High oxygen evolution reaction activity on lithiated nickel oxides - Activity descriptors

Alkaline water electrolyzers promise very high purity hydrogen gas production but suffer from large overpotential for anodic oxygen evolution reaction (OER). Here we describe the effect of lithium (Li+)-substitution into nickel oxide on the electrocatalytic activity towards OER in alkaline electroly...

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Veröffentlicht in:	Electrochimica acta 2019-09, Vol.318, p.809-819
Hauptverfasser:	Sankannavar, Ravi, Sandeep, K.C., Kamath, Sachin, Suresh, Akkihebbal K., Sarkar, A.
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Schlagworte:	Alkaline water electrolysis Diffraction patterns Electrical conductivity Electrical resistivity Electrolytes Lattice parameters Lattice vacancies Lithium Lithium nickel oxide Nickel oxides Organic chemistry Oxidation state Oxygen evolution reactions Oxygen vacancies Photoelectrons Rotating disks Sodium hydroxide Spectrum analysis Substitution reactions Synthesis
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description	Alkaline water electrolyzers promise very high purity hydrogen gas production but suffer from large overpotential for anodic oxygen evolution reaction (OER). Here we describe the effect of lithium (Li+)-substitution into nickel oxide on the electrocatalytic activity towards OER in alkaline electrolyte. The X-ray diffraction patterns of lithiated nickel oxides (LixNi1−xO, x = 0.00–0.50) synthesized by the solution-combustion method suggest that pure phase of lithiated nickel oxide was formed until x = 0.30; thereafter, a secondary phase of LiNiO2 was observed. Rietveld analysis showed that Li+-substitution caused a contraction in the lattice structure as shown by the decrease in lattice parameters upon Li+-substitution. Further, the weight fraction of LiNiO2 was found to be dominant for x = 0.50. Deconvolution of the high resolution X-ray photoelectron spectroscopy for O 1s and Ni 2p spectra suggested that concentration of oxygen vacancies increased linearly, whereas that of Ni3+ increased till x = 0.30 and it decreased when Li+-substitution was further increased to x = 0.40 and 0.50. Although electrical conductivity increased upon Li+-substitution, no significant effect was observed for lithiated samples with varying Li+-content (x = 0.10–0.50). The activities for OER were measured using the rotating disk electrode in 0.5 M NaOH electrolyte, and the data suggest that lithiated nickel oxide synthesized with x = 0.30 shows the highest current density at 1.70 vs. RHE (V). The decrease in OER activity for x = 0.40 and 0.50 was attributed to the decline in OER active Ni3+ sites (probably due to the presence of chemically unstable LiNiO2). [Display omitted] •Lithiated nickel oxides LixNi1-xO (x = 0.0–0.5) are found to be electrochemically active for OER.•XRD shown presence of chemically unstable LiNiO2 for x = 0.4 and 0.5 Li+-content.•Change in electrical conductivity was insignificant amongst lithiated NiO samples.•RDE measurements show Li0.3Ni0.7O electrocatalyst has higher activity for OER.•Concentration of Ni3+-sites at oxide surface found to be OER influencing activity descriptor.
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Here we describe the effect of lithium (Li+)-substitution into nickel oxide on the electrocatalytic activity towards OER in alkaline electrolyte. The X-ray diffraction patterns of lithiated nickel oxides (LixNi1−xO, x = 0.00–0.50) synthesized by the solution-combustion method suggest that pure phase of lithiated nickel oxide was formed until x = 0.30; thereafter, a secondary phase of LiNiO2 was observed. Rietveld analysis showed that Li+-substitution caused a contraction in the lattice structure as shown by the decrease in lattice parameters upon Li+-substitution. Further, the weight fraction of LiNiO2 was found to be dominant for x = 0.50. Deconvolution of the high resolution X-ray photoelectron spectroscopy for O 1s and Ni 2p spectra suggested that concentration of oxygen vacancies increased linearly, whereas that of Ni3+ increased till x = 0.30 and it decreased when Li+-substitution was further increased to x = 0.40 and 0.50. Although electrical conductivity increased upon Li+-substitution, no significant effect was observed for lithiated samples with varying Li+-content (x = 0.10–0.50). The activities for OER were measured using the rotating disk electrode in 0.5 M NaOH electrolyte, and the data suggest that lithiated nickel oxide synthesized with x = 0.30 shows the highest current density at 1.70 vs. RHE (V). The decrease in OER activity for x = 0.40 and 0.50 was attributed to the decline in OER active Ni3+ sites (probably due to the presence of chemically unstable LiNiO2). [Display omitted] •Lithiated nickel oxides LixNi1-xO (x = 0.0–0.5) are found to be electrochemically active for OER.•XRD shown presence of chemically unstable LiNiO2 for x = 0.4 and 0.5 Li+-content.•Change in electrical conductivity was insignificant amongst lithiated NiO samples.•RDE measurements show Li0.3Ni0.7O electrocatalyst has higher activity for OER.•Concentration of Ni3+-sites at oxide surface found to be OER influencing activity descriptor.</description><identifier>ISSN: 0013-4686</identifier><identifier>EISSN: 1873-3859</identifier><identifier>DOI: 10.1016/j.electacta.2019.06.089</identifier><language>eng</language><publisher>Oxford: Elsevier Ltd</publisher><subject>Alkaline water electrolysis ; Diffraction patterns ; Electrical conductivity ; Electrical resistivity ; Electrolytes ; Lattice parameters ; Lattice vacancies ; Lithium ; Lithium nickel oxide ; Nickel oxides ; Organic chemistry ; Oxidation state ; Oxygen evolution reactions ; Oxygen vacancies ; Photoelectrons ; Rotating disks ; Sodium hydroxide ; Spectrum analysis ; Substitution reactions ; Synthesis</subject><ispartof>Electrochimica acta, 2019-09, Vol.318, p.809-819</ispartof><rights>2019 Elsevier Ltd</rights><rights>Copyright Elsevier BV Sep 20, 2019</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c343t-dc5b7f67ad590453a47131e0ad3f802dc7cbb35e04e489390d21c87484c432683</citedby><cites>FETCH-LOGICAL-c343t-dc5b7f67ad590453a47131e0ad3f802dc7cbb35e04e489390d21c87484c432683</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://www.sciencedirect.com/science/article/pii/S0013468619312320$$EHTML$$P50$$Gelsevier$$H</linktohtml><link.rule.ids>314,776,780,3537,27901,27902,65306</link.rule.ids></links><search><creatorcontrib>Sankannavar, Ravi</creatorcontrib><creatorcontrib>Sandeep, K.C.</creatorcontrib><creatorcontrib>Kamath, Sachin</creatorcontrib><creatorcontrib>Suresh, Akkihebbal K.</creatorcontrib><creatorcontrib>Sarkar, A.</creatorcontrib><title>High oxygen evolution reaction activity on lithiated nickel oxides - Activity descriptors</title><title>Electrochimica acta</title><description>Alkaline water electrolyzers promise very high purity hydrogen gas production but suffer from large overpotential for anodic oxygen evolution reaction (OER). Here we describe the effect of lithium (Li+)-substitution into nickel oxide on the electrocatalytic activity towards OER in alkaline electrolyte. The X-ray diffraction patterns of lithiated nickel oxides (LixNi1−xO, x = 0.00–0.50) synthesized by the solution-combustion method suggest that pure phase of lithiated nickel oxide was formed until x = 0.30; thereafter, a secondary phase of LiNiO2 was observed. Rietveld analysis showed that Li+-substitution caused a contraction in the lattice structure as shown by the decrease in lattice parameters upon Li+-substitution. Further, the weight fraction of LiNiO2 was found to be dominant for x = 0.50. Deconvolution of the high resolution X-ray photoelectron spectroscopy for O 1s and Ni 2p spectra suggested that concentration of oxygen vacancies increased linearly, whereas that of Ni3+ increased till x = 0.30 and it decreased when Li+-substitution was further increased to x = 0.40 and 0.50. Although electrical conductivity increased upon Li+-substitution, no significant effect was observed for lithiated samples with varying Li+-content (x = 0.10–0.50). The activities for OER were measured using the rotating disk electrode in 0.5 M NaOH electrolyte, and the data suggest that lithiated nickel oxide synthesized with x = 0.30 shows the highest current density at 1.70 vs. RHE (V). The decrease in OER activity for x = 0.40 and 0.50 was attributed to the decline in OER active Ni3+ sites (probably due to the presence of chemically unstable LiNiO2). [Display omitted] •Lithiated nickel oxides LixNi1-xO (x = 0.0–0.5) are found to be electrochemically active for OER.•XRD shown presence of chemically unstable LiNiO2 for x = 0.4 and 0.5 Li+-content.•Change in electrical conductivity was insignificant amongst lithiated NiO samples.•RDE measurements show Li0.3Ni0.7O electrocatalyst has higher activity for OER.•Concentration of Ni3+-sites at oxide surface found to be OER influencing activity descriptor.</description><subject>Alkaline water electrolysis</subject><subject>Diffraction patterns</subject><subject>Electrical conductivity</subject><subject>Electrical resistivity</subject><subject>Electrolytes</subject><subject>Lattice parameters</subject><subject>Lattice vacancies</subject><subject>Lithium</subject><subject>Lithium nickel oxide</subject><subject>Nickel oxides</subject><subject>Organic chemistry</subject><subject>Oxidation state</subject><subject>Oxygen evolution reactions</subject><subject>Oxygen vacancies</subject><subject>Photoelectrons</subject><subject>Rotating disks</subject><subject>Sodium hydroxide</subject><subject>Spectrum analysis</subject><subject>Substitution reactions</subject><subject>Synthesis</subject><issn>0013-4686</issn><issn>1873-3859</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><recordid>eNqFUMFKAzEUDKJgrX6DC553fdlkN9ljKWoFwYsePIVt8rZNXTc1SYv9e7NUvQoPZh7MzOMNIdcUCgq0vt0U2KOObZqiBNoUUBcgmxMyoVKwnMmqOSUTAMpyXsv6nFyEsAEAUQuYkLeFXa0z93VY4ZDh3vW7aN2QeUx5Ixlhb-MhS7y3cW3biCYbrH7HPtmswZDl2exXlVbt7TY6Hy7JWdf2Aa9-cEpe7-9e5ov86fnhcT57yjXjLOZGV0vR1aI1VQO8Yi0XlFGE1rBOQmm00MslqxA4ctmwBkxJtRRccs1ZWUs2JTfH3K13nzsMUW3czg_ppCpLSSkXQjRJJY4q7V0IHju19faj9QdFQY09qo3661GNPSqoVeoxOWdHJ6Yn9ha9CtrioNFYn_TKOPtvxjelSIC_</recordid><startdate>20190920</startdate><enddate>20190920</enddate><creator>Sankannavar, Ravi</creator><creator>Sandeep, K.C.</creator><creator>Kamath, Sachin</creator><creator>Suresh, Akkihebbal K.</creator><creator>Sarkar, A.</creator><general>Elsevier Ltd</general><general>Elsevier BV</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SR</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><scope>L7M</scope></search><sort><creationdate>20190920</creationdate><title>High oxygen evolution reaction activity on lithiated nickel oxides - Activity descriptors</title><author>Sankannavar, Ravi ; Sandeep, K.C. ; Kamath, Sachin ; Suresh, Akkihebbal K. ; Sarkar, A.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c343t-dc5b7f67ad590453a47131e0ad3f802dc7cbb35e04e489390d21c87484c432683</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2019</creationdate><topic>Alkaline water electrolysis</topic><topic>Diffraction patterns</topic><topic>Electrical conductivity</topic><topic>Electrical resistivity</topic><topic>Electrolytes</topic><topic>Lattice parameters</topic><topic>Lattice vacancies</topic><topic>Lithium</topic><topic>Lithium nickel oxide</topic><topic>Nickel oxides</topic><topic>Organic chemistry</topic><topic>Oxidation state</topic><topic>Oxygen evolution reactions</topic><topic>Oxygen vacancies</topic><topic>Photoelectrons</topic><topic>Rotating disks</topic><topic>Sodium hydroxide</topic><topic>Spectrum analysis</topic><topic>Substitution reactions</topic><topic>Synthesis</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Sankannavar, Ravi</creatorcontrib><creatorcontrib>Sandeep, K.C.</creatorcontrib><creatorcontrib>Kamath, Sachin</creatorcontrib><creatorcontrib>Suresh, Akkihebbal K.</creatorcontrib><creatorcontrib>Sarkar, A.</creatorcontrib><collection>CrossRef</collection><collection>Engineered Materials Abstracts</collection><collection>Solid State and Superconductivity Abstracts</collection><collection>METADEX</collection><collection>Technology Research Database</collection><collection>Materials Research Database</collection><collection>Advanced Technologies Database with Aerospace</collection><jtitle>Electrochimica acta</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Sankannavar, Ravi</au><au>Sandeep, K.C.</au><au>Kamath, Sachin</au><au>Suresh, Akkihebbal K.</au><au>Sarkar, A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>High oxygen evolution reaction activity on lithiated nickel oxides - Activity descriptors</atitle><jtitle>Electrochimica acta</jtitle><date>2019-09-20</date><risdate>2019</risdate><volume>318</volume><spage>809</spage><epage>819</epage><pages>809-819</pages><issn>0013-4686</issn><eissn>1873-3859</eissn><abstract>Alkaline water electrolyzers promise very high purity hydrogen gas production but suffer from large overpotential for anodic oxygen evolution reaction (OER). Here we describe the effect of lithium (Li+)-substitution into nickel oxide on the electrocatalytic activity towards OER in alkaline electrolyte. The X-ray diffraction patterns of lithiated nickel oxides (LixNi1−xO, x = 0.00–0.50) synthesized by the solution-combustion method suggest that pure phase of lithiated nickel oxide was formed until x = 0.30; thereafter, a secondary phase of LiNiO2 was observed. Rietveld analysis showed that Li+-substitution caused a contraction in the lattice structure as shown by the decrease in lattice parameters upon Li+-substitution. Further, the weight fraction of LiNiO2 was found to be dominant for x = 0.50. Deconvolution of the high resolution X-ray photoelectron spectroscopy for O 1s and Ni 2p spectra suggested that concentration of oxygen vacancies increased linearly, whereas that of Ni3+ increased till x = 0.30 and it decreased when Li+-substitution was further increased to x = 0.40 and 0.50. Although electrical conductivity increased upon Li+-substitution, no significant effect was observed for lithiated samples with varying Li+-content (x = 0.10–0.50). The activities for OER were measured using the rotating disk electrode in 0.5 M NaOH electrolyte, and the data suggest that lithiated nickel oxide synthesized with x = 0.30 shows the highest current density at 1.70 vs. RHE (V). The decrease in OER activity for x = 0.40 and 0.50 was attributed to the decline in OER active Ni3+ sites (probably due to the presence of chemically unstable LiNiO2). [Display omitted] •Lithiated nickel oxides LixNi1-xO (x = 0.0–0.5) are found to be electrochemically active for OER.•XRD shown presence of chemically unstable LiNiO2 for x = 0.4 and 0.5 Li+-content.•Change in electrical conductivity was insignificant amongst lithiated NiO samples.•RDE measurements show Li0.3Ni0.7O electrocatalyst has higher activity for OER.•Concentration of Ni3+-sites at oxide surface found to be OER influencing activity descriptor.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.electacta.2019.06.089</doi><tpages>11</tpages></addata></record>
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subjects	Alkaline water electrolysis Diffraction patterns Electrical conductivity Electrical resistivity Electrolytes Lattice parameters Lattice vacancies Lithium Lithium nickel oxide Nickel oxides Organic chemistry Oxidation state Oxygen evolution reactions Oxygen vacancies Photoelectrons Rotating disks Sodium hydroxide Spectrum analysis Substitution reactions Synthesis
title	High oxygen evolution reaction activity on lithiated nickel oxides - Activity descriptors
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