electrocatalyst

An electrocatalyst lowers the activation energy required for an electrochemical reaction.{{Cite web|last=Jaramillo|first=Tom|date=September 3, 2014|title=Electrocatalysis 101 {{!}} GCEP Symposium - October 11, 2012|url=https://www.youtube.com/watch?v=2sbsTLvcbCg&feature=youtu.be|website=Youtube.com}} Some electrocatalysts change the potential at which oxidation and reduction processes occur.{{Cite book|last=Bard|first=Allen J. |title=Electrochemical methods: fundamentals and applications|date=2001|author2=Larry R. Faulkner|isbn=0-471-04372-9|edition=Second |location=Hoboken, NJ|oclc=43859504}} In other cases, an electrocatalyst can impart selectivity by favoring specific chemical interaction at an electrode surface.{{Cite journal|last=McCreery|first=Richard L.|date=July 2008|title=Advanced Carbon Electrode Materials for Molecular Electrochemistry |journal=Chemical Reviews|language=en|volume=108|issue=7|pages=2646–2687|doi=10.1021/cr068076m|pmid=18557655 |issn=0009-2665}} Given that electrochemical reactions occur when electrons are passed from one chemical species to another, favorable interactions at an electrode surface increase the likelihood of electrochemical transformations occurring, thus reducing the potential required to achieve these transformations.

Electrocatalysts can be evaluated according to activity, stability, and selectivity. The activity of electrocatalysts can be assessed quantitatively by the current density is generated, and therefore how fast a reaction is taking place, for a given applied potential. This relationship is described with the Tafel equation. In assessing the stability of electrocatalysts, the a key parameter is turnover number (TON). The selectivity of electrocatalysts refers to the product distribution. Selectivity can be quantitatively assessed through a selectivity coefficient, which compares the response of the material to the desired analyte or substrate with the response to other interferents.{{Cite journal|last1=Brown|first1=Micah D.|last2=Schoenfisch|first2=Mark H.|date=2019-11-27|title=Electrochemical Nitric Oxide Sensors: Principles of Design and Characterization |journal=Chemical Reviews|language=en|volume=119|issue=22|pages=11551–11575|doi=10.1021/acs.chemrev.8b00797|pmid=31553169 |s2cid=202761809 |issn=0009-2665}}

In many electrochemical systems, including galvanic cells, fuel cells and various forms of electrolytic cells, a drawback is that they can suffer from high activation barriers. The energy diverted to overcome these activation barriers is transformed into heat. In most exothermic combustion reactions this heat would simply propagate the reaction catalytically. In a redox reaction, this heat is a useless byproduct lost to the system. The extra energy required to overcome kinetic barriers is usually described in terms of low faradaic efficiency and high overpotentials. In these systems, each of the two electrodes and its associated half-cell would require its own specialized electrocatalyst.

Half-reactions involving multiple steps, multiple electron transfers, and the evolution or consumption of gases in their overall chemical transformations, will often have considerable kinetic barriers. Furthermore, there is often more than one possible reaction at the surface of an electrode. For example, during the electrolysis of water, the anode can oxidize water through a two electron process to hydrogen peroxide or a four electron process to oxygen. The presence of an electrocatalyst could facilitate either of the reaction pathways.

{{Cite book|last1=Bard|first1=Allen J.|url=https://www.amazon.co.uk/gp/reader/0471043729/ref=sib_dp_pt#reader-link|title=Electrochemical methods: fundamentals and applications|last2=Faulkner|first2=Larry R.|date=January 2001|publisher=Wiley|isbn=978-0-471-04372-0|location=New York|author1-link=Allen J. Bard|accessdate=27 February 2009}}

File:Types of Electrocatalysts.png

A homogeneous electrocatalyst is one that is present in the same phase of matter as the reactants, for example, a water-soluble coordination complex catalyzing an electrochemical conversion in solution. This technology is not practiced commercially, but is of research interest.

Many coordination complexes catalyze electrochemical reactions, although few have achieved commercial success. Well investigated processes include the hydrogen evolution reaction.{{cite journal |doi=10.1021/acs.chemrev.1c01001 |title=Molecular Catalysts with Diphosphine Ligands Containing Pendant Amines |date=2022 |last1=Wiedner |first1=Eric S. |last2=Appel |first2=Aaron M. |last3=Raugei |first3=Simone |last4=Shaw |first4=Wendy J. |last5=Bullock |first5=R. Morris |journal=Chemical Reviews |volume=122 |issue=14 |pages=12427–12474 |pmid=35640056 |osti=1922077 }}

There is much interest in replacing traditional chemical catalysis with electrocatalysis. In such a scheme electrons supplied by an electrode are reagents. The topic is a theme within the area of green energy, because the electrons can be sourced from renewable resources. Several conversions that use of hydrogen gas could be transformed into electrochemical processes that use protons.{{cite journal |doi=10.1039/D3CS00419H |title=Developing electrochemical hydrogenation towards industrial application |date=2023 |last1=Kleinhaus |first1=Julian T. |last2=Wolf |first2=Jonas |last3=Pellumbi |first3=Kevinjeorjios |last4=Wickert |first4=Leon |last5=Viswanathan |first5=Sangita C. |last6=Junge Puring |first6=Kai |last7=Siegmund |first7=Daniel |last8=Apfel |first8=Ulf-Peter |journal=Chemical Society Reviews |volume=52 |issue=21 |pages=7305–7332 |pmid=37814786 }} This technology remains economically noncompetitive.{{Cite web|title=Dream or Reality? Electrification of the Chemical Process Industries|url=https://www.aiche-cep.com/cepmagazine/march_2021/MobilePagedArticle.action?articleId=1663852|access-date=2021-08-22|website=www.aiche-cep.com|language=en}}

Another example is found in the area of nitrogen fixation. The traditional Haber-Bosch process produces ammonia by hydrogenation of nitrogen gas:

:{{chem2|N2 + 3 H2 -> 2 NH3}}

In the electrified version, the hydrogen is provided in the form of protons and electrons:{{cite journal |doi=10.1039/C9CS00159J |title=Electrochemical nitrogen fixation and utilization: Theories, advanced catalyst materials and system design |date=2019 |last1=Guo |first1=Wenhan |last2=Zhang |first2=Kexin |last3=Liang |first3=Zibin |last4=Zou |first4=Ruqiang |last5=Xu |first5=Qiang |journal=Chemical Society Reviews |volume=48 |issue=24 |pages=5658–5716 |pmid=31742279 }}{{cite journal |doi=10.1039/D2EE03132A |title=Renewable electron-driven bioinorganic nitrogen fixation: A superior route toward green ammonia? |date=2023 |last1=Wang |first1=Bo |last2=Zhang |first2=Yifeng |last3=Minteer |first3=Shelley D. |journal=Energy & Environmental Science |volume=16 |issue=2 |pages=404–420 |url=https://backend.orbit.dtu.dk/ws/files/298164093/D2EE03132A.pdf }}

:{{chem2|N2 + 6 H+ + 6 e- -> 2 NH3}}

The ammonia represents an energy source since it is combustable. In this way electrification can be seen as a means for energy storage.

Another process attracting much effort is the electrochemical reduction of carbon dioxide.{{Cite journal|last1=Kinzel|first1=Niklas W.|last2=Werlé|first2=Christophe|last3=Leitner|first3=Walter|date=2021-01-19|title=Transition Metal Complexes as Catalysts for the Electroconversion of CO 2 : An Organometallic Perspective|journal=Angewandte Chemie International Edition|volume=60 |issue=21 |language=en|pages=11628–11686|doi=10.1002/anie.202006988|pmid=33464678 |pmc=8248444 |issn=1433-7851|doi-access=free}}

Some enzymes can function as electrocatalysts.{{Cite journal|last1=Chen|first1=Hui|last2=Simoska|first2=Olja|last3=Lim|first3=Koun|last4=Grattieri|first4=Matteo|last5=Yuan|first5=Mengwei|last6=Dong|first6=Fangyuan|last7=Lee|first7=Yoo Seok|last8=Beaver|first8=Kevin|last9=Weliwatte|first9=Samali|last10=Gaffney|first10=Erin M.|last11=Minteer|first11=Shelley D.|date=2020-12-09|title=Fundamentals, Applications, and Future Directions of Bioelectrocatalysis|journal=Chemical Reviews|language=en|volume=120|issue=23|pages=12903–12993|doi=10.1021/acs.chemrev.0c00472|pmid=33050699 |issn=0009-2665|doi-access=free}} Nitrogenase, an enzyme that contains a MoFe cluster, can be leveraged to fix atmospheric nitrogen, i.e. convert nitrogen gas into molecules such as ammonia. Immobilizing the protein onto an electrode surface and employing an electron mediator greatly improves the efficiency of this process.{{Cite journal|last1=Milton|first1=Ross D.|last2=Minteer|first2=Shelley D.|date=2019-12-17|title=Nitrogenase Bioelectrochemistry for Synthesis Applications|url=https://pubs.acs.org/doi/abs/10.1021/acs.accounts.9b00494|journal=Accounts of Chemical Research|language=en|volume=52|issue=12|pages=3351–3360|doi=10.1021/acs.accounts.9b00494|pmid=31800207 |s2cid=208643374 |issn=0001-4842}} The effectiveness of bioelectrocatalysts generally depends on the ease of electron transport between the active site of the enzyme and the electrode surface. Other enzymes provide insight for the development of synthetic catalysts. For example, formate dehydrogenase, a nickel-containing enzyme, has inspired the development of synthetic complexes with similar molecular structures for use in CO₂ reduction.{{Cite journal|last1=Yang|first1=Jenny Y.|last2=Kerr|first2=Tyler A.|last3=Wang|first3=Xinran S.|last4=Barlow|first4=Jeffrey M.|date=2020-11-18|title=Reducing CO 2 to HCO 2 – at Mild Potentials: Lessons from Formate Dehydrogenase|url=https://pubs.acs.org/doi/10.1021/jacs.0c07965|journal=Journal of the American Chemical Society|language=en|volume=142|issue=46|pages=19438–19445|doi=10.1021/jacs.0c07965|pmid=33141560 |bibcode=2020JAChS.14219438Y |issn=0002-7863}} Microbial fuel cells are another way that biological systems can be leveraged for electrocatalytic applications.{{Cite journal|last1=Qiao|first1=Yan|last2=Bao|first2=Shu-Juan|last3=Li|first3=Chang Ming|date=2010|title=Electrocatalysis in microbial fuel cells—from electrode material to direct electrochemistry|url=http://xlink.rsc.org/?DOI=b923503e|journal=Energy & Environmental Science|language=en|volume=3|issue=5|pages=544|doi=10.1039/b923503e|issn=1754-5692}} Microbial-based systems leverage the metabolic pathways of an entire organism, rather than the activity of a specific enzyme, meaning that they can catalyze a broad range of chemical reactions. Microbial fuel cells can derive current from the oxidation of substrates such as glucose, and be leveraged for processes such as CO₂ reduction.

A heterogeneous electrocatalyst is one that is present in a different phase of matter from the reactants, for example, a solid surface catalyzing a reaction in solution. Different types of heterogeneous electrocatalyst materials are shown above in green. Since heterogeneous electrocatalytic reactions need an electron transfer between the solid catalyst (typically a metal) and the electrolyte, which can be a liquid solution but also a polymer or a ceramic capable of ionic conduction, the reaction kinetics depend on both the catalyst and the electrolyte as well as on the interface between them. The nature of the electrocatalyst surface determines some properties of the reaction including rate and selectivity.

Electrocatalysis can occur at the surface of some bulk materials, such as platinum metal. Bulk metal surfaces of gold have been employed for the decomposition methanol for hydrogen production.{{Cite journal|last=Roduner|first=Emil|date=June 13, 2017|title=Selected fundamentals of catalysis and electrocatalysis in energy conversion reactions—A tutorial|url=https://linkinghub.elsevier.com/retrieve/pii/S0920586117304236|journal=Catalysis Today|language=en|volume=309|pages=263–268|doi=10.1016/j.cattod.2017.05.091|s2cid=103395714 |hdl=2263/68699|hdl-access=free}} Water electrolysis is conventionally conducted at inert bulk metal electrodes such as platinum or iridium.{{Cite journal|last1=Carmo|first1=Marcelo|last2=Fritz|first2=David L.|last3=Mergel|first3=Jürgen|last4=Stolten|first4=Detlef|date=March 14, 2013|title=A comprehensive review on PEM water electrolysis|url=https://linkinghub.elsevier.com/retrieve/pii/S0360319913002607|journal=International Journal of Hydrogen Energy|language=en|volume=38|issue=12|pages=4901–4934|doi=10.1016/j.ijhydene.2013.01.151|bibcode=2013IJHE...38.4901C }} The activity of an electrocatalyst can be tuned with a chemical modification, commonly obtained by alloying two or more metals. This is due to a change in the electronic structure, especially in the d band which is considered to be responsible for the catalytic properties of noble metals.{{Cite journal|title=Nanostructured electrocatalysts with tunable activity and selectivity|journal=Nature Reviews Materials|last1=Mistry|first1=H.|volume=1|issue=4|pages=1–14|last2=Varela|first2=A.S.|doi=10.1038/natrevmats.2016.9|last3=Strasser|first3=P.|author-link3=Peter Strasser (chemist)|last4=Cuenya|first4=B.R.|year=2016|bibcode=2016NatRM...116009M}}

A variety of nanoparticle materials have been demonstrated to promote various electrochemical reactions,{{Cite journal|last1=Kleijn|first1=Steven E. F.|last2=Lai|first2=Stanley C. S.|last3=Koper|first3=Marc T. M.|last4=Unwin|first4=Patrick R.|date=2014-04-01|title=Electrochemistry of Nanoparticles|url=http://doi.wiley.com/10.1002/anie.201306828|journal=Angewandte Chemie International Edition|language=en|volume=53|issue=14|pages=3558–3586|doi=10.1002/anie.201306828|pmid=24574053 }} although none have been commercialized. These catalysts can be tuned with respect to their size and shape, as well as the surface strain.{{Cite journal|last1=Luo|first1=Mingchuan|last2=Guo|first2=Shaojun|date=September 26, 2017|title=Strain-controlled electrocatalysis on multimetallic nanomaterials|url=http://www.nature.com/articles/natrevmats201759|journal=Nature Reviews Materials|language=en|volume=2|issue=11|pages=17059|doi=10.1038/natrevmats.2017.59|bibcode=2017NatRM...217059L |issn=2058-8437}}File:Electronic density difference Cl Cu111.png simulation.|alt=Electronic density difference of a Cl atom adsorbed on a Cu(111) surface obtained with a density functional theory simulation. Red regions represent the abundance of electrons, whereas blue regions represent deficit of electrons.|thumb|220x220px]]

Also, higher reaction rates can be achieved by precisely controlling the arrangement of surface atoms: indeed, in nanometric systems, the number of available reaction sites is a better parameter than the exposed surface area in order to estimate electrocatalytic activity. Sites are the positions where the reaction could take place; the likelihood of a reaction to occur in a certain site depends on the electronic structure of the catalyst, which determines the adsorption energy of the reactants together with many other variables not yet fully clarified.

According to the TSK model, the catalyst surface atoms can be classified as terrace, step or kink atoms according to their position, each characterized by a different coordination number. In principle, atoms with lower coordination number (kinks and defects) tend to be more reactive and therefore adsorb the reactants more easily: this may promote kinetics but could also depress it if the adsorbing species isn't the reactant, thus inactivating the catalyst. Advances in nanotechnology make it possible to surface engineer the catalyst so that just some desired crystal planes are exposed to reactants, maximizing the number of effective reaction sites for the desired reaction.

To date, a generalized surface dependence mechanism cannot be formulated since every surface effect is strongly reaction-specific. A few classifications of reactions based on their surface dependence have been proposed{{Cite journal|title=Structure sensitivity and nanoscale effects in electrocatalysis|journal=Nanoscale|volume=3|issue=5|pages=2054–2073|last1=Koper|first1=M.T.M.|publisher=The Royal Society of Chemistry|doi=10.1039/c0nr00857e|pmid=21399781|year=2011|bibcode=2011Nanos...3.2054K}} but there are still many exceptions that do not fall into them.

File:Platinum nanoparticles 1 38 79 116 201.jpg

The interest in reducing as much as possible the costs of the catalyst for electrochemical processes led to the use of fine catalyst powders since the specific surface area increases as the average particle size decreases. For instance, most common PEM fuel cells and electrolyzers design is based on a polymeric membrane charged in platinum nanoparticles as an electrocatalyst (the so-called platinum black).{{Cite journal|title=A comprehensive review on PEM water electrolysis|journal=International Journal of Hydrogen Energy|last1=Carmo|first1=M.|volume=38|pages=4901–4934|last2=Fritz|first2=D.L.|issue=12|doi=10.1016/j.ijhydene.2013.01.151|year=2013|last3=Mergel|first3=J.|last4=Stolten|first4=D.|bibcode=2013IJHE...38.4901C }}

Although the surface area to volume ratio is commonly considered to be the main parameter relating electrocatalyst size with its activity, to understand the particle-size effect, several more phenomena need to be taken into account:

• Equilibrium shape: for any given size of a nanoparticle there is an equilibrium shape which exactly determines its crystal planes
• Reaction sites relative number: a given size for a nanoparticle corresponds to a certain number of surface atoms and only some of them host a reaction site
• Electronic structure: below a certain size, the work function of a nanoparticle changes and its band structure fades away
• Defects: the crystal lattice of a small nanoparticle is perfect; thus, reactions enhanced by defects as reaction sites get slowed down as the particle size decreases
• Stability: small nanoparticles have the tendency to lose mass due to the diffusion of their atoms towards bigger particles, according to the Ostwald ripening phenomenon
• Capping agents: in order to stabilize nanoparticles it is necessary a capping layer, therefore part of their surface is unavailable for reactants
• Support: nanoparticles are often fixed onto a support in order to stay in place, therefore part of their surface is unavailable for reactants

Carbon nanotubes and graphene-based materials can be used as electrocatalysts.{{cite web

| last = Wang

| first = Xin

| title = CNTs tuned to provide electrocatalyst support

| publisher = Nanotechweb.org

| date = 19 January 2008

| url = http://nanotechweb.org/cws/article/tech/37366

| accessdate = 27 February 2009

| archive-url = https://web.archive.org/web/20090122040434/http://nanotechweb.org/cws/article/tech/37366

| archive-date = 22 January 2009

| url-status = dead

}} The carbon surfaces of graphene and carbon nanotubes are well suited to the adsorption of many chemical species, which can promote certain electrocatalytic reactions.{{Cite journal|last=McCreery|first=Richard L.|date=June 17, 2008|title=Advanced Carbon Electrode Materials for Molecular Electrochemistry|url=https://pubs.acs.org/doi/10.1021/cr068076m|journal=Chemical Reviews|language=en|volume=108|issue=7|pages=2646–2687|doi=10.1021/cr068076m|pmid=18557655 |issn=0009-2665}} In addition, their conductivity means they are good electrode materials. Carbon nanotubes have a very high surface area, maximizing surface sites at which electrochemical transformations can occur.{{Cite journal|last1=Wildgoose|first1=Gregory G.|last2=Banks|first2=Craig E.|last3=Leventis|first3=Henry C.|last4=Compton|first4=Richard G.|date=November 30, 2005|title=Chemically Modified Carbon Nanotubes for Use in Electroanalysis|url=http://link.springer.com/10.1007/s00604-005-0449-x|journal=Microchimica Acta|language=en|volume=152|issue=3–4|pages=187–214|doi=10.1007/s00604-005-0449-x|s2cid=93373402 |issn=0026-3672}} Graphene can also serve as a platform for constructing composites with other kinds of nanomaterials such as single atom catalysts.{{Cite journal|last1=Zhang|first1=Qin|last2=Zhang|first2=Xiaoxiang|last3=Wang|first3=Junzhong|last4=Wang|first4=Congwei|date=2021-01-15|title=Graphene-supported single-atom catalysts and applications in electrocatalysis|url=https://iopscience.iop.org/article/10.1088/1361-6528/abbd70|journal=Nanotechnology|volume=32|issue=3|pages=032001|doi=10.1088/1361-6528/abbd70|pmid=33002887 |bibcode=2021Nanot..32c2001Z |s2cid=222146032 |issn=0957-4484}} Because of their conductivity, carbon-based materials can potentially replace metal electrodes to perform metal-free electrocatalysis.{{Cite journal|last=Dai|first=Liming|date=June 13, 2017|title=Carbon-based catalysts for metal-free electrocatalysis|journal=Current Opinion in Electrochemistry|language=en|volume=4|issue=1|pages=18–25|doi=10.1016/j.coelec.2017.06.004|doi-access=free}}

Metal—organic frameworks (MOFs), especially conductive frameworks, can be used as electrocatalysts for processes such as CO₂ reduction and water splitting. MOFs provide potential active sites at both metal centers and organic ligand sites.{{Cite journal|last1=Jiao|first1=Long|last2=Wang|first2=Yang|last3=Jiang|first3=Hai-Long|last4=Xu|first4=Qiang|date=November 27, 2017|title=Metal-Organic Frameworks as Platforms for Catalytic Applications|url=http://doi.wiley.com/10.1002/adma.201703663|journal=Advanced Materials|language=en|volume=30|issue=37|pages=1703663|doi=10.1002/adma.201703663|pmid=29178384 |s2cid=205282723 }} They can also be functionalized, or encapsulate other materials such as nanoparticles. MOFs can also be combined with carbon-based materials to form electrocatalysts.{{Cite journal|last1=Singh|first1=Chanderpratap|last2=Mukhopadhyay|first2=Subhabrata|last3=Hod|first3=Idan|date=January 5, 2021|title=Metal–organic framework derived nanomaterials for electrocatalysis: recent developments for CO2 and N2 reduction|journal=Nano Convergence|language=en|volume=8|issue=1|pages=1|doi=10.1186/s40580-020-00251-6|issn=2196-5404|pmc=7785767|pmid=33403521 |bibcode=2021NanoC...8....1S |doi-access=free }} Covalent organic frameworks (COFs), particularly those that contain metals, can also serve as electrocatalysts. COFs constructed from cobalt porphyrins demonstrated the ability to reduce carbon dioxide to carbon monoxide.{{Cite journal|last1=Sharma|first1=Rakesh Kumar|last2=Yadav|first2=Priya|last3=Yadav|first3=Manavi|last4=Gupta|first4=Radhika|last5=Rana|first5=Pooja|last6=Srivastava|first6=Anju|last7=Zbořil|first7=Radek|last8=Varma|first8=Rajender S.|last9=Antonietti|first9=Markus|last10=Gawande|first10=Manoj B.|date=2020|title=Recent development of covalent organic frameworks (COFs): synthesis and catalytic (organic-electro-photo) applications|url=http://xlink.rsc.org/?DOI=C9MH00856J|journal=Materials Horizons|language=en|volume=7|issue=2|pages=411–454|doi=10.1039/C9MH00856J|s2cid=204292382 |issn=2051-6347}}

However, many MOFs are known unstable in chemical and electrochemical conditions, making it difficult to tell if MOFs are actually catalysts or precatalysts. The real active sites of MOFs during electrocatalysis need to be analyzed comprehensively.{{cite journal |last1=Zheng |first1=Weiran |last2=Liu |first2=Mengjie |last3=Lee |first3=Lawrence Yoon Suk |title=Electrochemical Instability of Metal–Organic Frameworks: In Situ Spectroelectrochemical Investigation of the Real Active Sites |journal=ACS Catalysis |date=3 January 2020 |volume=10 |issue=1 |pages=81–92 |doi=10.1021/acscatal.9b03790|hdl=10397/100175 |s2cid=212979103 |hdl-access=free }}

File:Transition Metal Complex Electrocatalysts.png

{{main|Electrolysis of water}}

File:Hydrogen_fuel_cell_schematic.jpg

Hydrogen and oxygen can be combined through by the use of a fuel cell. In this process, the reaction is broken into two half reactions which occur at separate electrodes. In this situation the reactant's energy is directly converted to electricity. Useful energy can be obtained from the thermal heat of this reaction through an internal combustion engine with an upper efficiency of 60% (for compression ratio of 10 and specific heat ratio of 1.4) based on the Otto thermodynamic cycle. It is also possible to combine the hydrogen and oxygen through redox mechanism as in the case of a fuel cell. In this process, the reaction is broken into two half-reactions which occur at separate electrodes. In this situation the reactant's energy is directly converted to electricity.{{Cite journal|last=Kunze|first=Julia|author2=Ulrich Stimming|year=2009|title=Electrochemical Versus Heat-Engine Energy Technology: A Tribute to Wilhelm Ostwald's Visionary Statements|journal=Angewandte Chemie International Edition|volume=48|issue=49|pages=9230–9237|doi=10.1002/anie.200903603|pmid=19894237|doi-access=free}}{{cite web|last=Haverkamp|first=Richard|date=3 June 2008|title=What is an electrocatalyst?|url=http://www.sciencelearn.org.nz/contexts/nanoscience/sci_media/video/what_is_an_electrocatalyst|accessdate=27 February 2009|website=|publisher=Science learning New Zealand|format=QuickTime video and transcript|archive-date=29 April 2023|archive-url=https://web.archive.org/web/20230429203758/https://www.sciencelearn.org.nz/contexts/nanoscience/sci_media/video/what_is_an_electrocatalyst|url-status=dead}}

The standard reduction potential of hydrogen is defined as 0V, and frequently referred to as the standard hydrogen electrode (SHE).{{Cite journal|last1=Elgrishi|first1=Noémie|last2=Rountree|first2=Kelley J.|last3=McCarthy|first3=Brian D.|last4=Rountree|first4=Eric S.|last5=Eisenhart|first5=Thomas T.|last6=Dempsey|first6=Jillian L.|date=2018-02-13|title=A Practical Beginner's Guide to Cyclic Voltammetry|journal=Journal of Chemical Education|language=en|volume=95|issue=2|pages=197–206|doi=10.1021/acs.jchemed.7b00361|bibcode=2018JChEd..95..197E |issn=0021-9584|doi-access=free}}

{{Main|Electrochemical reduction of carbon dioxide}}

Electrocatalysis for CO₂ reduction is not practiced commercially but remains a topic of research. The reduction of CO₂ into useable products is a potential way to combat climate change. Electrocatalysts can promote the reduction of carbon dioxide into methanol and other useful fuel and stock chemicals. The most valuable reduction products of CO₂ are those that have a higher energy content, meaning that they can be reused as fuels. Thus, catalyst development focuses on the production of products such as methane and methanol. Homogeneous catalysts, such as enzymes and synthetic coordination complexes have been employed for this purpose. A variety of nanomaterials have also been studied for CO₂ reduction, including carbon-based materials and framework materials.{{Cite journal|last1=Pan|first1=Fuping|last2=Yang|first2=Yang|date=2020|title=Designing CO 2 reduction electrode materials by morphology and interface engineering|url=http://xlink.rsc.org/?DOI=D0EE00900H|journal=Energy & Environmental Science|language=en|volume=13|issue=8|pages=2275–2309|doi=10.1039/D0EE00900H|s2cid=219737955 |issn=1754-5692}}

Aqueous solutions of methanol can decompose into CO₂ hydrogen gas, and water. Although this process is thermodynamically favored, the activation barrier is extremely high, so in practice this reaction is not typically observed. However, electrocatalysts can speed up this reaction greatly, making methanol a possible route to hydrogen storage for fuel cells. Electrocatalysts such as gold, platinum, and various carbon-based materials have been shown to effectively catalyze this process. An electrocatalyst of platinum and rhodium on carbon backed tin-dioxide nanoparticles can break carbon bonds at room temperature with only carbon dioxide as a by-product, so that ethanol can be oxidized into the necessary hydrogen ions and electrons required to create electricity.

{{cite web

|last = Harris

|first = Mark

|title = Booze-powered cars coming soon

|publisher = techradar.com

|date = 26 January 2009

|url = http://www.techradar.com/news/world-of-tech/booze-powered-cars-coming-soon-513666

|accessdate = 27 February 2009

|url-status = dead

|archiveurl = https://web.archive.org/web/20090302025300/http://www.techradar.com/news/world-of-tech/booze-powered-cars-coming-soon-513666

|archivedate = 2 March 2009

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Electrocatalysts are used to promote certain chemical reactions to obtain synthetic products. Graphene and graphene oxides have shown promise as electrocatalytic materials for synthesis.{{Cite journal|last=Sachdeva|first=Harshita|date=2020-09-30|title=Recent advances in the catalytic applications of GO/rGO for green organic synthesis|journal=Green Processing and Synthesis|volume=9|issue=1|pages=515–537|doi=10.1515/gps-2020-0055|issn=2191-9550|doi-access=free}} Electrocatalytic methods also have potential for polymer synthesis.{{Cite journal|last1=Siu|first1=Juno C.|last2=Fu|first2=Niankai|last3=Lin|first3=Song|date=2020-03-17|title=Catalyzing Electrosynthesis: A Homogeneous Electrocatalytic Approach to Reaction Discovery|url= |journal=Accounts of Chemical Research|language=en|volume=53|issue=3|pages=547–560|doi=10.1021/acs.accounts.9b00529|issn=0001-4842|pmc=7245362|pmid=32077681}} Electrocatalytic synthesis reactions can be performed under a constant current, constant potential, or constant cell-voltage conditions, depending on the scale and purpose of the reaction.{{Cite journal|last1=Holade|first1=Yaovi|last2=Servat|first2=Karine|last3=Tingry|first3=Sophie|last4=Napporn|first4=Teko W.|last5=Remita|first5=Hynd|last6=Cornu|first6=David|last7=Kokoh|first7=K. Boniface|date=2017-10-06|title=Advances in Electrocatalysis for Energy Conversion and Synthesis of Organic Molecules|journal=ChemPhysChem|language=en|volume=18|issue=19|pages=2573–2605|doi=10.1002/cphc.201700447|pmid=28732139 |issn=1439-4235|doi-access=free}}

Water treatment systems often require the degradation of hazardous compounds. These treatment processes are dubbed Advanced oxidation processes, and are key in destroying byproducts from disinfection, pesticides, and other hazardous compound. There is an emerging effort to enable these processes to destroy more tenacious compounds, especially PFAS{{cite journal | last1=Ji | first1=Yangyuan | last2=Choi | first2=Youn Jeong | last3=Fang | first3=Yuhang | last4=Pham | first4=Hoang Son | last5=Nou | first5=Alliyan Tan | last6=Lee | first6=Linda S. | last7=Niu | first7=Junfeng | last8=Warsinger | first8=David M. | title=Electric Field-Assisted Nanofiltration for PFOA Removal with Exceptional Flux, Selectivity, and Destruction | journal=Environmental Science & Technology | publisher=American Chemical Society (ACS) | date=2023-01-19 | volume=57 | issue=47 | pages=18519–18528 | issn=0013-936X | doi=10.1021/acs.est.2c04874 | pmid=36657468 | bibcode=2023EnST...5718519J | s2cid=256030682 }}

• {{cite journal |title=Co-axial heterostructures integrating palladium/titanium dioxide with carbon nanotubes for efficient electrocatalytic hydrogen evolution |year=2016 |last1=Valenti |first1=G. |last2=Boni |first2=A. |last3=Melchionna |first3=M. |last4=Cargnello |first4=M. |last5=Nasi |first5=L. |last6=Bertoli |first6=G. |last7=Gorte |first7=R. J. |last8=Marcaccio |first8=M. |last9=Rapino |first9=S. |last10=Bonchio |first10=M. |last11=Fornasiero |first11=P. |last12=Prato |first12=M. |last13=Paolucci |first13=F. |journal=Nature Communications |volume=7 |pages=13549|bibcode=2016NatCo...713549V |doi=10.1038/ncomms13549 |pmid=27941752 |pmc=5159813 }}

• Electrochemistry
• Catalysis
• Electrolysis of water
• Non-faradaic electrochemical modification of catalytic activity
• Tafel equation

{{Reflist}}

Category:Electrochemistry

Category:Catalysis