TY - JOUR
T1 - Hybrid salt-enriched micro-sorbents for atmospheric water sorption
AU - Abd Elwadood, Samar N.
AU - Reddy, K. Suresh Kumar
AU - Al Wahedi, Yasser
AU - Al Alili, Ali
AU - Farinha, Andreia S.F.
AU - Witkamp, Geert Jan
AU - Dumée, Ludovic F.
AU - Karanikolos, Georgios N.
N1 - Funding Information:
Financial support by the Center for Catalysis and Separations (CeCaS, RC2-2018-024 ) of Khalifa University is greatly acknowledged. Support by the Center of Membranes and Advanced Water Technology (CMAT, RC2-2018-009 ) and the Research and Innovation Center on CO 2 and Hydrogen (RICH, RC2-2019-007 ) of Khalifa University is gratefully acknowledged. In addition, this work was supported by the Abu Dhabi National Oil Company (ADNOC), Emirates NBD and Sharjah Electricity Water & Gas Authority (SEWA) as the sponsors of the 3rd Forum for Women in Research , QUWA: Women Empowerment for Global Impact at University of Sharjah .
Funding Information:
Financial support by the Center for Catalysis and Separations (CeCaS, RC2-2018-024) of Khalifa University is greatly acknowledged. Support by the Center of Membranes and Advanced Water Technology (CMAT, RC2-2018-009) and the Research and Innovation Center on CO2 and Hydrogen (RICH, RC2-2019-007) of Khalifa University is gratefully acknowledged. In addition, this work was supported by the Abu Dhabi National Oil Company (ADNOC), Emirates NBD and Sharjah Electricity Water & Gas Authority (SEWA) as the sponsors of the 3rd Forum for Women in Research, QUWA: Women Empowerment for Global Impact at University of Sharjah.
Publisher Copyright:
© 2023 Elsevier Ltd
PY - 2023/4
Y1 - 2023/4
N2 - Water shortage severely impacts drought-stricken regions, with estimates indicating that almost half a billion people are affected yearly. Composites of Salt and Porous Matrix (CSPMs) are promising functional materials for water vapor sorption. Here, CSPMs were synthesized by loading SAPO-34 porous crystals with highly hygroscopic salts, namely LiCl and CaCl2, individually (mono-salt systems) or combined (binary salt systems) to enhance water sorption capacity and cyclability. The LiCl and CaCl2 content in the impregnation solution impacted the sorption behavior and equilibrium capacity of the resulting composites. Physicochemical, morphological, textural, and sorption properties were evaluated showing that the confinement of binary salts yielded the highest water uptake (0.88 gw/gads at 25 °C and 90 % RH), which was four times higher than that of the parent SAPO-34. The shape of the obtained water vapor isotherms revealed that the salts introduced into the porous structure led to significant changes in the sorption mechanism, with SAPO-34 following a Langmuir behavior (type I isotherm) and the composites a type II isotherm with associated multilayer formation due to the presence of the salts. Kinetic studies also revealed that the materials follow a PSO model dominated by water-surface interactions. Embedding different salts into the same hosting pores to support atmospheric water harvesting was therefore found to enhance capacity and cyclability compared to single inorganic porous structures toward more efficient water sorption processes.
AB - Water shortage severely impacts drought-stricken regions, with estimates indicating that almost half a billion people are affected yearly. Composites of Salt and Porous Matrix (CSPMs) are promising functional materials for water vapor sorption. Here, CSPMs were synthesized by loading SAPO-34 porous crystals with highly hygroscopic salts, namely LiCl and CaCl2, individually (mono-salt systems) or combined (binary salt systems) to enhance water sorption capacity and cyclability. The LiCl and CaCl2 content in the impregnation solution impacted the sorption behavior and equilibrium capacity of the resulting composites. Physicochemical, morphological, textural, and sorption properties were evaluated showing that the confinement of binary salts yielded the highest water uptake (0.88 gw/gads at 25 °C and 90 % RH), which was four times higher than that of the parent SAPO-34. The shape of the obtained water vapor isotherms revealed that the salts introduced into the porous structure led to significant changes in the sorption mechanism, with SAPO-34 following a Langmuir behavior (type I isotherm) and the composites a type II isotherm with associated multilayer formation due to the presence of the salts. Kinetic studies also revealed that the materials follow a PSO model dominated by water-surface interactions. Embedding different salts into the same hosting pores to support atmospheric water harvesting was therefore found to enhance capacity and cyclability compared to single inorganic porous structures toward more efficient water sorption processes.
KW - AlPOs
KW - Atmospheric water generation
KW - Composites of salt and porous matrix
KW - Porous materials
KW - Sorption
UR - http://www.scopus.com/inward/record.url?scp=85148614735&partnerID=8YFLogxK
U2 - 10.1016/j.jwpe.2023.103560
DO - 10.1016/j.jwpe.2023.103560
M3 - Article
AN - SCOPUS:85148614735
SN - 2214-7144
VL - 52
JO - Journal of Water Process Engineering
JF - Journal of Water Process Engineering
M1 - 103560
ER -