{"id":75248,"date":"2022-01-31T10:00:54","date_gmt":"2022-01-31T01:00:54","guid":{"rendered":"https:\/\/www.waseda.jp\/top\/en\/?p=75248"},"modified":"2022-02-07T11:04:34","modified_gmt":"2022-02-07T02:04:34","slug":"life-in-a-nutshell-new-species-found-in-the-carapace-of-late-cretaceous-marine-turtle-2-2-2-2-2-2-2-2","status":"publish","type":"post","link":"https:\/\/www.waseda.jp\/top\/en\/news\/75248","title":{"rendered":"New Study Suggests an Alternative Technique for Determining the True Activity of Catalysts"},"content":{"rendered":"

New Study Suggests an Alternative Technique for Determining the True Activity of Catalysts<\/strong><\/h1>\n

Researchers from Japan perform reliable estimation of the activity of water-splitting catalysts with an unconventional technique<\/em><\/h3>\n

Electrolysis of water into hydrogen and oxygen is a potential source of clean hydrogen fuel. However, the process requires efficient electrocatalysts. Unfortunately, conventional techniques often overestimate their efficiency. Now, researchers from Japan demonstrate an alternative technique for gauging the electrocatalytic performance accurately, opening doors to a smooth transition from lab-scale studies to large-scale hydrogen fuel generation and commercialization of new catalysts with no activity loss issues from overestimation of activity with transient voltammetry techniques.<\/p>\n

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Electrolysis of water or \u201cwater electrosplitting\u201d has received a great deal of attention recently owing to its potential as a clean source of hydrogen, the oft-touted fuel of the future. However, two issues have long stood in the way: the large amount of energy lost, and the cost of electrocatalysts (catalysts used for electrolysis). Fortunately, several new kinds of electrocatalysts have made their appearance, which could potentially solve these issues.<\/p>\n

The screening of new electrocatalysts is conventionally performed with techniques such as \u201clinear sweep voltammetry\u201d (LSV) and \u201ccyclic voltammetry\u201d (CV), which involve applying a constantly changing voltage to an electrode and monitoring the resulting current. As this current depends on the rate of oxidation or reduction occurring at the electrode, the measured current readings can be used to determine the effect of an electrocatalyst on the speed of the electrolysis reaction.<\/p>\n

However, an obvious drawback of these techniques is that they cannot accurately record the \u201csteady-state\u201d response of the electrocatalyst as it does not experience a particular applied voltage long enough to do so. As a result, substantially high current readings are often recorded, which do not reflect the true catalytic activity, hindering the development of efficient electrocatalysts and promotion of the same to large-scale processes.<\/p>\n

In a new study published in the Journal of The Electrochemical Society<\/em><\/a>, Assistant Professor Sengeni Anantharaj<\/a> from Waseda University, Japan, along with his collaborators Dr. Subrata Kundu from CSIR-Central Electrochemical Research Institute, India, and Prof. Suguru Noda<\/a> from Waseda University have now found a way around this problem, demonstrating an alternate technique called \u201csampled current voltammetry\u201d (SCV) as a more reliable indicator of electrocatalytic performance at a constant steady-state applied voltage.<\/p>\n

\u201cScreening catalysts accurately is just as important as developing new catalysts for all energy conversion reactions,\u201d<\/em> says Anantharaj, speaking of his motivation. \u201cOur work has highlighted a way to make accurate measurements of electrocatalytic activity previously not possible with conventional transient techniques.\u201d<\/em><\/p>\n

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Researchers from Waseda University, Japan, suggest an alternate technique for measuring steady-state electrocatalytic activity more reliably over conventional transient techniques, opening up a potential route to efficient hydrogen generation from water splitting.
\n<\/em><\/strong>Photo courtesy: Sengeni Anantharaj from Waseda University<\/h5>\n

Before applying the SCV technique, the researchers analyzed the errors resulting from LSV. To show the deviation in current values, they used a steady-state technique called \u201cchronoamperometry\u201d (CA), which is the most accurate method of all yet time consuming to measure current at constant voltages and compared it to the values obtained from LSV.<\/p>\n

To determine the activity of electrocatalysts used in electrolysis, they measured the current readings of both the oxygen-producing and hydrogen-producing half-cell reactions. Using a stainless-steel (SS) electrode, precipitated Co(OH)2<\/sub> (cobalt hydroxide), and platinum foil as catalysts in a KOH (potassium hydroxide) solution, the researchers found that the current density readings from LSV and CA differed significantly, with the difference growing wider at higher applied voltages.<\/p>\n

Using the same setup, they then applied the SCV technique and recorded the current densities at various fixed voltages obtained from the steady-state CA responses. \u201cTo validate the suitability of SCV, we recorded the CA responses of the SS electrode at various regularly increasing voltages for 130 seconds, within which the SS interface was able to reach a steady state,\u201d <\/em>elaborates Anantharaj.<\/p>\n

From the sampled current readings, the researchers found negligible difference compared to the steady-state CA technique, demonstrating the reliability of the SCV in correctly determining electrocatalyst\u2019s behavior at different voltages. Additionally, while the SCV is particularly useful in the search for a suitable electrocatalyst for water electrosplitting, it can be used to screen electrocatalysts accurately for any electrochemical reaction.<\/p>\n

\u201cBy addressing the long-standing problem of catalyst performance loss when promoted from the lab to the practical processes, our work could speed up the worldwide adoption of large-scale hydrogen generation from electrolysis,\u201d<\/em> comments Anantharaj.<\/p>\n

It certainly appears we\u2019re now one step closer to the wide adaptation of hydrogen-powered future!<\/p>\n

Reference<\/h3>\n

Authors: Sengeni Anantharaj1,2<\/sup>, Subrata Kundu3<\/sup> and Suguru Noda1,2<\/sup>
\nTitle of original paper: Worrisome Exaggeration of Activity of Electrocatalysts Destined for Steady-State Water Electrolysis by Polarization Curves from Transient Techniques<\/a>
\nJournal:\u00a0Journal of The Electrochemical Society<\/a>
\n<\/em>DOI:\u00a010.1149\/1945-7111\/ac47ec<\/a>
\nLatest Article Publication Date: 5 January 2022
\nAffiliations:
\n1<\/sup>Department of Applied Chemistry, School of Advanced Science and Engineering<\/a>, Waseda University
\n2<\/sup>Waseda Research Institute for Science and Engineering<\/a>, Waseda University
\n3<\/sup>Electrochemical Process Engineering (ECE) Division, CSIR-Central Electrochemical Research Institute (CECRI), India<\/p>\n","protected":false},"excerpt":{"rendered":"

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