Kinetic molecular sieving, thermodynamic and structural aspects of gas/vapor sorption on metal organic framework [Ni1.5(4,40-bipyridine)1.5(H3L)- (H2O)3][H2O]7 where H6L =2,4,6-trimethylbenzene- 1,3,5-triyl tris(methylene)triphosphonic acid
作者:Xuebo Zhao,a Jon G. Bell,b Si-Fu Tang,*c Liangjun Lia and K. Mark Thomas
關鍵字:gas/vapor sorption
論文來源:期刊
具體來源:J. Mater. Chem. A, 2016, 4, 1353
發表時間:2016年
A metal organic framework [Ni1.5(4,40-bipy)1.5(H3L)(H2O)3]$[H2O]7 where H6L ? 2,4,6-trimethylbenzene-
1,3,5-triyl tris(methylene)triphosphonic acid and 4,40-bipy ? 4,40-bipyridine has been prepared. The
structures of [Ni1.5(4,40-bipy)1.5(H3L)(H2O)3]$[H2O]7 and the desolvated form [Ni1.5(4,40-bipy)1.5(H3L)(H2O)3]
have been determined by single crystal X-ray diffraction and the framework structures are virtually
identical with the former having disordered water molecules in the pores. The framework structure
comprises of two-dimensional Ni1.5(H3L) layers and 4,40-bipy linkers acting as pillars with an unusual
framework topology of a (3, 3, 6) net that can be denoted as: {4$62}2{63}2{68$85$102}. The framework has
one-dimensional channels decorated with acidic O–H groups with irregular shape varying from narrow
windows (cross section: 4.2 � 4.2 °A) to pore cavities (diameter: �12 °A). Thermogravimetric studies
showed that both coordinated and lattice water molecules adsorbed in pores were removed in ultrahigh
vacuum to give [Ni1.5(4,40-bipy)1.5(H3L)]. The water vapor adsorption isotherm for [Ni1.5(4,40-
bipy)1.5(H3L)] showed that 3 coordinated and �7 pore lattice water molecules were adsorbed and the
framework structure was reformed. The desorption isotherm showed that the lattice water was easily
desorbed in vacuum at 20 �C to form [Ni1.5(4,40-bipy)1.5(H3L)(H2O)3]. The ethanol adsorption isotherms
for [Ni1.5(4,40-bipy)1.5(H3L)] for temperature range 20–50 �C were markedly hysteretic. The stoichiometry
was [Ni1.5(4,40-bipy)1.5(H3L)]$[1.11C2H5OH] at p/p0 ? 0.97 and 20 �C gave a total pore volume
approximately half that of [Ni1.5(4,40-bipy)1.5(H3L)(H2O)3]. The desorption isotherms show that ethanol is
strongly retained with decreasing pressure indicating a stable framework structure. The kinetic profiles
for oxygen, nitrogen, carbon dioxide, and water and ethanol vapors, can be described by Fickian,
combined barrier resistance/diffusion (CBRD), and stretched exponential models for both adsorption and
desorption. Gas adsorption studies for [Ni1.5(4,40-bipy)1.5(H3L)] reveal kinetic molecular sieving occurs
with very high kinetic selectivity for O2/N2 at 0 �C. Carbon dioxide adsorption has intermediate rates of
adsorption between oxygen and nitrogen. The isosteric enthalpy for CO2 adsorption at zero surface
coverage was 30.7 � 2.4 kJ mol�1. The corresponding activation energy for diffusion of CO2 into the
framework was �48 kJ mol�1. Narrow constrictions in the porous structure of [Ni1.5(4,40-bipy)1.5(H3L)]
give rise to kinetic molecular sieving effects and do not allow adsorption of molecules such as methane,
which has a larger cross-section. The selectivity for CO2/CH4 was very high (x1000) at 30 �C. The
adsorption results are discussed in terms of diffusion, thermodynamics and surface interactions in pores.