Quick Cart
Subtotal: $0.00
WaveVortex 10 Electrode Rotator
Part Number
AF01WV10
The WaveVortex® 10 is a compact research-grade electrode rotator design from Pine Research. With a small footprint, the WaveVortex 10 is the ideal instrument for precision Rotating Disk Electrode (RDE) and Rotating Ring-Disk Electrode (RRDE) experiments in laboratories with space constraints or when working inside a glovebox. The WaveVortex 10 design combines the rotator, control unit, shaft, and enclosure in one convenient package. The WaveVortex 10 is compatible a wide variety of standard RDE and RRDE electrodes manufactured by Pine Research, along with many of our cells, glassware, and accessories. Unique features of this rotator include: small fooprint, includes RDE/RRDE shaft intended for permanent installation, updated control unit with start/stop/pause features, and an integrated enclosure and motor interlock.
Related Product Bundles
This product is available in related bundles. View related bundles in the tab below.
Product Parts List
This product consists of separately available parts. View the parts list in the tab below.
Login to View Prices
Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.
Electrodes sold separately.
Given the wide range of electrodes we offer, rotators do not include electrodes (RDE, RRDE, RCE) and must be purchased separately. This way, you can select the perfect electrode for your applications.
Specify Power Cord
This product requires a power cord to connect to AC mains. Please specify the plug style used in your region when you order this product. We stock a variety of power cords.
Maximum Rotation Rate
All rotating electrodes, including RDE, RRDE, and RCE, have an assigned maximum rotation rate. The maximum rotation rate is specific to each electrode series. Do not exceed the maximum rotation rate when working with rotating electrodes.
The WaveVortex 10 Electrode Rotator is available as part of a product bundle. A product bundle is a combination of products that are compatible and often sold together for convenience and confidence. Below is a list of product bundles that contain WaveVortex 10 Electrode Rotator.
Bundled with RDE Electrode and Electrochemical Cell
Bundled with RRDE electrode and Electrochemical Cell
Bundled with WaveDriver 200 Electrochemical Workstation
Image
Bundle Name
Bundle Part #
Bundle Link
Complete RRDE System Bundle: WaveDriver 200, WaveVortex 10, E6R1 Series RRDE
[WD200-WV10-RRDE-E6R1]
Complete RRDE System Bundle: WaveDriver 200, WaveVortex 10, E8R4 Series RRDE
[WD200-WV10-RRDE-E8R4]
Bundled with WaveDriver 100 Electrochemical Workstation
Bundled with WaveDriver 40 Electrochemical Workstation
Image
Bundle Name
Bundle Part #
Bundle Link
Complete RRDE System Bundle: WaveDriver 40, WaveVortex 10, E8R4 Series RRDE
[WD40-WV10-RRDE-E8R4]
Complete RRDE System Bundle: WaveDriver 40, WaveVortex 10, E6R1 Series RRDE
[WD40-WV10-RRDE-E6R1]
Bundled with WaveNow Wireless Electrochemical Workstation
WaveVortex 10 Electrode Rotator is a single product with individual parts that may be purchased separately. The data below aggregates the specifications for each part in this product.
WaveVortex 10 Electrode Rotator
Electrode Rotator
Motor
Motor bandwidth
Undetermined
Control method
Closed loop servo-system (PWM); temperature-compensated tachometer mounted on motor shaft
Maximum continuous torque
18.7 mN·m
Motor power
11 W
Motor protection
Motor current is electronically limited
Motor type
Permanent Magnet
Slew rate
Undetermined
Electrical
Electrode connections
Disk electrode: red banana jack on motor unit; ring electrode: blue banana jack on motor unit
Rotator AC power input
100 - 240 VAC, ±10%, 50/60 Hz, 2 A
Rotator DC power supply
24 VDC, 1.5 A (included)
Power switch location
Side of unit
Grounding
Rotator chassis terminal
Metal banana jack on motor unit, Second connection provided on external I/O port
DC common (analog ground)
Connection provided on external I/O port
Rotator earth ground
No direct connection available
Rotation Rate
Enclosure interlock
Interlock prevents rotation when enclosure window is in raised position. Front panel LED indicates enclosure interlock state.
Motor stop connection
Optional digital motor stop input signal on external I/O port, available TTL logic: active high or active low, jumper selectable, front panel LED indicates when external motor stop is active
Rate accuracy
100 – 200 RPM: accurate to within ±2 counts of display reading; 200 – 8,000 RPM: accurate to within ±1% of display reading
External rate control
Optional rate control via input signal on external I/O port; available control ratios: 1, 2, or 4 RPM/mV, jumper selectable
Rate display
4 digit display indicates rotation rate (RPM)
Rate output
Optional rate monitoring via output signal on external I/O port; output signal ratio: 2 RPM/mV
Rotation rate control
10-turn rotation rate control knob on control unit front panel
Start/stop (front panel)
Push-button toggle on front panel with LED indicators for “pause” and “run”
Physical
Rotator dimensions
380 × 280 × 380 mm (15 × 11 × 15 in) with enclosure window lowered, 380 × 280 × 610 mm (15 × 11 × 24 in) with enclosure window raised
Electronics cabinet material
Black powder-coated aluminum
Enclosure base and sides materials
Black high-density polyethylene (PE)
Enclosure window material
Clear polycarbonate (PC)
Operating temperature
10 °C - 40 °C (50 °F - 104 °F)
Rotator shipping weight
11 kg (24 lb)
Rotator shipping dimensions
41 × 41 × 41 cm (16 × 16 × 16 in)
Safety & Environmental
Rotator RoHS compliant
Yes
Rotator safety certification
CE, ETL
Compatibility
Compatible electrode tips
WaveVortex 10 Rotating Shaft
Electrode Rotator
Compatibility
Compatible electrode tips
Applications
Rotating application
Electrode Shafts
Shaft length (overall)
126 mm (4.95 in)
Shaft shroud diameter
Shaft shroud length
66 mm
Shaft shroud material
Shaft rotator compatibility
Power Cords
WaveVortex 10 Electrode Rotator is sold as a simple product; however, customers may wish to order replacement or additional components of this product. We call these "parts" of the product. Should you want more details on individual parts of this product or wish to order an additional or replacement part, refer to the list of parts below with links to their product page.
Image
Product Name
Part #
Quantity
Price
Actions
WaveVortex 10 Standard Brush Assembly
AC01WV10S05
2
Login to View Prices
Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.
WaveVortex 10 Low-Humidity Brush Assembly
AC01WV10S05LH
2
Login to View Prices
Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.
WaveVortex 10 Rotating Shaft
AC01WV10S07
1
Login to View Prices
Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.
WaveVortex 10 Power Supply
EE24V17A
1
Login to View Prices
Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.
Power Cords
POWER-CORD
1
Login to View Prices
Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.
- Pandey, S.; Dubey, S.; Singh, V.; Ganesan, V. Vanadium-Doped FeNiSe4 as a High-Performance Oxygen Evolution Electrocatalyst: Synergistic Effects of Se–Ni–Fe Hybridization and Vanadium-Induced Electronic Modulation. ACS Applied Energy Materials 2025.
- Vo, T.; Ng, Y.; Thangasamy, P.; Venkatramanan, R.; Goh, W.; Bu, J.; Gao, J.; Liu, Y. Sustainable carbon-negative mineral extraction from desalination brine. Applied Catalysis B: Environment and Energy 2024, 357, 124321.
- Zuccante, G.; Acciarri, M.; Vecchio, C.L.; Gatto, I.; Baglio, V.; Pianta, N.; Ruffo, R.; Navarini, L.; Santoro, C. Oxygen reduction reaction platinum group metal-free electrocatalysts derived from spent coffee grounds. Electrochim. Acta 2024, 492, 144353.
- van der Minne, E.; Korol, L.; Krakers, L.M.A.; Verhage, M.; Rosário, C.M.M.; Roskamp, T.J.; Spiteri, R.J.; Biz, C.; Fianchini, M.; Boukamp, B.A.; Rijnders, G.; Flipse, K.; Gracia, J.; Mul, G.; Hilgenkamp, H.; Green, R.J.; Koster, G.; Baeumer, C. The effect of intrinsic magnetic order on electrochemical water splitting. Appl. Phys. Rev. 2024, 11, 011420.
- Zuccante, G.; Muhyuddin, M.; Ficca, V.C.A.; Placidi, E.; Acciarri, M.; Lamanna, N.; Franzetti, A.; Zoia, L.; Bellini, M.; Berretti, E.; Lavacchi, A.; Santoro, C. Transforming Cigarette Wastes into Oxygen Reduction Reaction Electrocatalyst: Does Each Component Behave Differently? An Experimental Evaluation. ChemElectroChem 2024, 11, e202300725.
- Islam, T. Iron Phthalocyanine Functionalized Boron Doped Graphene as an Inexpensive Cathode Catalyst for Alkaline Fuel Cells - ProQuest. Master's Thesis, New Mexico Institute of Mining and Technology, 2024.
- Diaz-Morales, O.; Lindberg, A.; Smulders, V.; Anil, A.; Simic, N.; Wildlock, M.; Alvarez, G.S.; Mul, G.; Mei, B.; Cornell, A. Catalytic effects of molybdate and chromate–molybdate films deposited on platinum for efficient hydrogen evolution. Journal of Chemical Technology & Biotechnology 2023, 98, 1269-1278.
- Giordano, E.; Berretti, E.; Capozzoli, L.; Lavacchi, A.; Muhyuddin, M.; Santoro, C.; Gatto, I.; Zaffora, A.; Santamaria, M. Boosting DMFC power output by adding sulfuric acid as a supporting electrolyte: Effect on cell performance equipped with platinum and platinum group metal-free cathodes. J. Power Sources 2023, 563, 232806.
- Mirshokraee, S.A.; Muhyuddin, M.; Morina, R.; Poggini, L.; Berretti, E.; Bellini, M.; Lavacchi, A.; Ferrara, C.; Santoro, C. Upcycling of waste lithium-cobalt-oxide from spent batteries into electrocatalysts for hydrogen evolution reaction and oxygen reduction reaction: A strategy to turn the trash into treasure. J. Power Sources 2023, 557, 232571.
- Lenne, Q.; Mattiuzzi, A.; Jabin, I.; Troian-Gautier, L.; Hamon, J.; Leroux, Y.R.; Lagrost, C. Chemical Surface Grafting of Pt Nanocatalysts for Reconciling Methanol Tolerance with Methanol Oxidation Activity. ChemSusChem 2023, 16, e202201990.
- Tran, T.S.; Balu, R.; Nguyen, C.K.; Mata, J.; Truong, V.K.; Dutta, N.K.; Choudhury, N.R. Graphene Nanosheets Stabilized by P3HT Nanoparticles for Printable Metal-Free Electrocatalysts for Oxygen Reduction. ACS Appl. Nano Mater. 2023, 6, 908-917.
- Li, J.; Liu, P.; Yan, J.; Huang, H.; Song, W. Fully-Conjugated Covalent Organic Frameworks with Two Metal Sites for Oxygen Electrocatalysis and Zn–Air Battery. Advanced Science 2023, 10, 2206165.
- Sang Tran, T.; Balu, R.; Campo, L.d.; Kumar Dutta, N.; Roy Choudhury, N. Sulfonated polythiophene-interfaced graphene for water-redispersible graphene powder with high conductivity and electrocatalytic activity. Energy Advances 2023, 2, 365-374.
- Caianiello, C.; Arenas, L.F.; Turek, T.; Wilhelm, R. A Hydroxylated Tetracationic Viologen based on Dimethylaminoethanol as a Negolyte for Aqueous Flow Batteries. Batteries & Supercaps 2023, 6, e202200355.
- Muhyuddin, M.; Testa, D.; Lorenzi, R.; Vanacore, G.M.; Poli, F.; Soavi, F.; Specchia, S.; Giurlani, W.; Innocenti, M.; Rosi, L.; Santoro, C. Iron-based electrocatalysts derived from scrap tires for oxygen reduction reaction: Evolution of synthesis-structure-performance relationship in acidic, neutral and alkaline media. Electrochim. Acta 2022, 433, 141254.
- Testa, D.; Zuccante, G.; Muhyuddin, M.; Landone, R.; Scommegna, A.; Lorenzi, R.; Acciarri, M.; Petri, E.; Soavi, F.; Poggini, L.; Capozzoli, L.; Lavacchi, A.; Lamanna, N.; Franzetti, A.; Zoia, L.; Santoro, C. Giving New Life to Waste Cigarette Butts: Transformation into Platinum Group Metal-Free Electrocatalysts for Oxygen Reduction Reaction in Acid, Neutral and Alkaline Environment. Catalysts 2022, 13, 635.
- Li, X.; Fang, Y.; Wang, J.; Fang, H.; Xi, S.; Zhao, X.; Xu, D.; Xu, H.; Yu, W.; Hai, X.; Chen, C.; Yao, C.; Tao, H.B.; Howe, A.G.R.; Pennycook, S.J.; Liu, B.; Lu, J.; Su, C. Ordered clustering of single atomic Te vacancies in atomically thin PtTe2 promotes hydrogen evolution catalysis. Nat. Commun. 2021, 12, 2351.
- Smulders, V.; Gomes, A.S.O.; Simic, N.; Mei, B.; Mul, G. Mixed Chromate and Molybdate Additives for Cathodic Enhancement in the Chlorate Process. Electrocatalysis 2021, 12, 447-455.
- Osipova, D. Nanostructured carbon from biomass as a catalyst for energy conversion devices. Master's Thesis, Aalto University, 2021.
- Pérez, B.L.V.; Fonseca, F.N.S.; Gonzalez-Aponte, K.M.; Cunci, L. Electrochemical Synthesis of Polyaniline on Onion-like Carbon Nanoparticles Using the RoDSE Technique. ECS Trans. 2020, 98, 595.
- Narulkar, D.D.; Devulapally, K.; U, A.K.; Dhuri, S.N.; Dhavale, V.M.; Vardhaman, A.K.; Giribabu, L. A novel nonheme manganese(II) complex for (electro) catalytic oxidation of water. Sustainable Energy & Fuels 2020, 4, 2656-2660.
- Lee, K.J.; Gruninger, C.T.; Lodaya, K.M.; Qadeer, S.; Griffith, B.E.; Dempsey, J.L. Analysis of multi-electron, multi-step homogeneous catalysis by rotating disc electrode voltammetry: theory, application, and obstacles. Analyst 2020, 145, 1258-1278.
- San Roman, D.; Krishnamurthy, D.; Garg, R.; Hafiz, H.; Lamparski, M.; Nuhfer, N.T.; Meunier, V.; Viswanathan, V.; Cohen-Karni, T. Engineering Three-Dimensional (3D) Out-of-Plane Graphene Edge Sites for Highly Selective Two-Electron Oxygen Reduction Electrocatalysis. ACS Catal. 2020, 10, 1993-2008.
- Todoroki, N.; Wadayama, T. Heterolayered Ni–Fe Hydroxide/Oxide Nanostructures Generated on a Stainless-Steel Substrate for Efficient Alkaline Water Splitting. ACS Appl. Mater. Interfaces 2019, 11, 44161-44169.
- Jo, K.; Hwang, E. A quantitative evaluation of oxygen reduction and hydrogen evolution reaction contributions to Pb corrosion. J. Electroanal. Chem. 2019, 850, 113393.
- Glasscott, M.W.; Pendergast, A.D.; Goines, S.; Bishop, A.R.; Hoang, A.T.; Renault, C.; Dick, J.E. Electrosynthesis of high-entropy metallic glass nanoparticles for designer, multi-functional electrocatalysis. Nat. Commun. 2019, 10, 1-8.
- Milton, R.D.; Ruth, J.C.; Deutzmann, J.S.; Spormann, A.M. Methanococcus maripaludis Employs Three Functional Heterodisulfide Reductase Complexes for Flavin-Based Electron Bifurcation Using Hydrogen and Formate. Biochemistry 2018, 57, 4848-4857.
Related Products and Accessories
-
WaveDriver 200 Electrochemical Workstation
AFP3 -
WaveNow Wireless Electrochemical Workstation
AFTP4 -
Reference Electrode, Silver/Silver Chloride, Single Junction
RREF0021 -
Counter Electrode Assembly, Platinum (Pt), 14/20
AFCTR5 -
Rotating Disk/Ring-Disk Cell Kit, Standard Volume, Water Jacket
AKCELL3 -
E8 Series Fixed-Disk High Efficiency Rotating Ring-Disk Electrode, Glassy Carbon (GC) Disk, Platinum (Pt) Ring, PTFE separator, PEEK shroud
AFE8R4GCPT -
Bearing Assembly, Gas-Purged, for AFE6MB/AFE9MBA Shaft, PEEK, with 24/25 Taper
AC01TPA6M