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    WaveDriver 10 DC Potentiostat

    Part Number
    AFP1
    WaveDriver 10 DC Potentiostat
    Product Discontinued - No Replacement Available
    This product has been discontinued and can no longer be purchased. The product remains on our website for reference and a listing of its specifications. There is no direct product replacement to offer.

    WaveDriver 10 Potentiostat/Galvanostat System

    Out of stock

    Categories
    Legacy Products > Legacy Electrode Rotators
    Tags
    WaveDriver 10 DC Potentiostat

    WaveDriver 10 Potentiostat/Galvanostat System

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    Specifications
    References
    Electrochemical Workstations
    Electrode Connections
    Reference electrode
    Sense line with driven shield
    Counter electrode
    Drive line with grounded shield
    Working electrode channels
    1 Channel
    Working electrode #1 (WK1)
    Separate sense and drive lines, each with driven shield (current measurement via passive shunt)
    Ground Connections
    DC common (signal)
    The DC Common is isolated from the USB port, the instrument chassis and earth ground. The DC Common is accessible via a banana binding post (black) on the back panel.
    Chassis terminal
    The metal case (chassis) terminal is a banana binding post (back panel) which may optionally be used to connect the chassis to earth ground or signal ground to improve noise screening (shielding).
    Earth
    No direct connection to earth ground is provided.
    Measured Current (Potentiostatic Mode)
    Current ranges (measured)
    ±1 A, ±100 mA, ±10 mA, ±1 mA, ±100 µA, ±10 µA, ±1 µA, ±100 nA
    Current resolution at each range (measured)
    31.3 µA, 3.13 µA, 313 nA, 31.3 nA, 3.13 nA, 313 pA, 31.3 pA, 3.13 pA
    Autoranging
    Yes
    Practical current range
    100 pA to 1 A
    DC accuracy (current, measured)
    ±0.2% of setting; ±0.05% of range
    DC leakage current
    <10 pA at 25°C
    AC accuracy (measured)
    N/A
    AC leakage current
    N/A
    ADC input
    16 bits
    Filters (for DC Experiments)
    10 Hz, 30 Hz, 100 Hz, 1 kHz, 10 kHz
    Applied Current (Galvanostatic Mode)
    Current ranges (applied)
    ±1 A, ±1 mA, ±100 µA, ±10 µA, ±1 µA, ±100 mA, ±10 mA, ±100 nA
    Current resolution at each range (applied)
    31.3 µA, 3.13 µA, 313 nA, 31.3 nA, 3.13 nA, 313 pA, 31.3 pA, 3.13 pA
    DC accuracy (current, applied)
    ±0.2% of setting; ±0.05% of range
    DAC output (current)
    16 bits
    Power Amplifier (Counter Electrode Amplifier)
    Output current
    ±1 A (maximum)
    Short circuit current limit
    undetermined
    Compliance voltage
    ±16.5 V
    Bandwidth
    >200 kHz (on fastest speed setting)
    Noise and ripple
    undetermined
    Slew rate/rise time
    10 V/µs (on fastest speed setting)
    Electrometer (Reference Electrode Amplifier)
    Input impedance
    >10¹³ in parallel with <10 pF
    Input current
    <10 pA leakage/bias current at 25°C
    CMRR
    >100 dB, 0 - 1 kHz, >74 dB at 10 kHz
    Electrometer bandwidth
    >11 MHz (3 dB)
    Measured Potential
    Potential ranges (measured)
    ±15 V, ±10 V
    Potential resolution at each range (measured)
    469 µV per ADC bit, 313 µV per ADC bit
    DC accuracy (potential, measured)
    ±0.2% of setting; ±0.05% of range
    ADC output
    16 bits
    Filters (for DC Experiments)
    10 Hz, 30 Hz, 100 Hz, 1 kHz, 10 kHz
    Applied Potential (Potentiostatic Mode)
    Potential ranges (applied)
    ±15 V, ±10 V
    Potential resolution at each range (applied)
    469 µV per DAC bit, 313 µV per DAC bit, 78 µV per DAC bit
    DC accuracy (potential, applied)
    ±0.2% of setting; ±0.05% of range
    DAC output (potential)
    16 bits
    CV sweep rate (minimum)
    10 µV/s
    CV sweep rate (maximum)
    125 V/s
    Data Acquisition (for DC Experiments)
    Clock resolution
    10 ns (minimum time base)
    Point interval
    80 µs (minimum)
    Synchronization
    Simultaneous current and potential input
    Raw point total
    <10 million per experiment
    Electrochemical Impedance Spectroscopy (EIS)
    EIS capable
    No
    EIS frequency range
    N/A
    EIS frequency resolution
    N/A
    EIS frequency stability
    N/A
    Modes
    N/A
    Voltage excitation setpoint
    N/A
    Current excitation setpoint
    N/A
    Frequency sweeping
    N/A
    EIS accuracy
    N/A
    Rotator Control Connections
    Rotator connector A
    7-pin mini circular DIN includes analog and digital signal grounds, digital rotator enable signal, auxiliary digital output signal, and analog rotation rate control signal
    Rotator connector B
    3-pin connector includes analog signal ground, digital rotator enable signal (+15 V max), and analog rotation rate control signal
    Rate control signal
    ±10 V, ±2.5 V
    Digital enable signal
    open drain (TTL compatible)
    Accessories
    Dummy cell
    External dummy cell included
    Cell cable
    Combination D-SUB connector to multiple banana plugs via shielded coaxial cables (included)
    Auxiliary Connections
    Connector C
    9-pin DSUB connector includes digital signal ground, two digital output signals, and three digital input signals
    Trigger input
    BNC female, TTL compatible
    Trigger output
    BNC female, TTL compatible
    Potential (E1) output
    N/A
    Current (I1) output
    N/A
    Potential (E2) output
    N/A
    Current (I2) output
    N/A
    Auxiliary analog input
    N/A
    Auxiliary analog output
    BNC female, ±10 V bipolar output, 313 µV resolution, 0.2% accuracy (available when second working electrode not in use)
    WK1 input
    BNC female, ±10V differential input, 20 kΩ impedance, ±0.5% accuracy; allows external waveform to be summed directly to the working electrode excitation signal
    WK2 input
    BNC female, ±10V differential input, 20 kΩ impedance, ±0.5% accuracy; allows external waveform to be summed directly to the working electrode excitation signal
    General
    Power input
    24.0 VDC (±5%), 4.0 A (low voltage DC device)
    Power supply input
    100 - 240 VAC, 1.4 - 0.7 A, 50 - 60 Hz
    Power supply output
    24 VDC, 5.0 A power supply (included) has a C14 type input connector
    Power cord
    Various international cables sold separately (C13 type)
    LED indicators
    Power, USB, and status
    Instrument dimensions
    160 × 324 × 255 mm (6.3 × 12.75 × 10.0 in)
    Workstation shipping dimensions
    254 × 356 × 457 mm (10 × 14 × 18 in)
    Instrument weight
    4.6 kg (10.2 lb)
    Workstation shipping weight
    7.7 kg (17 lb)
    Temperature range
    10°C - 40°C
    Humidity range
    80% RH maximum, non-condensing
    Workstation modes
    Potentiostat (POT), Galvanostat (GAL), Open-Circuit Potential (OCP), Zero-Resistance Ammeter (ZRA)
    Communication
    Interface
    USB
    Wireless capable
    No
    When possible, we add published articles, theses and dissertations, and books to our references library. When we know this product has been used, we will include it in this list below. If you have a reference where our product was used and it's not in this list, please contact us with the details and we will add it.
    1. Lydon et al. Electrochemical characterization of isolated nitrogenase cofactors from Azotobacter vinelandii. ChemBioChem, 2025, , .
    2. Kayode et al. In Situ PANI–Graphite Nanochain-like Structures and Their Application as Supercapacitive Electrodes. Journal of Composites Science, 2024, 8, 200.
    3. Garcia-Lobato et al. Corrosion resistance and in vitro bioactivity of dense and porous titania coatings deposited on 316L SS by spraying method. Applied Surface Science, 2019, 484, 975-980.
    4. Garcia-Lobato et al. Enhanced electrochromic performance of NiO-MWCNTs thin films deposited by electrostatic spray deposition. Materials Research Bulletin, 2019, 114, 95-100.
    5. Lydon et al. Chemical modification of gold electrodes via non-covalent interactions. Inorganic Chemistry Frontiers, 2016, 3, 836-841.
    6. Wang et al. A highly efficient PtCo/C electrocatalyst for the oxygen reduction reaction. RSC Advances, 2016, 6, 34484-34491.
    7. Gunawardhana and Kaumal Development of a portable paper-based microfluidic device for the detection of alcohol in biological fluids. Sri Lankan Journal of Biology, 2016, 1, 38.
    8. Thammavongsy et al. Flexibility is Key: Synthesis of a Tripyridylamine (TPA) Congener with a Phosphorus Apical Donor and Coordination to Cobalt(II). Inorganic Chemistry, 2015, 54, 11505–11510.
    9. Tsay et al. Solvation Effects on Transition Metal Hydricity. Journal of the American Chemical Society, 2015, 137, 14114–14121.
    10. Wang et al. Effect of different solvent ratio (ethylene glycol/water) on the preparation of Pt/C catalyst and its activity toward oxygen reduction reaction. RSC Advances, 2015, 5, 56570-56577.
    11. Tawfic et al. Enhanced Capacity and Stability for the Separation of Cesium in Electrically Switched Ion Exchange. Fusion Science and Technology, 2015, 67, 608–611.
    12. Armutlulu et al. Supercapacitor Electrodes Based on Three-Dimensional Copper Structures with Precisely Controlled Dimensions. ChemElectroChem, 2015, 2, 236–245.
    13. Shaffer et al. Reactivity of a Series of Isostructural Cobalt Pincer Complexes with CO2 , CO, and H+. Inorganic Chemistry, 2014, 53, 13031–13041.
    14. Tsang et al. A MEMS-enabled biodegradable battery for powering transient implantable devices. 2014 IEEE 27th International Conference on Micro Electro Mechanical Systems (MEMS), 2014, , 358–361.