posted on 2018-07-19, 00:00authored byMáté Erdős, Martijn F. de Lange, Freek Kapteijn, Othonas A. Moultos, Thijs J. H. Vlugt
A computational screening
of 2930 experimentally synthesized metal–organic
frameworks (MOFs) is carried out to find the best-performing structures
for adsorption-driven cooling (AC) applications with methanol and
ethanol as working fluids. The screening methodology consists of four
subsequent screening steps for each adsorbate. At the end of each
step, the most promising MOFs for AC application are selected for
further investigation. In the first step, the structures are selected
on the basis of physical properties (pore limiting diameter). In each
following step, points of the adsorption isotherms of the selected
structures are calculated from Monte Carlo simulations in the grand-canonical
ensemble. The most promising MOFs are selected on the basis of the
working capacity of the structures and the location of the adsorption
step (if present), which can be related to the applicable operational
conditions in AC. Because of the possibility of reversible pore condensation
(first-order phase transition), the mid-density scheme is used to
efficiently and accurately determine the location of the adsorption
step. At the end of the screening procedure, six MOFs with high deliverable
working capacities (∼0.6 mL working fluid in 1 mL structure)
and diverse adsorption step locations are selected for both adsorbates
from the original 2930 structures. Because the highest experimentally
measured deliverable working capacity to date for MOFs with methanol
is ca. 0.45 mL mL–1, the selected six structures
show the potential to improve the efficiency of ACs.