{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"用液相沉积法制备了壳层均匀、包裹致密的单分散P(St-co-AA)/Fe2O3亚微核壳粒子.用XRD、TEM和FESEM表征了该类粒子的物相、形貌及微观结构.结果表明用该法制备的核壳粒子,其壳层为Fe2O3晶粒,且均匀地包裹在乳胶粒子表面形成草莓状结构;改变FeCl3溶液的用量和重复包裹次数能方便地调节P(St-co-AA)/Fe2O3亚微核壳粒子的壳层厚度.可通过煅烧法用该核壳粒子来制备形状完整的单分散亚微中空磁球.","authors":[{"authorName":"黄中梅","id":"58ca2759-13e4-4cf1-834f-e47d6726c41b","originalAuthorName":"黄中梅"},{"authorName":"赵素玲","id":"832be98b-2550-4be1-934a-e7d10f651845","originalAuthorName":"赵素玲"}],"doi":"","fpage":"63","id":"77b43fd2-8769-4fca-a636-f66036ac8c77","issue":"10","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"a8686b7c-aef3-4826-abca-063c33b2087a","keyword":"核壳粒子","originalKeyword":"核壳粒子"},{"id":"86b4992c-5f2f-4216-b6ed-60b702a6b1ad","keyword":"亚微中空磁球","originalKeyword":"亚微中空磁球"},{"id":"9119020e-7d0e-4d3b-ac84-728a27806ca4","keyword":"聚(苯乙烯-共-丙烯酸)","originalKeyword":"聚(苯乙烯-共-丙烯酸)"},{"id":"80dded21-fc9c-44a8-85f5-44957b01196b","keyword":"Fe2O3","originalKeyword":"Fe2O3"}],"language":"zh","publisherId":"cldb201410016","title":"水解FeCl3制备单分散P(St-co-AA)/Fe2O3亚微核壳粒子","volume":"28","year":"2014"},{"abstractinfo":"结合空心纳微粒子的形成机理和结构可控性,阐述了空心纳微粒子的硬模板法和软模板法两大制备技术,重点综述了逐层自组装(LBL)法、表面化学反应与沉积法、微封装法等的研究进展.概述了空心纳微粒子的结构与性能的关系及其在材料科学、生物医学、催化剂等领域的应用现状及前景.","authors":[{"authorName":"黄中梅","id":"e74fc35c-5fc9-4c41-9560-c563b6d4017a","originalAuthorName":"黄中梅"},{"authorName":"官建国","id":"56c8b740-548f-4b53-a6ba-3a73dce21794","originalAuthorName":"官建国"},{"authorName":"甘治平","id":"b038cce9-85e0-4818-a945-01bad7991ddc","originalAuthorName":"甘治平"},{"authorName":"王振杰","id":"07dde63d-17cb-4a10-aab1-1636ec5c7952","originalAuthorName":"王振杰"}],"doi":"10.3321/j.issn:1000-324X.2005.06.001","fpage":"1281","id":"a620cb31-ab9d-4ef4-81f3-6cd7655e10e8","issue":"6","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":"6cf196f0-b5eb-4bfb-86c0-93cf503ad762","keyword":"空心纳微粒子","originalKeyword":"空心纳微粒子"},{"id":"30c382d6-c01e-4e2d-982c-d8e901fec15f","keyword":"模板","originalKeyword":"模板"},{"id":"ccb6e5ba-29df-47ff-9fa8-838354a196ee","keyword":"逐层自组装法","originalKeyword":"逐层自组装法"},{"id":"3b7232a5-159f-486f-8b12-f072da454b56","keyword":"表面化学反应与沉积法","originalKeyword":"表面化学反应与沉积法"},{"id":"04e30f63-e5cc-45cc-8e6a-6de24fb84327","keyword":"微封装法","originalKeyword":"微封装法"}],"language":"zh","publisherId":"wjclxb200506001","title":"空心纳微粒子的模板法制备技术及应用","volume":"20","year":"2005"},{"abstractinfo":"梅钢铁水中磷含量偏高,冶炼低磷钢种有困难,通过对国内外降磷方法所采用的\"铁水炉外预脱磷\"、\"SRP法\"及\"转炉双渣法脱磷方法\"的比较分析,摸索出适合梅钢自身特点的方法--转炉同炉铁水脱磷炼钢工艺.通过在冶炼中采用前期造渣、中途倒渣的方法,将磷的质量分数降到≤0.01%,满足了生产低磷钢的要求.","authors":[{"authorName":"唐洪乐","id":"07f52dc6-c59e-4e0f-ae66-bd2d5c1bf385","originalAuthorName":"唐洪乐"},{"authorName":"汪洪峰","id":"ab27baba-5cb3-4e6f-99f0-9b2e0e782999","originalAuthorName":"汪洪峰"},{"authorName":"孙晓辉","id":"d53d7143-3298-436e-82b0-761567afc07b","originalAuthorName":"孙晓辉"}],"doi":"","fpage":"34","id":"645485c4-c2c3-41ec-95d8-e6e43c02277e","issue":"10","journal":{"abbrevTitle":"GT","coverImgSrc":"journal/img/cover/GT.jpg","id":"27","issnPpub":"0449-749X","publisherId":"GT","title":"钢铁"},"keywords":[{"id":"cb44b437-92fd-4616-8608-bf22a05dc3b7","keyword":"TBM顶底复吹","originalKeyword":"TBM顶底复吹"},{"id":"6fc84803-f180-4728-963f-0588623349d2","keyword":"脱磷率","originalKeyword":"脱磷率"},{"id":"f6649a2c-ccf1-418a-abb5-33f487c5c47a","keyword":"中磷铁水","originalKeyword":"中磷铁水"},{"id":"78984ddf-c3a0-4b3f-bee7-e43eb57898d4","keyword":"低磷钢","originalKeyword":"低磷钢"}],"language":"zh","publisherId":"gt200810008","title":"梅钢中磷铁水低磷钢冶炼问题的探讨","volume":"43","year":"2008"},{"abstractinfo":"在梅钢2号连铸机生产过程中,漏钢事故经常发生,同时误报的次数较为频繁,严重影响板坯质量和铸机的高效化生产的情况.针对这种情况,梅钢自主研发了适合梅钢二号连铸机的漏钢预报系统.模型投用后完全避免了粘结漏钢,解决了困扰梅钢2号连铸机正常生产的难题,并且为公司节约巨额费用.","authors":[{"authorName":"田建良","id":"2912a4f1-07df-4193-8d9b-d7fbc4fe9c06","originalAuthorName":"田建良"},{"authorName":"陈开义","id":"4d3b73ea-cb43-472b-be7c-d2c7d5a2568d","originalAuthorName":"陈开义"},{"authorName":"江中块","id":"59cfa878-c55b-4755-855e-b1ded9b6eeea","originalAuthorName":"江中块"}],"doi":"","fpage":"15","id":"38ff962c-1726-4ac2-bd24-fbaf1325e382","issue":"3","journal":{"abbrevTitle":"LZ","coverImgSrc":"journal/img/cover/LZ.jpg","id":"52","issnPpub":"1005-4006","publisherId":"LZ","title":"连铸"},"keywords":[{"id":"b538988a-0a42-4076-8f61-67c873f52d89","keyword":"粘结漏钢","originalKeyword":"粘结漏钢"},{"id":"65bc285f-a178-4164-9021-d2f76792c9ba","keyword":"预报系统","originalKeyword":"预报系统"}],"language":"zh","publisherId":"lz201303005","title":"梅钢漏钢预报系统的开发与实践","volume":"","year":"2013"},{"abstractinfo":"内梅罗指数和地质累积指数广泛应用于土壤、沉积物等环境介质中的重金属污染评价,选择金矿开发区土壤中Hg、Pb、Cu、Cd、Zn 5种重金属,对比了两种方法的评价结果,统计分析各个样品的综合污染程度,区分不同方法评价的差异,并提出了形成差异的主要原因.","authors":[{"authorName":"张江华","id":"efdcea07-2be1-458c-84fa-699bd0b89294","originalAuthorName":"张江华"},{"authorName":"赵阿宁","id":"f32933ac-35f0-4353-bb73-a2565d8dc9f0","originalAuthorName":"赵阿宁"},{"authorName":"王仲复","id":"2eb27f25-2f04-4b75-b13c-247e0a22aa30","originalAuthorName":"王仲复"},{"authorName":"柯海玲","id":"eff0ac9e-55f0-4a2d-aaa8-a9bce01d5559","originalAuthorName":"柯海玲"},{"authorName":"陈华清","id":"9606329a-4136-415f-82a1-428cb06ab0aa","originalAuthorName":"陈华清"}],"doi":"10.3969/j.issn.1001-1277.2010.08.013","fpage":"43","id":"f1cf5aba-2710-4849-942d-04491613fc65","issue":"8","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"20be97ae-033d-4402-b919-c39b28722962","keyword":"重金属污染","originalKeyword":"重金属污染"},{"id":"52cc6e94-854b-48af-8151-eda00703471c","keyword":"内梅罗指数","originalKeyword":"内梅罗指数"},{"id":"263bc8c0-00c8-49c6-a191-5a15da4005d6","keyword":"地质累积指数","originalKeyword":"地质累积指数"},{"id":"d0f4efc7-5f17-4522-a02a-8272047b1e40","keyword":"小秦岭金矿带","originalKeyword":"小秦岭金矿带"}],"language":"zh","publisherId":"huangj201008013","title":"内梅罗指数和地质累积指数在土壤重金属评价中的差异探讨——以小秦岭金矿带为例","volume":"31","year":"2010"},{"abstractinfo":"发展了一种新的采用毛细管区带电泳分析柠檬黄铝色淀和日落黄铝色淀的方法。通过前处理步骤成功实现了铝色淀中铝基质与色素的分离。利用石英毛细管柱(48.50 cm(有效长度40.00 cm)×50μm),分别针对柠檬黄铝色淀和日落黄铝色淀进行了电泳条件的优化,并得到最优分离结果。所建立的定量分析方法的检出限对于柠檬黄铝色淀和日落黄铝色淀分别达0.26 mg / L 和0.27 mg / L,线性范围分别为0.53~1.3×102 mg / L 和0.54~1.4×102 mg / L,两种被分析物的测定重复性(RSD,n =6)分别为4.3%和5.7%,日间重复性( RSD,n =6)分别为5.6%和6.0%。经过更深入研究后,该方法可以发展为食品中相应色淀的检测方法。","authors":[{"authorName":"张一丁","id":"a3cd5a59-625b-4a67-906e-a58d01f934b0","originalAuthorName":"张一丁"},{"authorName":"常翠兰","id":"bd234c61-9f75-42c4-9867-88ba02e2e682","originalAuthorName":"常翠兰"},{"authorName":"郭启雷","id":"ba21cc69-4e1c-4f84-93c8-2b377338be44","originalAuthorName":"郭启雷"},{"authorName":"曹红","id":"43e261aa-deea-48df-964a-30f28d775cb2","originalAuthorName":"曹红"},{"authorName":"白玉","id":"e16b1374-1276-4df1-a852-6303926fc681","originalAuthorName":"白玉"},{"authorName":"刘虎威","id":"a6637165-a99e-44d9-b78b-5485c5a9effb","originalAuthorName":"刘虎威"}],"doi":"10.3724/SP.J.1123.2013.11020","fpage":"438","id":"34bddd19-2587-4a94-9cd5-a466cb60472f","issue":"4","journal":{"abbrevTitle":"SP","coverImgSrc":"journal/img/cover/SP.jpg","id":"58","issnPpub":"1000-8713","publisherId":"SP","title":"色谱 "},"keywords":[{"id":"1dd3d34a-c643-427f-a637-fb3e56f9a722","keyword":"毛细管区带电泳","originalKeyword":"毛细管区带电泳"},{"id":"fccec8e0-4a52-4539-86a6-31f6e774afea","keyword":"柠檬黄","originalKeyword":"柠檬黄"},{"id":"e8e9f7cc-130d-4f7e-bf65-b2c7d231f885","keyword":"日落黄","originalKeyword":"日落黄"},{"id":"621766ff-feb5-4cc5-a66c-09c06f6f971d","keyword":"色淀","originalKeyword":"色淀"},{"id":"3a9685cb-c5ad-41ad-aa36-0abd952990ea","keyword":"食品","originalKeyword":"食品"}],"language":"zh","publisherId":"sp201404019","title":"食品中柠檬黄铝色淀和日落黄铝色淀的毛细管区带电泳分析","volume":"","year":"2014"},{"abstractinfo":"模拟土壤施用稀土定位试验结果表明:黄刚土中各组份吸附稀土的能力为:无定形FexOy、紧结有机物>松结有机物>MnOx>晶形FexOy>永久负电荷;进入黄刚土的外源轻稀土,主要累积于紧结有机态(29.90~49.72%)、无定形氧化铁吸附态(26.81~46.76%),而累积于松结有机态的轻稀土受外源稀土的加入量影响较小(24.93~28.72%).当外源稀土用量在0.684~2.735mg/kg*季时,大豆地上部稀土无明显增加,而用量达13.674mg/kg时,地上部明显增加.黄刚土外源稀土的最佳用量为0.684mg/kg,此时,大豆增产43.82±15.08%、油菜增产17.92±9.07%.","authors":[{"authorName":"荆国芳","id":"fc1b92c6-600d-4fcd-8e1e-fa3dc5a1c9f5","originalAuthorName":"荆国芳"},{"authorName":"钱晓晴","id":"f0c35fa0-cdb7-47b9-b5f0-473802d2c771","originalAuthorName":"钱晓晴"}],"doi":"10.3969/j.issn.1004-0277.2002.02.011","fpage":"38","id":"8b89503d-85fe-42d8-a31b-5ee41eed9fc4","issue":"2","journal":{"abbrevTitle":"XT","coverImgSrc":"journal/img/cover/XT.jpg","id":"65","issnPpub":"1004-0277","publisherId":"XT","title":"稀土"},"keywords":[{"id":"d9808f7e-67c4-4266-9caf-60295c858dc6","keyword":"稀土","originalKeyword":"稀土"},{"id":"60f39a5b-d062-4283-92b6-49c319b6ff2e","keyword":"形态","originalKeyword":"形态"},{"id":"97b50517-dd4d-4380-b408-02394f1ee3bd","keyword":"生态效应","originalKeyword":"生态效应"}],"language":"zh","publisherId":"xitu200202011","title":"外源稀土在黄刚土中形态分布和生态效应研究","volume":"23","year":"2002"},{"abstractinfo":"建立了快速检测环境水样中的丁基黄原酸的离子色谱-紫外检测方法.以NaOH淋洗液等度淋洗,丁基黄原酸在IonPacAS16高效阴离子交换柱(HPAEC)上可以在8 min内完成分离,而常规共存离子无干扰.使用紫外检测法(UV)301nm波长进行测定,丁基黄原酸的检出限(500 μL进样,S/N=3)分别为0.1 μg·L-1,且均具有较宽的线性范围(0.5-1000 μg·L-1).5 μg· L-1丁基黄原酸标准溶液测定的相对标准偏差小于1%,而样品加标回收率在99.3%-104.8%之间.该方法检测丁基黄原酸无需复杂前处理、检测迅速、灵敏度高,适用于地表水中丁基黄原酸的分析.","authors":[{"authorName":"李仁勇","id":"13b1402d-1df2-4e6c-a17f-2e700ea36e4a","originalAuthorName":"李仁勇"}],"doi":"","fpage":"688","id":"daaa1004-a63d-40f2-9b71-6cd035e81b98","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":"b3f6ddc0-18e3-4e33-9f8e-e92486ae1ad9","keyword":"离子色谱","originalKeyword":"离子色谱"},{"id":"c624ec5e-dec7-4095-a80e-b46a3f78c254","keyword":"紫外检测","originalKeyword":"紫外检测"},{"id":"3ce5b231-c12a-4e54-9816-730ac8e3d6ff","keyword":"IonPac AS16","originalKeyword":"IonPac AS16"},{"id":"f5b071a8-2075-498b-ad3f-52842947a33a","keyword":"环境水样","originalKeyword":"环境水样"},{"id":"63064339-1cb3-4e1f-ba83-1e50a8e95e27","keyword":"丁基黄原酸","originalKeyword":"丁基黄原酸"}],"language":"zh","publisherId":"hjhx201703029","title":"离子色谱法串联紫外检测环境地表水样中丁基黄原酸","volume":"36","year":"2017"},{"abstractinfo":"低碳钢在双氧水系抛光液中化学抛光时,双氧水易分解,温度不易控制,而在硝酸系抛光液中化学抛光会产生黄烟且能耗较大.为此,研制了一种新型无黄烟低碳钢中温化学抛光液对Q235钢化学抛光,考察了化学抛光液组成及温度、时间对抛光质量的影响.结果表明:使用本工艺的化学抛光试样表面平整、粗糙度低,光亮度达3~4级;获得最佳抛光质量的化学抛光工艺为120~250 mL/L H3PO4,100~200 mL/L H3SO4,40~80 g/L NaNO3,10~40 g/L NaCl,20 g/L复合添加剂,55~65℃,2~5 min.","authors":[{"authorName":"朱其柱","id":"915a74d4-7101-4eaa-96b4-addf8a6415b6","originalAuthorName":"朱其柱"},{"authorName":"金光","id":"412b152f-2cb6-4d47-866a-03af54d7a13d","originalAuthorName":"金光"},{"authorName":"赵晖","id":"c3f3492c-b025-4df9-a83c-e7c38a1a7dca","originalAuthorName":"赵晖"}],"doi":"","fpage":"42","id":"d319e205-e66e-47bd-bdef-1925a14ab04a","issue":"9","journal":{"abbrevTitle":"CLBH","coverImgSrc":"journal/img/cover/CLBH.jpg","id":"7","issnPpub":"1001-1560","publisherId":"CLBH","title":"材料保护"},"keywords":[{"id":"6b2153e6-1e09-4d98-822e-67434c68e3f7","keyword":"化学抛光","originalKeyword":"化学抛光"},{"id":"c537e638-18f1-4a72-b258-d4574cbe0b0a","keyword":"Q235钢","originalKeyword":"Q235钢"},{"id":"2a88ac12-86b4-4293-b400-567886dd9646","keyword":"中温","originalKeyword":"中温"},{"id":"8dc9b550-70a9-471f-95ec-7d9c02e0b11b","keyword":"光亮度","originalKeyword":"光亮度"}],"language":"zh","publisherId":"clbh201009014","title":"Q235钢中温无黄烟化学抛光工艺","volume":"43","year":"2010"},{"abstractinfo":"以壳聚糖为吸附剂,戊二醛作为交联剂,采用反相悬浮交联法制备球状壳聚糖树脂,利用二硫化碳作为改性剂,在碱性条件下对壳聚糖树脂进行黄原酸化改性,制备成交联黄原酸化壳聚糖树脂(cross-linked xanthated chitosan resin,CXCR).对 CXCR进行红外表征,并研究了其对水溶液中棒曲霉素的吸附性能.结果表明,CXCR 在棒曲霉素初始浓度为8 mg/L,CXCR 用量为1 g/L,溶液 pH 值=4,25℃下吸附16 h,吸附量可达6.53 mg/g,可有效地吸附水溶液中的棒曲霉素.CXCR 对棒曲霉素的吸附符合拟二级动力学模型;吸附热力学符合 Freundlich 吸附等温线模型.CXCR 有望作为一种新型的材料用于棒曲霉素的吸附,具有广阔的应用前景.","authors":[{"authorName":"刘心荷","id":"4cc4f365-7fcc-4f23-bd15-5f9d8ab6f41e","originalAuthorName":"刘心荷"},{"authorName":"李杨","id":"b6ff6fc6-9ac8-4eaf-b562-c30fa26a17fa","originalAuthorName":"李杨"},{"authorName":"孟祥红","id":"7d4f140e-18e8-4c6b-bfb4-bd66bff2f59a","originalAuthorName":"孟祥红"},{"authorName":"刘炳杰","id":"e6f1f754-c172-4062-9a45-646fc4d8c2ab","originalAuthorName":"刘炳杰"}],"doi":"10.3969/j.issn.1001-9731.2015.04.004","fpage":"4020","id":"9ec9e735-106b-47b3-bb55-a1068e6b742e","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":"bdc9ac8f-35c9-4558-9751-28b409ca899d","keyword":"壳聚糖树脂","originalKeyword":"壳聚糖树脂"},{"id":"8f3fe566-5ce9-4eba-a921-1ad019f38477","keyword":"黄原酸化","originalKeyword":"黄原酸化"},{"id":"c2e87a30-c0bf-482e-8238-71ca9be66203","keyword":"改性","originalKeyword":"改性"},{"id":"94480ea7-0d46-475a-bc31-a2efcc036ed3","keyword":"棒曲霉素","originalKeyword":"棒曲霉素"},{"id":"fd3fd57a-303c-458e-9dcf-d3ef0353c0b3","keyword":"吸附","originalKeyword":"吸附"}],"language":"zh","publisherId":"gncl201504004","title":"交联黄原酸化壳聚糖树脂对水溶液中棒曲霉素的吸附","volume":"","year":"2015"}],"totalpage":9226,"totalrecord":92258}