胶","originalKeyword":"溶胶"},{"id":"5667a056-c0c6-4f4d-a742-26c2537e0fdc","keyword":"-凝胶法","originalKeyword":"-凝胶法"}],"language":"zh","publisherId":"clyjxb200101003","title":"新型氧敏薄膜材料","volume":"15","year":"2001"}],"totalpage":2388,"totalrecord":23871}