高校化学工程学报
高校化學工程學報
고교화학공정학보
JOURNAL OF CHEMICAL ENGINEERING OF CHINESE UNIVERSITIES
2015年
1期
72-77
,共6页
程亮%侯翠红%刘国际%张保林
程亮%侯翠紅%劉國際%張保林
정량%후취홍%류국제%장보림
纳米腐植酸%吸附性能%热力学%动力学%镉离子
納米腐植痠%吸附性能%熱力學%動力學%鎘離子
납미부식산%흡부성능%열역학%동역학%력리자
nanoscale humic acid%adsorption performance%thermodynamics%kinetics%cadmuim ions
研究了采用碱溶酸析法配加高剪切技术制备的纳米腐植酸对重金属镉离子的吸附性能,用原子力显微镜(AFM)、红外光谱(FT-IR)、扫描电子显微镜(SEM)、比表面积测试仪(BET)等对纳米腐植酸进行表征,绘制了静态平衡吸附等温线及吸附动力学曲线。实验结果表明:吸附剂纳米腐植酸对镉离子的吸附较符合Freundlich模型,在288~308 K温度下,吸附焓变?H =24.22 kJ?mol?1,表明吸附是吸热过程,吸附动力学符合HO二级吸附速率方程,反应的表观活化能Ea=25.58 kJ?mol?1,表明纳米腐植酸对重金属离子的吸附是化学反应控制,而非扩散所控。吸附剂纳米腐植酸解吸再生循环使用5次后,Cd2+的吸附容量仅减少18.9%,说明该吸附剂具有较好的解吸再生性能。
研究瞭採用堿溶痠析法配加高剪切技術製備的納米腐植痠對重金屬鎘離子的吸附性能,用原子力顯微鏡(AFM)、紅外光譜(FT-IR)、掃描電子顯微鏡(SEM)、比錶麵積測試儀(BET)等對納米腐植痠進行錶徵,繪製瞭靜態平衡吸附等溫線及吸附動力學麯線。實驗結果錶明:吸附劑納米腐植痠對鎘離子的吸附較符閤Freundlich模型,在288~308 K溫度下,吸附焓變?H =24.22 kJ?mol?1,錶明吸附是吸熱過程,吸附動力學符閤HO二級吸附速率方程,反應的錶觀活化能Ea=25.58 kJ?mol?1,錶明納米腐植痠對重金屬離子的吸附是化學反應控製,而非擴散所控。吸附劑納米腐植痠解吸再生循環使用5次後,Cd2+的吸附容量僅減少18.9%,說明該吸附劑具有較好的解吸再生性能。
연구료채용감용산석법배가고전절기술제비적납미부식산대중금속력리자적흡부성능,용원자력현미경(AFM)、홍외광보(FT-IR)、소묘전자현미경(SEM)、비표면적측시의(BET)등대납미부식산진행표정,회제료정태평형흡부등온선급흡부동역학곡선。실험결과표명:흡부제납미부식산대력리자적흡부교부합Freundlich모형,재288~308 K온도하,흡부함변?H =24.22 kJ?mol?1,표명흡부시흡열과정,흡부동역학부합HO이급흡부속솔방정,반응적표관활화능Ea=25.58 kJ?mol?1,표명납미부식산대중금속리자적흡부시화학반응공제,이비확산소공。흡부제납미부식산해흡재생순배사용5차후,Cd2+적흡부용량부감소18.9%,설명해흡부제구유교호적해흡재생성능。
Nanoscale humic acid was prepared by alkali-solution/acid-isolation together with high shearing methods, which was used in the adsorption of cadmium ions. The prepared acid was characterized by means of AFM, FT-IR, SEM and BET, and the static equilibrium adsorption isotherm and adsorption kinetic curves were obtained. The results show that the adsorption process follows the Freundlich isothermal adsorption model. The enthalpy change at temperatures of 288~308 K is 24.22 kJ·mol–1, which suggests that adsorption process is endo-thermic. The adsorption kinetics follows the psendo-second-order equation and the apparent activition energy is 25.58 kJ·mol–1. This result indicates that the adsorption process is chemical reaction controlled rather than diffusion controlled. The adsorption capacity decreases 18.9% after 5 times of acid reusing and this result demonstrates that the adsorbent has good regenerability.
