Abstract
Sustainable energy and chemical/material transformation constrained by limited greenhouse gas generation impose a grand challenge and posit outstanding opportunities to electrochemical material devices. Dramatic advancements in experimental and computational methodologies have captured detailed insights into the working of these material devices at a molecular scale and have brought to light some fundamental constraints that impose bounds on efficiency. We propose that the coupling of molecular events in the material device gives rise to contra-varying or co-varying properties and efficiency improving partial decoupling of such properties can be achieved via introducing engineered heterogeneities. A specific class of engineered heterogeneity is in the form of isomaterial heterostructures comprised of non-native and native polymorphs. The non-native polymorph differs from their native/ground state bulk polymorph in terms of its discrete translational symmetry and we anticipate specific symmetry relationships exist between non-native and native structures that enable the formation of interfaces that enhance efficiency. We present circumstantial evidence and provide speculative mechanisms for such an approach with the hope that a more comprehensive delineation of proposed material design will be undertaken.
Highlights
An inherent elasticity between prosperity and energy/chemical/material usage behooves upon the scientific community to demonstrate sustainable energy and material transformation technologies
Heterostructured Electrochemical Materials Optimization design strategy pertaining to photoelectrochemical oxygen evolution reaction (PEC-OER) (Gratzel, 2001; Vayssieres, 2010; Walter et al, 2011; Van de Krol and Gratzel, 2012; Nellist et al, 2016; Sivula and De Krol, 2016; Hellman and Wang, 2017; Mayer, 2017; Pala, 2017; Aslam et al, 2018; Spitler et al, 2020), electrochemical oxygen evolution reaction (EC-OER) (Jung et al, 2016; Saha et al, 2016; Stevens et al, 2017) and cathodes for Lithium-Ion Batteries (C-LIB) (Grey and Tarascon, 2017; Liu et al, 2019)
The tradeoff in contra-varying or co-varying properties can itself limit the performance of materials and we argue that isomaterially heterostructured interfaces can provide material topologies to scale beyond such limitations
Summary
An inherent elasticity between prosperity and energy/chemical/material usage behooves upon the scientific community to demonstrate sustainable energy and material transformation technologies. The central challenge of PEC-OER is primarily 3-fold: (1) Poor (good) stability in aqueous solution of materials that show high (low) photoelectrochemical activity (2) High (low) photocurrents are associated with low (high) photopotentials (3) Higher (lower) optical absorption resulting in lower (higher) electron-hole separation.
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