功能材料
功能材料
공능재료
JOURNAL OF FUNCTIONAL MATERIALS
2014年
10期
10113-10118
,共6页
李凯斌%沈一丁%费贵强%李仲谨
李凱斌%瀋一丁%費貴彊%李仲謹
리개빈%침일정%비귀강%리중근
β-环糊精%磁性微球%阴离子%吸附%动力学
β-環糊精%磁性微毬%陰離子%吸附%動力學
β-배호정%자성미구%음리자%흡부%동역학
β-cyclodextrin%magnetic microspheres%anion%adsorption%kinetics
采用β-环糊精(β-CD)、FeCl2、Fe2(SO4)3、Na3 P3 O9等为主要原料,制备了阴离子β-CD 磁性微球(β-CDM),通过 X射线衍射、扫描电镜、粒度和热重等对其进行表征、测试,采用原子吸收光谱研究其吸附性能。结果表明,β-CDM 呈规整球形,平均粒径为93.5μm,热性能随Fe3 O4的引入得以提高,对 Cu2+、Mn2+和Zn2+的吸附具有选择性,对 Mn2+的吸附量最大,除去率达到98.59%。准二级吸附动力学模拟结果表明,β-CDM对Cu2+、Mn2+、Zn2+的吸附速率常数K2(g/(mg·min))可分别达到0.1851,0.1068,0.1584,对Cu2+吸附达平衡时所需时间最短。循环使用研究表明,β-CDM在磁场作用下具有较好的分离和循环使用性能。
採用β-環糊精(β-CD)、FeCl2、Fe2(SO4)3、Na3 P3 O9等為主要原料,製備瞭陰離子β-CD 磁性微毬(β-CDM),通過 X射線衍射、掃描電鏡、粒度和熱重等對其進行錶徵、測試,採用原子吸收光譜研究其吸附性能。結果錶明,β-CDM 呈規整毬形,平均粒徑為93.5μm,熱性能隨Fe3 O4的引入得以提高,對 Cu2+、Mn2+和Zn2+的吸附具有選擇性,對 Mn2+的吸附量最大,除去率達到98.59%。準二級吸附動力學模擬結果錶明,β-CDM對Cu2+、Mn2+、Zn2+的吸附速率常數K2(g/(mg·min))可分彆達到0.1851,0.1068,0.1584,對Cu2+吸附達平衡時所需時間最短。循環使用研究錶明,β-CDM在磁場作用下具有較好的分離和循環使用性能。
채용β-배호정(β-CD)、FeCl2、Fe2(SO4)3、Na3 P3 O9등위주요원료,제비료음리자β-CD 자성미구(β-CDM),통과 X사선연사、소묘전경、립도화열중등대기진행표정、측시,채용원자흡수광보연구기흡부성능。결과표명,β-CDM 정규정구형,평균립경위93.5μm,열성능수Fe3 O4적인입득이제고,대 Cu2+、Mn2+화Zn2+적흡부구유선택성,대 Mn2+적흡부량최대,제거솔체도98.59%。준이급흡부동역학모의결과표명,β-CDM대Cu2+、Mn2+、Zn2+적흡부속솔상수K2(g/(mg·min))가분별체도0.1851,0.1068,0.1584,대Cu2+흡부체평형시소수시간최단。순배사용연구표명,β-CDM재자장작용하구유교호적분리화순배사용성능。
In this paper,anionicβ-cyclodextrin magnetic microsphere (β-CDM)was prepared by usingβ-CD, FeCl2 ,Fe2 (SO4 )3 and Na3 P3 O9 as main materials.The characterization and performance tests such as X-ray diffraction (XRD),scanning electron microscope (SEM),particle size analysis,TGA and atomic absorption spectroscopy were further studied.The results show the morphology ofβ-CDM presents regular spherical and the average particle size was 93.5μm.Thermal performance increases with increasing Fe3 O4 content.It demon-strates elective adsorption for Cu2+,Mn2+ and Zn2+.The maximum removal rate of Mn2+ reaches 98.59%. The simulation results by quasi secondary adsorption kinetics show that the adsorption rate constant K 2 (g/(mg ·min))for Cu2+,Zn2+,Mn2+ can reach 0.1851,0.1068,0.1584,respectively.And it takes the shortest time for Cu2+ to reach equilibrium.What’s more,recycle studies show thatβ-CDM was in favor of separation and regenerate under the magnetic field.