{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":3,"startPagecode":1},"records":[{"abstractinfo":"通过在已化学镀铜涤纶织物上电沉积非晶态 Ni-Fe-P 合金,制备出一种镀层致密均匀的柔性金属化屏蔽织物.研究和分析了电流密度、温度和 pH值对合金织物方阻值、增重率及屏蔽效能的影响,从而制定出最佳工艺.通过对比腐蚀前后非晶态 Ni-Fe-P合金和非晶态 Ni-P 合金镀层表面形貌、成分和电磁屏蔽效能可以得出,在电流密度为8．7 A/dm2,温度为60℃,pH 值＝1．5的工艺条件下所制备的非晶态 Ni-Fe-P 合金织物结晶更加细化、光亮,致密性和均质性都得以明显提高,并具有良好的耐腐蚀性能,且在300 kHz~1．5 GHz 频率范围内的电磁屏蔽效能达到了69．20~80．30 dB.","authors":[{"authorName":"张晓艺","id":"d00d8d1a-6927-4508-b32a-55d0da5c2554","originalAuthorName":"张晓艺"},{"authorName":"安振涛","id":"4e361505-3b18-4a0a-a494-5dee135f369f","originalAuthorName":"安振涛"},{"authorName":"<span style=\"color:red\">吴雪</span><span style=\"color:red\">艳</span>","id":"16382c29-7deb-4105-b192-204ad6ed7aa6","originalAuthorName":"吴雪艳"},{"authorName":"王维","id":"02ea7b84-63c5-4042-9324-f982ae96bad5","originalAuthorName":"王维"}],"doi":"10.3969/j.issn.1001-9731.2015.08.023","fpage":"8102","id":"090ca01e-6c15-417f-9c2d-54edc9a8b036","issue":"8","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"2bd3e237-8719-49ac-872e-87c56df5b3b0","keyword":"非晶态镍铁磷合金","originalKeyword":"非晶态镍铁磷合金"},{"id":"937616f9-fbd3-476b-9fd8-90918719b3bf","keyword":"屏蔽织物","originalKeyword":"屏蔽织物"},{"id":"286a4c75-9f23-4038-bf26-a972ff9ce328","keyword":"工艺优化","originalKeyword":"工艺优化"},{"id":"4789a606-6a3f-41be-87cf-0e9368b4749d","keyword":"耐腐蚀性","originalKeyword":"耐腐蚀性"}],"language":"zh","publisherId":"gncl201508023","title":"非晶态Ni-Fe-P合金屏蔽织物的工艺优化及耐蚀性研究","volume":"","year":"2015"},{"abstractinfo":"为进一步增大膨胀石墨的膨胀体积,用二次插入的方法制备了石墨层间化合物。首先用化学氧化法制备了膨胀体积为250 mL/g的可膨胀石墨,然后以膨胀体积为250 mL/g 的可膨胀石墨为原料,用二次插入的方法制备了膨胀体积为380 mL/g 的膨胀石墨。讨论了各种反应物比率、反应温度和反应时间对膨胀体积的影响。对制得的膨胀石墨进行了各种表征,XRD谱显示产物保持了天然石墨的层状晶体结构,但是产物的石墨层间距离增大。扫描电镜照片显示通过二次插入石墨层间确实被进一步打开。结果显示这种新的制备方法是可行的,它为纳米石墨材料的研究提供了新的思路。","authors":[{"authorName":"<span style=\"color:red\">吴雪</span><span style=\"color:red\">艳</span>","id":"a6a3c3ae-0cb2-43f2-ad81-72d60bbac32b","originalAuthorName":"吴雪艳"},{"authorName":"安振涛","id":"66f67c1b-10fd-4369-9596-ececdf183225","originalAuthorName":"安振涛"},{"authorName":"姚恺","id":"8f84dfac-5547-4b80-bf80-3358c0c4091d","originalAuthorName":"姚恺"},{"authorName":"傅孝忠","id":"72c00daf-ef2a-4f13-900a-e7dff296c410","originalAuthorName":"傅孝忠"},{"authorName":"李冀辉","id":"3e8b73c0-706b-4224-a284-906cb206ec0f","originalAuthorName":"李冀辉"}],"doi":"10.3969/j.issn.1001-9731.2014.Supplement(Ⅰ).028","fpage":"122","id":"360acea7-4629-435b-8610-c8ab112a37ad","issue":"z1","journal":{"abbrevTitle":"GNCL","coverImgSrc":"journal/img/cover/GNCL.jpg","id":"33","issnPpub":"1001-9731","publisherId":"GNCL","title":"功能材料"},"keywords":[{"id":"220ea91e-7942-4519-a828-9b7a51d4bf07","keyword":"石墨层间化合物","originalKeyword":"石墨层间化合物"},{"id":"68ad1920-7722-4128-ae81-30c72497b7ea","keyword":"石墨层状结构","originalKeyword":"石墨层状结构"},{"id":"27cc2f9c-4a67-429d-960f-28829fc72ba5","keyword":"氧化","originalKeyword":"氧化"}],"language":"zh","publisherId":"gncl2014z1028","title":"再次插入法制备超大膨胀体积石墨层间化合物","volume":"","year":"2014"},{"abstractinfo":"为了降解吸附弹药库房中的有害气体,以减少对保管人员及弹药的危害,分析了弹药库房中的有害气体来源及危害.讨论了TiO2特殊的光降解性能,以嵌入TiO2的膨胀石墨为填料,以聚氨酯清漆为粘结剂对弹药用涂料进行改性.对甲醛进行降解试验,验证了新型涂料有较好的降解能力和吸附能力.通过改性制备与试验证明:运用膨胀石墨为载体,纳米二氧化钛改性弹药用涂料的方法是可行的,新型涂料物化性能良好,具有较好的降解应用前景.","authors":[{"authorName":"<span style=\"color:red\">吴雪</span><span style=\"color:red\">艳</span>","id":"2e2d7332-2e93-422a-960c-ab14342eee2c","originalAuthorName":"吴雪艳"},{"authorName":"高欣宝","id":"72571729-d67c-426c-9232-785eddd9ea10","originalAuthorName":"高欣宝"},{"authorName":"姚恺","id":"f9b7f139-55e7-4925-b469-4b2b97de6173","originalAuthorName":"姚恺"},{"authorName":"王耀济","id":"17610a71-32b8-4afb-9273-c935ab33447c","originalAuthorName":"王耀济"}],"doi":"10.3969/j.issn.1001-3660.2008.06.009","fpage":"27","id":"3aadf08d-b59f-43c2-85c3-aa80c287fb66","issue":"6","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术   "},"keywords":[{"id":"5e0db3dd-bc43-4594-885d-811b226c67bd","keyword":"弹药","originalKeyword":"弹药"},{"id":"9ede1200-808d-4972-b55a-76acb2c93b03","keyword":"有害气体","originalKeyword":"有害气体"},{"id":"eeabe282-213f-4edb-bdc4-70b7948b5c30","keyword":"涂料","originalKeyword":"涂料"},{"id":"e77931f7-ad80-4aa4-8a20-ecc903412fdc","keyword":"降解","originalKeyword":"降解"}],"language":"zh","publisherId":"bmjs200806009","title":"纳米二氧化钛改性弹药用涂料的研究","volume":"37","year":"2008"},{"abstractinfo":"采用多种高温固相反应途径合成了纯相Ba<SUB>3</SUB>BPO<SUB>7</SUB>并研究了Ba<SUB>3</SUB>BPO<SUB>7</SUB>的水解和热稳定性能.研究表明:Ba<SUB>3</SUB>BPO<SUB>7</SUB>遇水水解,生成Ba<SUB>3</SUB>(PO<SUB>4</SUB>)<SUB>2</SUB>、Ba<SUB>5</SUB>(PO<SUB>4</SUB>)<SUB>3</SUB>OH和Ba(OH)<SUB>2</SUB>;TG-DTA表明它是一致熔化合物,熔点在1353℃左右;同时,初步研究了X射线激发Ba<SUB>3</SUB>BPO<SUB>7</SUB>:<EM>RE</EM>(<EM>RE</EM>=Eu<SUP>3+</SUP>、Sm<SUP>3+</SUP>)的发光性能,表明基质Ba<SUB>3</SUB>BPO<SUB>7</SUB>与稀土离子之间存在着能量传递.","authors":[{"authorName":"段成军","id":"513f2f10-ba4a-4a5b-a07a-f02d4c32bd5a","originalAuthorName":"段成军"},{"authorName":"<span style=\"color:red\">吴雪</span><span style=\"color:red\">艳</span>","id":"6e5861a5-8090-4c46-963a-34a326864e6c","originalAuthorName":"吴雪艳"},{"authorName":"陈昊鸿","id":"d3885c79-da6f-49b1-b645-d347b3acfbe8","originalAuthorName":"陈昊鸿"},{"authorName":"杨昕昕","id":"4302b299-e128-4386-b7cf-ad7f15801a22","originalAuthorName":"杨昕昕"},{"authorName":"赵景泰","id":"b599998b-7ccc-48c2-a58c-e36a34a4a3db","originalAuthorName":"赵景泰"}],"categoryName":"|","doi":"","fpage":"1043","id":"f3a52636-3efb-40b2-b74b-88ccdb456693","issue":"5","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":"1f153379-cf8f-4ead-9abe-f78ec8fa38c1","keyword":"碱土硼磷酸盐","originalKeyword":"碱土硼磷酸盐"},{"id":"f19b83b9-54d0-44af-9c4d-a07ea52885b4","keyword":" hydrolyzation","originalKeyword":" hydrolyzation"},{"id":"e3c1f291-54d4-410d-8802-fdded2e23efe","keyword":" X-ray excited luminescent properties","originalKeyword":" X-ray excited luminescent properties"}],"language":"zh","publisherId":"1000-324X_2005_5_1","title":"Ba<SUB>3</SUB>BPO<SUB>7</SUB>的合成及其水解、热稳定性和稀土掺杂发光性能的研究","volume":"20","year":"2005"},{"abstractinfo":"采用多种高温固相反应途径合成了纯相Ba3BPO7并研究了Ba3BPO7的水解和热稳定性能.研究表明:Ba3BPO7遇水水解,生成Ba3(PO4)2、Ba5(PO4)3OH和Ba(OH)2;TG-DTA表明它是一致熔化合物,熔点在1353℃左右;同时,初步研究了X射线激发Ba3BPO7:RE(RE=Eu3+、Sm3+)的发光性能,表明基质Ba3BPO7与稀土离子之间存在着能量传递.","authors":[{"authorName":"段成军","id":"77ddab54-9cb6-4274-b5de-b40d22aedb0e","originalAuthorName":"段成军"},{"authorName":"<span style=\"color:red\">吴雪</span><span style=\"color:red\">艳</span>","id":"61a88859-fd62-4e86-92d4-387bb8849607","originalAuthorName":"吴雪艳"},{"authorName":"陈昊鸿","id":"6236deff-64a3-46b6-bca8-a9ee913f510c","originalAuthorName":"陈昊鸿"},{"authorName":"杨昕昕","id":"2c2dae25-184c-443d-ae1b-a6e1bd9ba82f","originalAuthorName":"杨昕昕"},{"authorName":"赵景泰","id":"38adc489-fd7a-46a8-b7d9-0daf5b49cc6f","originalAuthorName":"赵景泰"}],"doi":"10.3321/j.issn:1000-324X.2005.05.004","fpage":"1043","id":"9d198563-f0c7-4d80-ae9d-00e9d5572ee3","issue":"5","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":"db33815f-90a7-4791-a1c3-65a0fbdd08c9","keyword":"碱土硼磷酸盐","originalKeyword":"碱土硼磷酸盐"},{"id":"6b88e406-d76e-4168-b717-11e6369b7503","keyword":"水解","originalKeyword":"水解"},{"id":"10954cd1-346d-4312-8eba-5f844858aa8a","keyword":"发光性能","originalKeyword":"发光性能"}],"language":"zh","publisherId":"wjclxb200505004","title":"Ba3BPO7的合成及其水解、热稳定性和稀土掺杂发光性能的研究","volume":"20","year":"2005"},{"abstractinfo":"以活性<span style=\"color:red\">艳</span>橙溶液为模拟废水,通过H2O2/TiO2超声(US)协同作用光降解活性<span style=\"color:red\">艳</span>橙溶液,探讨了TiO2催化剂用量、H2O2用量、活性<span style=\"color:red\">艳</span>橙溶液的初始浓度、pH值、TiO2催化剂锻烧温度等对活性<span style=\"color:red\">艳</span>橙溶液降解率的影响,并比较了几种不同作用方式对活性<span style=\"color:red\">艳</span>橙溶液的降解效果.结果表明:UV/H2O2/TiO2/US协同作用降解活性<span style=\"color:red\">艳</span>橙溶液的效果最好;当活性<span style=\"color:red\">艳</span>橙溶液的初始浓度为20 mg·L-1,pH＝5,TiO2用量为0.4 g·L-1,H2O2用量为0.4 ml·L-1时,降解率可达92.06%.","authors":[{"authorName":"陈芳","id":"c018b667-4b1a-4338-b385-2d4c125d64b8","originalAuthorName":"陈芳"},{"authorName":"易回阳","id":"7008f390-2bc9-4a87-b6ed-71777a8de22a","originalAuthorName":"易回阳"},{"authorName":"吴一鸣","id":"bf3d8c22-2232-46d8-8102-d586676d01f0","originalAuthorName":"吴一鸣"}],"doi":"","fpage":"230","id":"b15922b8-beeb-4a39-9990-eeb51b375572","issue":"3","journal":{"abbrevTitle":"YXKXYGHX","coverImgSrc":"journal/img/cover/YXKXYGHX.jpg","id":"74","issnPpub":"1674-0475","publisherId":"YXKXYGHX","title":"影像科学与光化学   "},"keywords":[{"id":"88a482ad-2c4f-4805-8a02-a613239277fb","keyword":"超声波","originalKeyword":"超声波"},{"id":"dc948252-a79c-4d4a-9236-5ae4192b8f72","keyword":"TiO2","originalKeyword":"TiO2"},{"id":"d7b25bb4-ef3f-4423-a23b-6a3ab0c3ac88","keyword":"协同作用","originalKeyword":"协同作用"},{"id":"b41f2468-584b-4018-ac2c-90b0366a1c28","keyword":"活性<span style=\"color:red\">艳</span>橙","originalKeyword":"活性艳橙"},{"id":"510604c2-b4ac-4dd0-9b95-2ca3d2b4fc0b","keyword":"降解","originalKeyword":"降解"}],"language":"zh","publisherId":"ggkxyghx201003008","title":"H2O2/TiO2超声协同光降解活性<span style=\"color:red\">艳</span>橙的研究","volume":"28","year":"2010"},{"abstractinfo":"通过静态吸附实验方法,研究了有机改性凹凸棒石吸附活性<span style=\"color:red\">艳</span>蓝KN-R的动力学行为.研究结果表明:准二级动力学模型能很好地描述活性<span style=\"color:red\">艳</span>蓝KN-R在有机改性凹凸棒石上的动力学行为,平衡吸附量q2随着KN-R初始浓度、振荡速度、温度的增加而增加.有机改性凹凸棒石吸附活性<span style=\"color:red\">艳</span>蓝KN-R主要是外表面吸附,吸附活化能为39.2 kJ/mol,说明其为物理吸附、化学吸附综合作用的过程,其速率由化学过程与外扩散共同控制.","authors":[{"authorName":"张波","id":"f9714a14-4182-4326-b828-5048e81c1590","originalAuthorName":"张波"},{"authorName":"彭书传","id":"ee74e18c-2c8d-444d-b77e-7d7cc30a323f","originalAuthorName":"彭书传"},{"authorName":"王世亮","id":"2081aac6-56de-48dc-afb0-2a3156bf3ad2","originalAuthorName":"王世亮"},{"authorName":"张泽滨","id":"93899ca6-0450-415a-ace0-d2cad41cd09c","originalAuthorName":"张泽滨"},{"authorName":"吴敏伟","id":"7bd933ae-1226-4ef6-b7a1-c107f72d1daf","originalAuthorName":"吴敏伟"}],"doi":"","fpage":"122","id":"2ad6a218-c793-44a4-af6f-213768c81239","issue":"4","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"14b91fae-876a-4a73-aed5-77891101763e","keyword":"有机改性","originalKeyword":"有机改性"},{"id":"1314339a-4fe8-4996-83a2-feff1221503c","keyword":"凹凸棒","originalKeyword":"凹凸棒"},{"id":"35569aab-9a77-4074-b7c3-dbfeb611ffe3","keyword":"吸附","originalKeyword":"吸附"},{"id":"acbdf65e-ed32-4155-a86c-5a7cc298153f","keyword":"活性<span style=\"color:red\">艳</span>蓝KN-R","originalKeyword":"活性艳蓝KN-R"},{"id":"6d9a6b9d-9b2e-48a1-bd3d-bd6a2a787f27","keyword":"动力学","originalKeyword":"动力学"}],"language":"zh","publisherId":"cldb201304031","title":"有机改性凹凸棒石吸附活性<span style=\"color:red\">艳</span>蓝KN-R的动力学研究","volume":"27","year":"2013"},{"abstractinfo":"采用湿相转化法制备了以活性<span style=\"color:red\">艳</span>蓝KN-R为印迹分子的醋酸纤维素(CA)-聚偏二氟乙烯(PVDF)分子印迹膜(MIM).实验结果表明在一定的制备条件下可制得具有较大吸附结合率的MIM,此时的铸膜液组成为:活性<span style=\"color:red\">艳</span>蓝KN-R质量浓度硼ω1为0.1%,共混组成比ω(CA):ω(PVDF)=9.5:0.5,聚合物质量浓度ωp,为14%,添加剂LiCl质量浓度ωa为7.5%.所制得的MIM是一种特异分子吸附膜,对印迹分子具有亲和性,其分离机理属于延迟渗透机理.在一定范围(0～0.1%)内,随着印迹分子活性<span style=\"color:red\">艳</span>蓝KN-R质量浓度增大,MIM的吸附选择性提高.由吸附焓△H0及MIM与印迹分子间结合力强弱的测定结果可知,MIM与印迹分子之间的结合作用力以疏水/范德华力与氢键作用为主.","authors":[{"authorName":"李婧娴","id":"adc39f6d-454c-4444-b471-9abaf319eb20","originalAuthorName":"李婧娴"},{"authorName":"董声雄","id":"974c9bac-83ba-4efc-8746-ddffb5b2a98e","originalAuthorName":"董声雄"},{"authorName":"苗晶","id":"40757d46-48bb-449f-a6f5-b995922abdcb","originalAuthorName":"苗晶"}],"doi":"10.3969/j.issn.1007-8924.2009.01.002","fpage":"8","id":"00fd3ec0-448e-4ff2-a4bf-8e3a505411fa","issue":"1","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":"ab540a8e-4a22-4c27-9032-8794df61b554","keyword":"湿相转化法","originalKeyword":"湿相转化法"},{"id":"f919dd35-564c-46a0-8918-ae39230d5374","keyword":"活性<span style=\"color:red\">艳</span>蓝KN-R","originalKeyword":"活性艳蓝KN-R"},{"id":"034d028a-41f9-48db-b3e0-c9cfdc9d8c26","keyword":"分子印迹膜(MIM)","originalKeyword":"分子印迹膜(MIM)"},{"id":"f3c4f724-a1ba-4f6c-998c-93cc8914abec","keyword":"共混膜","originalKeyword":"共混膜"}],"language":"zh","publisherId":"mkxyjs200901002","title":"活性<span style=\"color:red\">艳</span>蓝KN-R分子印迹CA/PVDF共混膜的制备及性能表征","volume":"29","year":"2009"},{"abstractinfo":"采用溶胶-凝胶法制备了不掺杂和掺杂铝离子、镧离子以及两种离子共掺杂的ZnO,并用X射线衍射(XRD),高分辨透射电镜(HRTEM),紫外-可见(UV-Vis)吸收光谱对其进行了表征.用紫外灯作为光源,一定浓度的活性<span style=\"color:red\">艳</span>蓝X-BR溶液为光催化反应模型污染物,研究了各种离子掺杂ZnO的光催化性能,考察了掺杂量对降解率的影响.结果表明,镧离子和铝离子掺杂浓度为2 at%和3 at%的共搀杂ZnO的光催化性能最好;在室温下,加入催化剂浓度为0.1 g/L,降解时间为45 min时,对活性<span style=\"color:red\">艳</span>蓝X-BR溶液的降解率达到96.63%.","authors":[{"authorName":"周银","id":"490f2150-e783-47a1-8704-d2f879571574","originalAuthorName":"周银"},{"authorName":"王宇","id":"9889757b-2987-4b5e-83bb-e106ffd7f6a1","originalAuthorName":"王宇"},{"authorName":"卢士香","id":"8f1b321e-def4-42df-9c69-db5772180c51","originalAuthorName":"卢士香"},{"authorName":"徐文国","id":"3d5fd658-3b2e-4813-b421-3c76f27b6af4","originalAuthorName":"徐文国"},{"authorName":"苏苏","id":"a70d8526-7852-4b5e-883c-6555b9987294","originalAuthorName":"苏苏"}],"doi":"","fpage":"998","id":"6ec05008-600c-430c-90c0-d112e4b2ec7d","issue":"4","journal":{"abbrevTitle":"RGJTXB","coverImgSrc":"journal/img/cover/RGJTXB.jpg","id":"57","issnPpub":"1000-985X","publisherId":"RGJTXB","title":"人工晶体学报"},"keywords":[{"id":"e960863a-1c4b-48e3-9edd-d7d235e981ea","keyword":"溶胶-凝胶","originalKeyword":"溶胶-凝胶"},{"id":"eac95f4b-6141-422d-bc5f-f6bcf0341d93","keyword":"纳米氧化锌","originalKeyword":"纳米氧化锌"},{"id":"3cc63b6d-1577-4565-bd8c-a1ef019394f0","keyword":"光催化降解","originalKeyword":"光催化降解"},{"id":"7b88e351-38b3-48ee-96b5-d6da24950946","keyword":"镧铝共掺杂","originalKeyword":"镧铝共掺杂"}],"language":"zh","publisherId":"rgjtxb98200904041","title":"La3+,Al3+共掺杂纳米ZnO光催化降解活性<span style=\"color:red\">艳</span>蓝X-BR研究","volume":"38","year":"2009"},{"abstractinfo":"按nAl2O3:nSiO2∶ nNaO∶ nH2O=1∶14∶ 6∶250的摩尔比,100℃10 h水热合成出微孔NaY分子筛,按n(SiO2)∶n(CTAB)∶n(H2O)=0.6∶1∶30的摩尔比配制成MCM48的溶胶液,再将NaY混合到MCM-48的晶化液中,110℃晶化72 h后取出漂洗烘干,再在550℃焙烧去除有机模板剂,获得NaY/MCM-48微介孔复合分子筛,采用XRD、SEM和TEM等手段对合成分子筛进行了表征.考查了分子筛的投加量、pH值、温度、吸附时间等对吸附活性<span style=\"color:red\">艳</span>兰KN-R染料废水脱色率的影响,研究了三种分子筛对活性<span style=\"color:red\">艳</span>兰的吸附等温线,吸附动力学和热力学.研究结果表明:NaY/MCM-48微介孔复合分子筛,对活性<span style=\"color:red\">艳</span>兰KN-R的吸附效果较好,当NaY/MCM-41微介孔复合分子筛的投加量为0.3 g/L、活性<span style=\"color:red\">艳</span>兰KN-R染料浓度20 mg/L,溶液pH =4、吸附时间为60 min,温度为55℃时吸附结果最好,脱色率以达到了96.6％.这三种分子筛可用Langmuir和Freundlich等温吸附方程描述,其中NaY,MCM-48分子筛与Freundlich等温吸附方程具有更好的相关性,而NaY/MCM--48复合分子筛与Langmuir等温吸附方程具有更好的相关性;拟二级吸附动力学反应模型与实验数据之间有更好的相关性,可以用方程lnK=-△H/RT+ lnCe来进行拟合.","authors":[{"authorName":"李聪","id":"18e0a899-6716-41af-b8d8-c5ff5deb4cbf","originalAuthorName":"李聪"},{"authorName":"成岳","id":"e7cd3727-367d-4252-9de4-9656d06f6012","originalAuthorName":"成岳"},{"authorName":"马朝云","id":"09a6b6a3-6937-4239-b563-2ed76cf9f14c","originalAuthorName":"马朝云"},{"authorName":"刘宇","id":"c5fef559-8e92-412f-b0f4-99dc3f269a96","originalAuthorName":"刘宇"}],"doi":"","fpage":"529","id":"fcd42162-ef1b-49cc-bc91-0570774256c1","issue":"2","journal":{"abbrevTitle":"GSYTB","coverImgSrc":"journal/img/cover/GSYTB.jpg","id":"36","issnPpub":"1001-1625","publisherId":"GSYTB","title":"硅酸盐通报   "},"keywords":[{"id":"27869a04-69bc-4d7b-b98a-ca219eee6f01","keyword":"NaY/MCM-48复合分子筛","originalKeyword":"NaY/MCM-48复合分子筛"},{"id":"72742597-8f43-4e20-b6f2-308cbd02cc00","keyword":"活性<span style=\"color:red\">艳</span>兰KN-R染料","originalKeyword":"活性艳兰KN-R染料"},{"id":"b1dcc73c-02ba-43c1-881d-3e0867e147b2","keyword":"脱色率","originalKeyword":"脱色率"},{"id":"d5f98ce5-4693-4186-b9e8-46315ec4a2fa","keyword":"吸附等温线","originalKeyword":"吸附等温线"},{"id":"8127dcbe-bc00-4859-a26c-84d967d5ac35","keyword":"动力学和热力学","originalKeyword":"动力学和热力学"}],"language":"zh","publisherId":"gsytb201602035","title":"NaY/MCM-48复合分子筛的制备及对活性<span style=\"color:red\">艳</span>兰KN-R染料的吸附性能研究","volume":"35","year":"2016"}],"totalpage":3,"totalrecord":22}