Steady-state properties of single-file systems with conversion

Abstract: We have used Monte Carlo methods and analytical techniques to investigate the influence of the characteristic parameters, such as pipe length, diffusion, adsorption, desorption, and reaction rate constants on the steady-state properties of single-file systems with a reaction. We looked at cases when all the sites are reactive and when only some of them are reactive. Comparisons between mean-field predictions and Monte Carlo simulations for the occupancy profiles and reactivity are made. Substantial differences… Show more

“…An exact description of our discrete reaction-diffusion model is provided by the master equations for the evolution of probabilities of various configurations within the pore. Often these are written in hierarchical form [8,11,[12][13][14]. Here, we use <C n > to denote the probability or ensemble averaged concentration for species C = A or B at site n, <C n E n+1 > for the probability that C is at site n and for site n+1 to be empty (E), etc.…”

“…A simple MF factorization approximation, <C n E n+1 >  <C n ><E n+1 >, etc., produces a closed set of discrete reaction-diffusion equations (dRDE) for single-site concentrations. A higher-level pair approximation retains pair quantities, but factorizes triplets, e.g., <C n M n+1 N n+2 >  <C n M n+1 ><M n+1 N n+2 >/<M n+1 >, with C, M, N = A, B, or E. This generates a closed set of equations for single-site and pair quantities [8,11,[12][13][14].…”

“…For AB conversion in the case where all sites are catalytic, one has that [12][13][14] . In (1), we have defined the discrete derivative, K n = K n -K n-1 .…”

“…In the steady state, sites are randomly occupied by particles, X, with probability X eq = <X out > [12].…”

“…Passing of A with other A (or B with B) is not significant. Several previous analyses exist for the case of single-file diffusion [8][9][10][11][12][13][14][15] revealing that reactivity is strongly localized near the pore openings in this case of no-passing [9]. A perception exists that a simple mean-field (MF) type treatment of chemical diffusion (see below) is adequate [11].…”

Conversion Reactions in Surface-Functionalized Mesoporous Materials: Effect of Restricted Transport and Catalytic Site Distribution

“…An exact description of our discrete reaction-diffusion model is provided by the master equations for the evolution of probabilities of various configurations within the pore. Often these are written in hierarchical form [8,11,[12][13][14]. Here, we use <C n > to denote the probability or ensemble averaged concentration for species C = A or B at site n, <C n E n+1 > for the probability that C is at site n and for site n+1 to be empty (E), etc.…”

“…A simple MF factorization approximation, <C n E n+1 >  <C n ><E n+1 >, etc., produces a closed set of discrete reaction-diffusion equations (dRDE) for single-site concentrations. A higher-level pair approximation retains pair quantities, but factorizes triplets, e.g., <C n M n+1 N n+2 >  <C n M n+1 ><M n+1 N n+2 >/<M n+1 >, with C, M, N = A, B, or E. This generates a closed set of equations for single-site and pair quantities [8,11,[12][13][14].…”

“…For AB conversion in the case where all sites are catalytic, one has that [12][13][14] . In (1), we have defined the discrete derivative, K n = K n -K n-1 .…”

“…In the steady state, sites are randomly occupied by particles, X, with probability X eq = <X out > [12].…”

“…Passing of A with other A (or B with B) is not significant. Several previous analyses exist for the case of single-file diffusion [8][9][10][11][12][13][14][15] revealing that reactivity is strongly localized near the pore openings in this case of no-passing [9]. A perception exists that a simple mean-field (MF) type treatment of chemical diffusion (see below) is adequate [11].…”

Conversion Reactions in Surface-Functionalized Mesoporous Materials: Effect of Restricted Transport and Catalytic Site Distribution

Kinetic Monte Carlo

Single‐File Diffusion