Electrosynthesis Exchange

Benchtop Power Supplies:

Many available, but here are two examples:

These are often the most economical options for bulk electrolysis experiments. Note, they do not allow for the use of reference electrodes, alternating currents and cannot be used for analytical measurements (CV). Most of the benchtop power supplies are single output and lack programmability but are a good starting point for conducting bulk electrolysis. If the potential range is high enough, one can daisy-chain reactions to run several reactions at the same time at the same current using a single power supply, since electrical current is constant throughout a circuit.

Given the high currents and potentials required for flow electrochemistry, a power supply like these is often necessary (provided the flow system does not come with its own integrated power supply).

Safety note:

Some benchtop power supplies can provide very high potential and currents, so always exercise caution.

All in one electrochemical setup: IKA ElectraSyn 2.0

The IKA ElectraSyn is a power source and stirrer plate, to be used with Electrasyn compatible vials, lids, and electrodes. The ElectraSyn is designed to enable a synthetic chemist to run electrochemical reactions with ease, as it is all clip-in/plug-in. The integrated display of the ElectraSyn allows you to set up the exact electrochemical parameters and will calculate the charge and time required for you. As the components and cell set-ups are standardised, repeating reactions in Electrosyn is facile.

Potentiostats/Galvanostats: Analytical instruments that can do preparative chemistry

Suppliers:

These are powerful, more expensive instruments that can perform a wide range of analytical (CV, LSW, SQV) and bulk electrolysis experiments (chronopotentiometry and chronoamperometry, including variable waveforms), as well as in many cases, impedance spectroscopy. Multi channel options are also available for conducting multiple reactions simultaneously and dense data outputs are generated, which can aid rapid reaction development.

There are also several more economical/homemade alternatives:

1. Building a Microcontroller Based Potentiostat: A Inexpensive and Versatile Platform for Teaching Electrochemistry and Instrumentation | Journal of Chemical Education

2. An Easily Fabricated Low-Cost Potentiostat Coupled with User-Friendly Software for Introducing Students to Electrochemical Reactions and Electroanalytical Techniques | Journal of Chemical Education

3. A Small yet Complete Framework for a Potentiostat, Galvanostat, and Electrochemical Impedance Spectrometer | Journal of Chemical Education

4. Minimizing Hazardous Waste in the Undergraduate Analytical Laboratory: A Microcell for Electrochemistry | Journal of Chemical Education

General Considerations for Choosing a Power Source

The use of a power source in the lab can fall broadly into two categories: analytical electrochemistry (CV, LSW, SWV, EIS) and preparative electrochemistry (bulk electrolysis). It may be better to buy separate equipment for these two applications, although some equipment can do most of the two mostly quite well. Many instruments come with a wide range of parameters and deciding which are important for your application can be confusing. Below is a breakdown of some factors to consider when deciding what equipment is best.

1. Maximum potential/current ranges and potential/current accuracy

When considering maximum potentials required, most small scale (<1 mmol/100 mM) bulk electrolysis requires less than 30V and a potential accuracy of 100 mV is sufficient. Similarly, a current output of 50 mA will suffice for most lab-scale batch electrolysis reactions, but current accuracy should be considered more carefully. ±1 mA is common for lower end power supplies, but as many reported procedures require low current intensities (~10 mA) the error associated in the current supplied can be substantial. For these types of applications an accuracy of ±0.1 mA is better. It should be noted that large scale batch reactions or flow electrochemistry will often exceed these current or potential ranges.

2. Waveform requirements.

Depending on the type of electrolysis required you may require a power supply that is capable of both constant current and constant potential electrolysis. Alternative waveforms (such as alternating polarity) are not as widely used as constant potential or constant current electrolysis, but can be situationally useful, so the ability to perform these should also be considered.

3. Programmability and data output.

The ability to set an automatic power cut-off after a specified time or charge applied threshold is reached is useful for performing reactions without having to constantly monitor it. Most power supplies offer these cut-offs. The benchtop power supplies can be easily controlled with inexpensive wall timers. The data outputs available from the more expensive instruments allow for greater analysis of reaction data (observed currents/potentials) and can be useful in reaction development.

4. Reference electrode compatibility

Instruments that can operate in a three-electrode configuration (with a reference electrode) are necessary for analytical experiments, such as cyclic voltammetry. These are not necessary if trying to reproduce literature conditions (assuming the procedure does not call for a reference electrode). The use of a reference electrode allows for the monitoring of half-cell processes independently and can be very useful for reaction monitoring and optimization.

Electrode Materials

Electrode Material	Product Code / Description	Supplier	Country of Supplier	Link to Product	Example Publication
Boron-Doped Diamond	Condias Diachem	Condias	Germany	🛒	📰
Glassy Carbon	Sigradur G or K	HTW	Germany	🛒	📰
Platinum Plate	ChemPur, 009330-25X25	LoLab	Germany	🛒	📰
RVC	SGL Carbon SIGRACELL® GFA 6EA	SGL Carbon	Germany	🛒	📰
Carbon Felt	GF-20-P21E	Nippon Carbon	Japan	🛒	📰
Graphite Plate	JL-PMC-50071	JING DE LONG	P.R. China	🛒	📰
Nickel Foam	For Battery,Electric Capacity etc Nickel Foam 1.5MM x 250MM x 200mm	ExtendTrade	P.R. China	🛒	📰
Platinum Plate	Pt213-Pt262	Tianjin Aida	P.R. China	🛒	📰
RVC	VC003810	Goodfellow	South Korea	🛒	📰
Carbon Foil	VC00-FL-000100	Goodfellow	UK	🛒	📰
Nickel Plate	NI00-FL-000108	Goodfellow	UK	🛒	📰
Platinum Wire	PT5441 Platinum Wire	Advent Research Materials	UK	🛒	📰
Platinum Wire	13039.BU	Alfa-Aesar	UK	🛒	📰
RVC	VC00-FA-000125	Goodfellow	UK	🛒	📰
Carbon Felt	AvCarb C200 Soft Carbon Battery Felt	FuelCellStore	USA	🛒	📰
Graphite Felt	AvCarb G200 Graphite Felt	FuelCellStore	USA	🛒	📰
Graphite Plate	9121K61	McMaster-Carr	USA	🛒	📰
Graphite Rod	9121K71	McMaster-Carr	USA	🛒	📰
Nickel Foam	EQ-bcnf-16m-2	MTI Corporation	USA	🛒	📰
Nickel Plate	#19920	Online Metals	USA	🛒	📰
RVC	Duocel RVC Panel	Duocel	USA	🛒	📰
RVC	Ultramet 80PPI	Ultramet	USA	🛒	📰
Glassy Carbon	GC-20	Tokai Carbon	USA/Japan	🛒	📰

Electrode Cleaning

Electrode Material	Link to Publication	Cleaning Process
Aluminium	📰	Sandpaper as needed. Care with acid & base as this will dissolve surface. Wash with water and acetone
BDD	📰	A new type of carbon electrode material is electrically conducting diamond doped with boron, which is grown as a thin film on a conducting substrate [33]. Boron-doped diamond electrode is very hard and can be used in the combination with ultrasonic mixing [34]. Furthermore, it is characterized by the wide working window, low and stable background current and corrosion resistance. Contaminants adsorbed on the electrode surface can be removed by the exposure to clean organic solvents for half an hour [35], or by heating the electrode to about 500◦C under high-vacuum conditions for 30 min [36]. Electrochemical activation is achieved by potential cycling between −0.5 V and 1.5 V vs. SCE in 0.5 M KNO3 at 50 mV/s [37
BDD	📰	Using the electrode as the anode in a ~1 M solution of sulfuric acid and running a constant potential of 1-3 V for a few minutes can help clean the electrode by oxidizing impurities on the surface. This procedure however should only be used for glassy carbon and the boron doped diamond electrodes. Do not sandpaper
Copper	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Copper	📰	Clean copper electrodes by first wiping with acetone, then sanding, wiping with dilute HCl (to remove loose copper particles) and rinsing with acetone
Copper-coated graphite	📰	The electrodes were carefully cleaned with water and acetone
Glassy Carbon	📰	Using the electrode as the anode in a ~1 M solution of sulfuric acid and running a constant potential of 1-3 V for a few minutes can help clean the electrode by oxidizing impurities on the surface. This procedure however should only be used for glassy carbon and the boron doped diamond electrodes.
Glassy Carbon	📰	polished with an alumina slurry if necessary but often rinsing is enough. In addition, several cyclic voltammograms with dilute sulfuric acid can clean contaminants within the electrode
Glassy Carbon	📰	Rinse with water then MeOH, wet polishing pad with distilled water, add alumina suspension and polish, polish in fig 8, rinse with distilled water. Sonicate for 5 mins in distilled water if necessary
Glassy Carbon	📰	Glassy carbon GC electrodes were chemical and electrochemically pretreated before electropolymerization of o-AP. The electrode surfaces were polished carefully to a mirror finish and then cleaned ultrasonically with triply distilled water for 3 min. This kind of electrode was denoted in [15] as an “untreated” electrode. In addition, electrochemical treatment of the electrodes was achieved by placing the polished electrodes in 0.1 M H2SO4 at 1.85 V (SCE) for 5 min, and then they were cycled between −0.2 V and 0.7 V for 15 min. Chemical pretreatment of the electrodes was achieved by immersing the electrodes in concentrated nitric acid (67% wt/wt) and sulfuric acid (98% wt/wt)
Gold	📰	In acidic aqueous electrolytes (e.g., 0.5 mol/L H2SO4), platinum forms surface oxides at about 1 V vs. SCE, which can be reductively dissolved at about 0.8 V [12]. At potentials lower than 0.4 V, a platinum electrode is covered with adsorbed hydrogen. These surface reactions cause high background currents in a wide potential range. They also change the characteristics of the electrode surface. Hence, in many cases, a platinum electrode must be re-polished after each electrochemical measurement. Both platinum and gold electrodes are activated by polishing with alumina slurry on a smooth glass plate. The sizes of alumina particles are between 1 μm and 0.05 μm. The polishing starts with the largest size and continues using successively smaller sizes. After a mirror-like finish is obtained, the electrode is cleaned by rinsing with deionized water and ultrasonication in water for 15 min. For the best results the electrode should be used immediately after polishing [1
Gold Plated	📰	1M NaOH, 1 M HCl, no sandpaper. Wash with water and acetone
Graphite	📰	first rinsing the electrode with the reaction solvent and then cleaning it in an ultrasonic bath with reaction solvent, then acid, water and again the reaction solvent
Graphite	📰	Graphite electrodes could be used several times by renewing the top surface of the graphite. This was achieved by scraping away the top layer with a razor blade, sonicating in MeCN for 5 minutes, followed by oven-drying for 30 mins
Graphite	📰	was polished with 400-grit sandpaper, rinsed and cleaned in 1 N HCl for 16 hours.
Graphite	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Lead	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Leaded Bronze	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Magnesium	📰	1M NaOH, sandpaper as needed. Care with HCl as this will dissolve surface. Wash with water and acetone
Metal Electrodes	📰	Unless they are coated, can be sanded with fine sandpaper (i.e. P1200). Electrodes with a metal coating can only be rinsed and wiped down
Nickel	📰	cleaned by immersion in warm dilute hydrochloric acid and boiling distilled water
Nickel	📰	Rinse with water then MeOH, wet polishing pad with distilled water, add alumina suspension and polish, polish in fig 8, rinse with distilled water. Sonicate for 5 mins in distilled water if necessary
Nickel	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Nickel Foam	📰	Nickel foam (about 3.3 cm x 1 cm) was carefully cleaned with the concentrated HCl solution (37 wt.%) in an ultrasound bath for 5 min in order to remove the surface oxide layer. And then deionized water and absolute ethanol were used for 5 min each to ensure the surface of the Ni foam was well cleaned.
Nickel Foam	📰	Nickel foam (about 3.3 cm x 1 cm) was carefully cleaned with concentrated HCl solution (37 wt.%) in an ultrasound bath for 5 min in order to remove the surface oxide layer. And then deionized water and absolute ethanol were used for 5 min each to ensure the surface of the Ni foam was well cleaned.
Nickel Foam	📰	1M NaOH, 1 M HCl, no sandpaper. Wash with water and acetone
Niobium	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Platinum	📰	can be flame cleaned to remove any oxide layer for very sensitive processes.
Platinum	📰	Cleaned by heating to red-hot in a flame
Platinum	📰	The former were prepared from electrodes cleaned as described previously, which were then polarized cathodically to hydrogen evolution and then anodically for 5 min at 25 mA cm-2 in acetate solution. They were finally cleaned again by boiling in concentrated hydrochloric acid, washing with water and standing overnight in a sulphuric-nitric acid cleaning mixture.
Platinum	📰	“ Reduced ” electrodes were prepared by polarizing cleaned electrodes for 30 min at a constant potential of 0.1 V more positive than the reversible hydrogen electrode.
Platinum	📰	Clean the Pt electrode by submerging it in concentrated nitric acid (~70%) for 5 min, followed by rinsing it with water and then acetone. Run the Pt plate through the flame of a butane torch until it glows orange. Allow it to cool for 1 min before any future use.
Platinum	📰	Pt microelectrode was cleaned by polishing in 50 nm alumina slurry and rinsed with acetone
Platinum	📰	Alternate the polarity of the working electrode by setting the potential to 500 mV and switching the polarity switch between (+) and (-). Perform at least 10 cycles, pausing at each potential for a few seconds. Return the potential to the desired value and test the response with a standard solution. If the response does not improve, disassemble the cell and polish the electrode with a methanol-soaked lab tissue. Use firm pressure. Rinse the block with methanol and reassemble. Proceed polishing with abrasives only if the response is still too low compared to earlier performance.
Platinum	📰	Aqua Regia, Pulse electrolysis then flame treatment. See paper for full details of each step
Platinum Plated	📰	1M NaOH, care with acid, definitely no sandpaper
Platinum Wire	📰	After each reaction, the electrodes are left to soak in a saturated aqueous Ca2CO3 solution for 10 minutes. After this they were rinsed with water, washed with acetone then left to dry in a 70 ⁰C for several hours before use. Occasionally, there was an amorphous film that is resistant to cleaning, thus at this point the platinum wire is unwound and cleaned with a paper towel soaked in acetone. After re-winding the platinum wire around the PTFE tube, the electrodes are used to apply a potential difference of 10 V to a solution of CH3CN and nBu4NBF4 (0.2M) for 30 minutes. After this the electrodes are re-cleaned with acetone and left to dry in a 70 ⁰C for several hours before use.
RVC	📰	Wash with 1 N HCl, H2O several times, and acetone, sequentially, and allow to dry before setting up the next reaction. If the exterior of electrodes is shiny black with a metallic luster obviously, we recommend you do not reuse them again
RVC	📰	1M NaOH, 1 M HCl, sandpaper not appropriate as electrode is fragile. Wash with water and acetone
Silver	📰	After each electrolysis, the silver-gauze working electrode was cleaned by using ultrasonication in an aqueous sodium bicarbonate paste for 30 min; it was then rinsed with distilled water and dried in an oven at 180 °C.
Silver	📰	Rinse with water then MeOH, wet polishing pad with distilled water, add alumina suspension and polish, polish in fig 8, rinse with distilled water. Sonicate for 5 mins in distilled water if necessary
Silver Plated	📰	1M NaOH, 1 M HCl, no sandpaper. Wash with water and acetone
Stainless Steel	📰	The stainless steel electrodes were cleaned with ethanol-acetone mixture 50-50% (v/v), then with a fluoronitric acid solution 2-20%, and finally thoroughly washed with distilled water.
Stainless Steel	📰	1M NaOH, sandpaper as needed. Care with HCl as this will dissolve surface. Wash with water and acetone
Tin	📰	Before each use, the surface of electrodes is polished with 1000 grit sandpaper and sonicated in acetone. After wiping the surface with a paper towel, the electrodes are dried and kept under high vacuum
Tin	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Titanium	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Tungsten	📰	1M NaOH, 1 M HCl, sandpaper as needed. Wash with water and acetone
Zinc	📰	Before each use, the surface of electrodes is polished with 1000 grit sandpaper and sonicated in acetone. After wiping the surface with a paper towel, the electrodes are dried and kept under high vacuum
Zinc	📰	Sandpaper as needed. Care with acid & base as this will dissolve surface. Wash with water and acetone

Batch Reactors

1. IKA Electrasyn

The Electrasyn reactionware setup consists of a standardized cell, lid and electrode system that is compatible with the Electrasyn potentiostat. It is also possible to power chemistry in other reactors using the Electrasyn by making connections from the Electrasyn lid.

2. Merck SynLectro

This is Merck's range of standardised electrochemical reactors. The range includes cells, lids, electrode holders and electrodes.

3. Homemade Cells/Other Glassware

In many cases, standard reaction glassware can be used as an electrochemical cell for undivided batch reactions. For example, a multi-neck round-bottomed flask is a convenient cell choice as each inlet can hold its own electrode, allowing flexibility in inter-electrode distance and immersion in the reaction mixture. These systems can be delicate for smaller scale reactions involving only small amounts of solvent and sometimes a narrower vessel such as a Schlenk tube can be a better way to maximize electrode immersion. Standard seals can be easily adapted to hold electrodes (example in SI).

Flow Cells

To conduct electrochemistry in flow three main components are required; a pump, a power source and a flow cell with electrodes. Some suppliers offer an all-in-one system but it can be more economical and adaptable to source each component individually. Often, for smaller scale flow reactions standard syringe-pumps can be repurposed as pumps for these flow cells. It should also be kept in mind that electrochemistry in flow often has a higher current and potential requirement than in batch and therefore a more powerful power supply may be needed.

1. IKA ElectraSyn-Flow

IKA's electrochemical flow system. The platform includes a flow cell with interchangeable electrodes, a power supply and an optional pump.

2. Vapourtec

Vapourtec is well known for standard flow chemical equipment. They also produce an electrochemical flow cell that is compatible with their other products.

3. Ammonite

Ammonite produce a circular microflow cell in two sizes. The cells are compatible with standard pumps and power supplies

4. Hzcell

Hzcell offer a microfluidic electrolysis flow cell. The cell is available with or without a pump and can be supplied with a variety of electrode materials. The cell offers flexibility in other parameters such as electrode separation and reactor temperature control.

5.C-Tech Innovation

The C-Tech Innovation C-Flow product line consists of electrochemical flow cells of various sizes, suitable for small scale up to production scale chemistry. Some cells can be configured as divided and undivided setups.

6. ElectroCell

The ElectroCell product line ranges from small scale micro flow reactors to production scale setups. A range of electrode materials are available and the cells can be configured in both divided and undivided modes.

3D-Printed Reactionware

3D-Printing reactionware for electrochemistry offers an affordable alternative to many commercial products. The Lennox group has developed a series of undivided and divided cells that can be easily printed 3D-printed. For further details see the full publication here. The .STL files are available here.