低温与超导
低溫與超導
저온여초도
CRYOGENICS AND SUPERCONDUCTIVITY
2010年
1期
80-84
,共5页
郑青榕%蔡振雄%陈武%戴乐阳
鄭青榕%蔡振雄%陳武%戴樂暘
정청용%채진웅%진무%대악양
活性炭%吸附%孔径分布%密度泛函理论
活性炭%吸附%孔徑分佈%密度汎函理論
활성탄%흡부%공경분포%밀도범함이론
Activated carbon%Adsorption%Pore size distribution%Density functional theory
为提高由NLDFT计算值确定活性炭孔径分布(PSD)的精度,根据测得的77K氮在非石墨化碳黑BP460和椰壳活性炭K05上的吸附数据,比较了吸附空间及壁面结构采取不同假设对计算结果的影响.结果表明,常规将活性炭吸附空间近似为无限尺寸的石墨化碳黑表面构成的狭缝孔,并由Lorenz-Berthelot混合法则确定相互作用参数,计算值在较低压力区域和试验值之间的偏差明显;而将吸附壁面结构近似为非石墨化碳黑,并由表面粗糙度和石墨晶格分布的误差函数修正相互作用参数后,计算结果和试验值吻合良好.分析结果时发现,归一化方法和考虑周边吸附质分子作用的加权函数是影响NLDFT计算结果准确性的关键因素.
為提高由NLDFT計算值確定活性炭孔徑分佈(PSD)的精度,根據測得的77K氮在非石墨化碳黑BP460和椰殼活性炭K05上的吸附數據,比較瞭吸附空間及壁麵結構採取不同假設對計算結果的影響.結果錶明,常規將活性炭吸附空間近似為無限呎吋的石墨化碳黑錶麵構成的狹縫孔,併由Lorenz-Berthelot混閤法則確定相互作用參數,計算值在較低壓力區域和試驗值之間的偏差明顯;而將吸附壁麵結構近似為非石墨化碳黑,併由錶麵粗糙度和石墨晶格分佈的誤差函數脩正相互作用參數後,計算結果和試驗值吻閤良好.分析結果時髮現,歸一化方法和攷慮週邊吸附質分子作用的加權函數是影響NLDFT計算結果準確性的關鍵因素.
위제고유NLDFT계산치학정활성탄공경분포(PSD)적정도,근거측득적77K담재비석묵화탄흑BP460화야각활성탄K05상적흡부수거,비교료흡부공간급벽면결구채취불동가설대계산결과적영향.결과표명,상규장활성탄흡부공간근사위무한척촌적석묵화탄흑표면구성적협봉공,병유Lorenz-Berthelot혼합법칙학정상호작용삼수,계산치재교저압력구역화시험치지간적편차명현;이장흡부벽면결구근사위비석묵화탄흑,병유표면조조도화석묵정격분포적오차함수수정상호작용삼수후,계산결과화시험치문합량호.분석결과시발현,귀일화방법화고필주변흡부질분자작용적가권함수시영향NLDFT계산결과준학성적관건인소.
For improving the accuracy of PSD of the activated carbon determined by non-local density functional theory (NLDFT), adsorption isotherms of nitrogen at 77K on non-graphitized thermal carbon black BP460 and activated carbon were measured to evaluate the interaction parameters of fluid-fluid and fluid-solid. Results show that using a graphitized thermal carbon black as a reference system and fitting parameters by Lorenz-Berthelot mixing rule bring about a poor correlation between the results from experiment and the theory, however good correlations occur if the pore wall surface of the activated carbon is identical to a non-graphitized carbon black. Results also reveal that introduction of the surface roughness and the error function for the dispersion of the solid mass are beneficial to the accurate determination of interaction parameters. Conclusions are drawn that regularization method for determining the parameters from experimental adsorption isotherms is crucial to the accuracy of fluid-solid potentials, and those fitted under a reference system of a non-graphitized carbon black can be used to model adsorption in slit pores and generate a set of local isotherms, which can accordingly be used to determine the PSD function of activated carbon.