WaveDriver 200 EIS Bipotentiostat Basic Bundle

Pricing

#	Description	Price in USD
Bipotentiostat Bundle
[WD200-BASIC]	WaveDriver 200 EIS Bipotentiostat Basic Bundle
Power Cords	this bundle includes a power cord
List of All Items Included in Bundle
AFP3	WaveDriver 200 EIS Bipotentiostat/Galvanostat includes cell cable, power adapter, USB cable, and dummy test cell
Software	click here for AfterMath software information
Compatible Cables (sold separately)
AKCABLE7-03	WaveVortex Rotation Rate Control Cable links the WaveDriver 200 to the WaveVortex 10 Rotator for AfterMath control of rotation rate this cable is usually purchased as part of a rotator bundle
AKCABLE4	MSR Rotation Rate Control Cable links the WaveDriver 200 to the MSR rotator control unit for AfterMath control of rotation rate this cable is usually purchased as part of a rotator bundle
RRAVCB-T	WaveDriver Spectroelectrochemistry Integration Cable connects and synchronizes potentiostat, spectrometer, and light source this cable is usually purchased as part of a spectroelectrochemistry bundle
ACP2E08	WaveDriver Mini-USB Style Cell Cable mini-USB plug contains connections for working, counter, and reference electrodes typically used to connect a WaveDriver potentiostat to a Compact Voltammetry Cell
ACP2E09	WaveDriver Mini-USB Style Cell Cable with Reference Pin Connector mini-USB plug contains connections for working and counter electrodes; separate line fits pin connector on reference electrode typically used to connect a WaveDriver potentiostat to a Honeycomb Spectroelectrochemistry Cell
ACP3E01	WaveDriver Bipotentiostat Cell Cable D-Shell connector to 7 banana plugs with optional alligator clips included with purchase of potentiostat, order separately only as additional/replacement cable. For use with WaveDriver 20, 40 and 200 bipotentiostats

Description

The WaveDriver 200 EIS Bipotentiostat/Galvanostat has been engineered to provide you with the essential hardware and software features you need at an affordable price. The most complete electrochemical workstation offered by Pine Research, the WaveDriver 200 combines the benefits of a true integrated bipotentiostat with Electrochemical Impedance Spectroscopy (EIS).

True Integrated Bipotentiostat. From the software to the cell cable design, everything about the WaveDriver 200 bipotentiostat makes working with dual working electrode configurations as straightforward as possible: no messy inter-channel connections are required, and no additional cell cables or adapters are required. The WaveDriver 200 connects to your laptop or PC via a standard USB cable and is controlled by our powerful AfterMath software. The software user interface is designed with two working electrodes in mind, so entering experimental parameters for dual-electrode techniques is quick-and-easy.

Applications. The WaveDriver 200 finds use in academic and industrial research laboratories around the world and across a wide variety of applications. The instrument offers a large range of accessible current ranges (±100 nA up to ±1 A) and potential ranges (±2.5V up to ±15 V) along with advanced filtering and iR compensation. Back panel connections allow rotation rate control when performing voltammetry using a Rotating Disk Electrode (RDE), Rotating Ring-Disk Electrode (RRDE), or Rotating Cylinder Electrode (RCE). Additional input/output and timing connections permit the WaveDriver to control third-party instrumentation in applications such as spectroelectrochemistry.

Electrochemical Impedance Spectroscopy. Our talented team of engineers and chemists have taken a careful approach to integrating EIS into our WaveDriver series potentiostats, giving you access to the most practical range of EIS frequencies (10 µHz to 1 MHz) at an affordable price. We have incorporated powerful and easy-to-use EIS equivalent circuit fitting directly into our AfterMath software platform. Multiple curve fitting algorithms and options allow you to fit even the most troublesome EIS data to one of the built-in equivalent circuit models, or alternately, you can design and draw your own equivalent circuit model.

Integrated Curve Fitting and Analysis. Our software team has seamlessly integrated EIS curve fitting into AfterMath. Why work with more than one software application to fit your EIS data when you can do it using the very same software application that acquired the data? AfterMath EIS curve fitting utilities provide several analyses, including Circuit Fit, Transmission Line, and Kramers-Kronig. Unlike others, our fitting software also provides several fitting methods including Modified Levenberg-Marquardt (LM), Simplex, and Powell algorithms in addition to fitting options that include dynamic point selection, unity, and parametric fitting.
Novel Transmission Line Fitting. AfterMath provides a unique approach to model your porous electrodes. While the transmission line model is not new, AfterMath provides you with some unique transmission line fitting tools. Instead of a static circuit, where you have no control over the elements of the model, we provide a very flexible basic model, from which you can customize nearly all aspects of the model to suit your system. Give it a try – import your three- or five-column EIS data directly into AfterMath and see the difference with our transmission line fitting.
Finishing Touches. While fitting your EIS data, why flip back and forth between Nyquist and Bode plots? Why not be able to view both plots and fits simultaneously? We heard this feedback from many customers and have designed AfterMath to provide you with both plots simultaneously during fitting. Unique slider controls allow you to rapidly vary the value of one circuit component while watching the effect of that component on the Bode and Nyquist plots.

Cost-Competitive. Take a look around at similar bipotentiostat/galvanostat systems and you will have a difficult time finding another with comparable specifications and capabilities at the price of the WaveDriver 200. While you may find a single-channel EIS-capable potentiostat at a similar price, the WaveDriver 200 gives you a built-in second working electrode without having to purchase a second channel.

Visit our YouTube channel for helpful instructional videos regarding the use and maintenance of this and many other Pine Research products.

Pine Research YouTube

Specification

All specifications are subject to change without notice.


WaveDriver 200 EIS Bipotentiostat / Galvanostat
Working Electrode Channels	2
Measured Current Ranges	±1 A, ±100 mA, ±10 mA, ±1 mA, ±100 μA, ±10 μA, ±1 μA, ±100 nA
Autoranging	Yes
Practical Current Range	20 pA to 1.0 A
ADC Input	16 bits
Compliance Voltage	±17 V
Measured Potential Ranges	±15.0 V, ±10.0 V, ±2.5 V
CV Sweep Rate (min)	10 μV/s (469 μV step per 46.9 s, 313 μV step per 31.3 s, or 78 μV per 7.8 s)
CV Sweep Rate (max)	75 V/s
Point Interval	80 μs (minimum)
EIS Capable	Yes
EIS Frequency Range	10 μHz - 1 MHz
Instrument Dimensions	160 × 324 × 255 mm (6.3 × 12.75 × 10.0 in)
Instrument Weight	4.6 kg (10.2 lb)
Interface	USB
Wireless Capable	No
Additional Specifications	click here for a complete list of specifications

Documentation

Document #	Title
WaveDriver 200 EIS Bipotentiostat/Galvanostat
DRU10162	WaveDriver 200 User Guide click here to download (10 MB download)
DRB10224	WaveDriver 200 Brochure click here to download (1 MB download)
DRK10242	AfterMath EIS Data Import Procedure click here to download (538 KB download)
DRD10200	WaveDriver 200 Accuracy Contour Plot click here to download (205 KB download)

Support

Below are selected product references:


WaveDriver 200 EIS Bipotentiostat / Galvanostat [AFP3]
Wang, Yang; Chen, Ye; Wang, Ziwei; Li, Ping; Zhao, Jianyun; Zhao, Hongyang; Li, Dan; He, Tianxi; Wei, Yuantao; Su, Yaqiong; Xiao, Chunhui Boron doping induced electronic reconfiguration of Fe-Nx sites in N-doped carbon matrix for efficient oxygen reduction reaction in both alkaline and acidic media. Int. J. Hydrogen Energy, 2022, 47(43), 18663-18674. Guo, Qinghua; Li, Heng; Wang, Simin; Gong, Yan; Ren, Liang; Yu, Guangsuo Experimental study on preparation of oxygen reduction catalyst from coal gasification residual carbon. Chemical Engineering Journal, 2022, 446, 137256. Lin, Changxin; Liu, Yongchuan; Zhang, Xiangxin; Miao, Xiaofei; Chen, Yuanqiang; Chen, Sujing; Zhang, Yining Regulating the plating process of zinc with highly efficient additive for long-life zinc anode. J. Power Sources, 2022, 549, 232078. Lee, Soo Jeong; Lee, You Jeong; Seo, Sumi; Jo, Hyeonyeong; Han, Donghoon; Yoon, Seog Joon Effect of the surroundings on the photophysical properties of CsPbBr3 perovskite quantum dots embedded in SiOx matrices. Bull. Korean Chem. Soc., 2022, 43(12), 1312-1319. Li, Xingliang; Mu, Wanjun; Chen, Baihua; He, Yao; Tu, Jun; Yang, Yuchuan; Yang, Yanqiu; Wei, Hongyuan; Peng, Shuming Complexation of uranyl with chelidamic acid: Crystal structures, binding strength, and electrochemical redoxes. Nuclear Analysis, 2022, 1(2), 100014. Lyu, Xiang; Li, Jianlin; Jafta, Charl J.; Bai, Yaocai; Canales, Camila P.; Magnus, Fridrik; Ingason, Árni S.; Serov, Alexey Investigation of oxygen evolution reaction with Ni foam and stainless-steel mesh electrodes in alkaline seawater electrolysis. J. Environ. Chem. Eng., 2022, 10(5), 108486. Lyu, Xiang; Bai, Yaocai; Li, Jianlin; Tao, Runming; Yang, Jun; Serov, Alexey Investigation of oxygen evolution reaction with 316 and 304 stainless-steel mesh electrodes in natural seawater electrolysis. J. Environ. Chem. Eng., 2023, 11(3), 109667. Cetindere, Seda; Ardic Alidagi, Husniye; Anjass, Montaha Two novel Anderson-type polyoxometalate based MnIII complexes constructed from pyrene derivatives: Synthesis, photophysical, and electrochemical properties. Inorg. Chim. Acta, 2023, 545, 121280. Molodtsova, Tatyana; Gorshenkov, Mikhail; Kubrin, Stanislav; Saraev, Andrey; Ulyankina, Anna; Smirnova, Nina One-step access to bifunctional γ-Fe2O3/δ-FeOOH electrocatalyst for oxygen reduction reaction and acetaminophen sensing. J. Taiwan Inst. Chem. Eng., 2022, 140, 104569. 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, 2023, 13(3), 635. Osipova, Daria Nanostructured carbon from biomass as a catalyst for energy conversion devices. Master's Thesis, Aalto University, Espoo, Finland, 2021. Narulkar, Dattaprasad D.; Devulapally, Koteshwar; U, Anil Kumar; Dhuri, Sunder N.; Dhavale, Vishal M.; Vardhaman, Anil Kumar; Giribabu, Lingamallu A novel nonheme manganese(II) complex for (electro) catalytic oxidation of water. Sustainable Energy Fuels, 2020, 4(6), 2656-2660. Lee, ChaeHyun; Kim, Kyoungsoo; Shin, YeJi; Han, Donghoon; Yoon, Seog Joon In Situ Spectroelectrochemical Investigation of Perovskite Quantum Dots for Tracking Their Transformation. Front. Energy Res., 2021, 8. Askari, Sadegh; Mariotti, Davide; McGlynn, Ruairi; Benedikt, Jan Air-Cathode with 3D Multiphase Electrocatalyst Interface Design for High-Efficiency and Durable Rechargeable Zinc–Air Batteries. Energy Technology, 2021, 9(5), 2000999. Miao, Xiaofei; Zhang, Xiangxin; Chen, Sujing; Liu, Yongchuan; Chen, Yuanqiang; Lin, Junhong; Chen, Qi; Zhang, Yining Dual-redox enhanced supercapacitors with sodium anthraquinone-2-sulfonate and potassium bromide. Electrochim. Acta, 2021, 374, 137889. Yi, Xuerui; Yin, Fengxiang; He, Xiaobo; Li, Guoru Partially reduced NiO by cellulose as a highly active catalyst for oxygen evolution reaction: synergy between in situ generated Ni3+ and lattice oxygen. Int. J. Energy Res., n/a(n/a). Meunier, C. J. ; Denison, J. D. ; McCarty, G. S. ; Sombers, L. A. Interpreting Dynamic Interfacial Changes at Carbon Fiber Microelectrodes Using Electrochemical Impedance Spectroscopy. Langmuir, 2020, 36(15), 4214-4223. Zhu, Y. High Temperature CO2RR on Yttrium doped Barium Zirconate Electrolysis Cell. Ph.D. Dissertation, Cornell University, Ithaca, NY, 2019. Yarur, F. ; Manioudakis, J. ; Naccache, R. ; Majewski, M. Carbon Dot Sensitized Photoanodes for Visible Light Driven Organic Transformations. ChemRxiv, 2019. 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), 1-8. Goines, S. ; Dick, J. E. Electrochemical Characterization of Nicotinamide Riboside. ChemElectroChem, 2019, 6(20), 5264-5272. Eom, C. J. ; Suntivich, J. In Situ Stimulated Raman Spectroscopy Reveals the Phosphate Network in the Amorphous Cobalt Oxide Catalyst and Its Role in the Catalyst Formation. The Journal of Physical Chemistry C, 2019. Fehr, J. M. ; McKenas, C. G. ; Liu, B. ; Lockett, M. R. Azide‑alkyne click reactions to prepare chemically modified amorphous carbon electrodes. Appl. Surf. Sci., 2019, 480, 1109-1115. Chen, J. ; Zhao, G. ; Chen, Y. ; Rui, K. ; Mao, H. ; Dou, S. X. ; Sun, W. Iron-Doped Nickel Molybdate with Enhanced Oxygen Evolution Kinetics. Chemistry – A European Journal, 2019, 25(1), 280-284. Liu, H. ; Xu, C. ; Du, Y. ; Ma, F. ; Li, Y. ; Yu, J. ; Zhen, L. Ultrathin Co9S8 nanosheets vertically aligned on N,S/rGO for low voltage electrolytic water in alkaline media. Sci. Rep., 2019, 9(1), 1951.

WaveDriver 200 EIS Bipotentiostat / Galvanostat [AFP3]

WaveDriver 200 Basic Bundle

All specifications are subject to change without notice.

Questions? Find Answers.

Software

Applications

Theory

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WaveDriver 200 Basic Bundle

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All specifications are subject to change without notice.

Questions? Find Answers.

Software

Applications

Theory

Product Specifications