Dynamic Monte Carlo reactor modeling of calcium looping with sorbent purge and utilization decay

This work presents a new dynamic modelling approach for calcium looping systems that allows explicit sorbent deactivation and purge/makeup. These are common in plant operations, but often neglected in modelling. This model adopts a Monte Carlo approach, tracking merely 100 particles between the carbonator and the calciner for 60 reaction cycles with the particle residence time in each reactor determined stochastically. The simulated results agree well with the experimental data in both the transient and steady-state stages. This model provides a promising approach to predicting the dynamic behaviour of calcium looping systems under relatively realistic conditions at low computational cost. The stochastic description of a multiphase reactor via the Monte Carlo process can be widely adapted in various scenarios.

Dynamic Monte Carlo reactor modeling of calcium looping with sorbent purge and utilization decay

A Combination Technique for Optimal Control Problems Constrained by Random PDEs

Stochastic adaptive resampling for the estimation of discrete choice models

Controlling morpho-electrophysiological variability of neurons with detailed biophysical models

Stochastic adaptive resampling for the estimation of discrete choice models

A Combination Technique for Optimal Control Problems Constrained by Random PDEs

Controlling morpho-electrophysiological variability of neurons with detailed biophysical models