Highly efficient cooling using a new nanoporous solid

  Print version of this article RSS
22/10/2018

Heat recovery (solar energy, heat pump, air conditioning, cooling…) has been a growing stake since people got aware of the emergency of reducing their power consumption and encouraging sustainable development. Even if water recovery and release using nanoporous materials is a reliable strategy to achieve this goal, developing new energy efficient processes remains a challenge. Researchers from the Paris porous materials Institute (CNRS, ENS Paris, ESPCI Paris/ PSL University) and from the Charles Gerhardt Institute in Montpellier (Université Montpellier/CNRS/ ENSCM) discovered a new hybrid porous material, robust and synthetized through a «green chemistry» route. Their findings published in Nature Energy revealed that this new material is much more efficient than any other water adsorbent, with a high storage capacity and a lower regeneration temperature.

PNG - 136.8 kb
(left) View of the structure of the Zr-MOF (Zr atoms/polyhedra: in yellow; oxygen and hydrogen atoms in red and white). Right: evolution of the coefficient of performance of the MOF-Zr in comparison with benchmark porous solids ©Christian Serre

The use of water sorption (i.e. molecules capable of fixing water at the surface) has been so far very promising for heat recovery from industrial processes and solar energy. The typical temperature of in-house warm water systems involving a cogeneration producer does not exceed 63°C, and it can be used for cooling systems and heat pumps. Current processes are based on inorganic porous commercial adsorbents (zeolites or related solids) that suffer from high regeneration temperatures and/or limited pore volumes leading to poor energy efficient systems.

To overcome these drawbacks, researchers from the Paris porous materials Institute and from the Charles Gerhardt Institute in Montpellier [1] designed a new hydrophilic nanoporous hybrid solid with large pores, made of zirconium oxoclusters – Zr-MOF, which combines a set a parameters giving much higher water sorption performance.

For cooling processes, the overall performance relies not only on evaporation and condensation temperatures of water, but also on adsorption (exothermic) and desorption (endothermic) temperatures, the storage capacity, stability and kinetics of heat exchange, among others.
The new Zr-MOF exhibits a microporous structure very stable in presence of hot water. It shows a highly pronounced hydrophilic behavior with significant heat exchanges and a pore size sufficient enough to adsorb large amount of water and also a lower regeneration temperature during desorption step (<65°C). Researchers from the Korean Research Institute of Chemical Technology (KRICT) have performed energetic performance calculations (ratio of the energy taken from the evaporator and the energy needed to regenerate the adsorbent). This analysis revealed that the solid is more efficient than any other evaluated porous materials so far for this type of application. It should lead to the development of new generation of cooling processes to recover solar energy or even energy from heat sources related to human activities.

Reference
Sujing Wang, Ji Sun Lee, Mohammad Wahiduzzaman, Jaedeuk Park, Mégane Muschi, Charlotte Martineau-Corcos, Antoine Tissot, Kyung Ho Cho, Jérôme Marrot, William Shepard, Guillaume Maurin*, Jong-San Chang*, and Christian Serre*
A Robust Energy-Efficient Metal-Organic Framework Adsorbent for Refrigeration
Nature Energy – October 2018
DOI: dx.doi.org/10.1038/s41560-018-0261-6

Researchers Contact:
Christian Serre, IMAP FRE2000, CNRS, ENS, ESPCI Paris, PSL University
Courriel : christian.serre (arobase) ens.fr
Guillaume Maurin, ICGM, Université de Montpellier, CNRS
Contact : guillaume.maurin1 (arobase) umontpellier.fr

Footnotes

[1In collaboration with the Institut Lavoisier de Versailles, the Korea Research Institute of Chemical Technology and the SOLEIL synchrotron





ÉCOLE SUPÉRIEURE DE PHYSIQUE ET DE CHIMIE INDUSTRIELLES DE LA VILLE DE PARIS
10 Rue Vauquelin, 75005 Paris