Medhat Mohamed El-Moselhy scite author profile

Globally speaking, waste acid neutralization is a widely used industrial pollution control process. In principle, acidÀbase neutralization is a thermodynamically favorable reaction that involves the association of hydrogen and hydroxyl ions to form neutral water molecules with the generation of a significant amount of thermal energy (ΔH = À55.84 kJ/mol). However, it is not possible to recover the energy, because the increase in temperature of the bulk solution phase is often miniscule, because of the diluted nature of the waste acid solution and the high specific heat of water. Here, we demonstrate a methodology to recover a significant amount of useful energy by carrying out the neutralization reaction inside a pH-sensitive hydrophilic polymer (or biopolymer) phase containing covalently attached weak-acid or weak-base functional groups. When contacted with an acid or a base, the variation of pH causes the functional groups to reversibly acquire and lose its ionic character. This gives rise to an onÀoff pattern regarding the generation of osmotic pressure inside the polymer phase, causing it to reversibly swell and shrink, because of the movement of water into and out of the polymer phase. Laboratory experiments validate the reversibility of the swellingÀshrinking pattern of a commercial weak-acid ion-exchange resin for multiple numbers of cycles with a concomitant generation of mechanical energy during the neutralization reaction. The process can be enhanced by tailoring the cross-linking and hydrophilicity of the polymer phase. The energy generated is free of carbon emission.

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Comparison of the structural properties of isomorphously substituted Fe in mordenite zeolites prepared by different methods

Mohamed

Gomaa

El-Moselhy

et al. 2003

Journal of Colloid and Interface Science

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Enhanced defluoridation using reusable strong acid cation exchangers in Al3+ form (SAC-Al) containing hydrated Al(III) oxide nanoparticles

Praipipat

El-Moselhy

Khuanmar

et al. 2017

Chemical Engineering Journal

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