2019
DOI: 10.1021/acsenergylett.9b00220
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Direct Electrolytic Splitting of Seawater: Opportunities and Challenges

Abstract: Hot, coastal, hyper-arid regions with intense solar irradiation and strong on- and off-shore wind patterns are ideal locations for the production of renewable electricity using wind turbines or photovoltaics. Given ample access to seawater and scarce freshwater resources, such regions make the direct and selective electrolytic splitting of seawater into molecular hydrogen and oxygen a potentially attractive technology. The key catalytic challenge consists of the competition between anodic chlorine chemistry an… Show more

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Cited by 791 publications
(647 citation statements)
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“…I would like to point out that the presented strategy of exploring CER electrocatalysts with improved selectivity and stability can be equally employed to search for selective OER electrocatalysts, such as for electrocatalytic seawater splitting. [88,89] In this regard, the opposite free energy difference, i. e., ΔG(OCl)-ΔG(OOH), needs to be maximized to obtain a selective OER electrocatalyst based on transition metal oxides, where the CER is sufficiently suppressed. [13] However, in this case the stability issue might be problematic, since the OOH adsorbate limits the stability window of the transition metal oxide in acidic medium (cf.…”
Section: Linear Scaling Relationships Of the Limiting Ocl And Ooh Adsmentioning
confidence: 99%
“…I would like to point out that the presented strategy of exploring CER electrocatalysts with improved selectivity and stability can be equally employed to search for selective OER electrocatalysts, such as for electrocatalytic seawater splitting. [88,89] In this regard, the opposite free energy difference, i. e., ΔG(OCl)-ΔG(OOH), needs to be maximized to obtain a selective OER electrocatalyst based on transition metal oxides, where the CER is sufficiently suppressed. [13] However, in this case the stability issue might be problematic, since the OOH adsorbate limits the stability window of the transition metal oxide in acidic medium (cf.…”
Section: Linear Scaling Relationships Of the Limiting Ocl And Ooh Adsmentioning
confidence: 99%
“…Similarly,aset of peaks in the core-levels pectrumo fC1s reveals the presence of sp 2 -hybridized carbon C=C( 284.2 eV), C=NÀC( 285.7 eV), andC ÀO/C=O (288.2 eV; Figure 3c). The N1score-level spectrum was also deconvoluted into as et of four peaks corresponding to CÀN=C (398.3 eV;t riazine network), NÀ(C) 3 (399.6 eV;t ertiary N),C ÀNÀ H( 400.9 eV;p yrrolic-type N), andashake-up satellite peak (402.3 eV), as presented in Figure 3d. [31] The higher intensity of tertiaryNindicates the presence of ac onsiderable amount of heptazine units present in the whole structure.…”
Section: @Hcnmentioning
confidence: 99%
“…It can decrease the deleterious consequences caused by the use of exhaustible fossil fuels on the environment around the globe . However, on a large scale, the realization of this potential technology is still limited by the need for high input potentials and the slow kinetics of the oxygen evolution reaction (OER), which mainly relies on the use of precious and earth‐scarce metals (Ir and Ru) as catalysts . Regarding this longstanding challenge, it is, therefore, highly desired to develop cost‐effective and competent electrode materials for efficient and long‐lasting OER reasonably close to the thermodynamic potential (1.23 V) or to even replace the benchmark precious metals.…”
Section: Introductionmentioning
confidence: 99%
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“…However, direct electrolysis of seawater is still regarded as a most challenging endeavor in the future hydrogen economy. Beside intensive research on active and robust catalysts, the generation of chlorine gas during the oxidative splitting of seawater remains the most striking challenge . Herein, systematic electrochemical studies and surface analysis were performed to minimize the effect of the chlorine formation in side reactions.…”
Section: Introductionmentioning
confidence: 99%