Getting started with the course – a package including a potentiostat and laboratory experiments
Getting started with the course – a package including a potentiostat and laboratory experiments
The electrochemistry starter pack comprises five laboratory experiments, complete with digital operating instructions and accessories, as well as the Gamry System Interface 1010T potentiostat/galvanostat/ZRA – this combination guarantees a successful introduction to electrochemistry at an attractive price.The Interface 1010T Potentiostat/Galvanostat/ZRA kit and starter pack allow Gamry Instruments’ 11 electrochemistry laboratory experiments to be streamlined into 5 experiments in a cost-effective manner, making the methods and theories of electrochemistry available to an even wider audience in an efficient and comprehensive way. With the complete package, you receive the support you need to familiarise yourself, your students or staff with the various methods of electrochemistry.
Product Description
Despite the many concrete examples of its application in our everyday lives, electrochemistry is usually neglected as a sub-discipline of many degree programmes in the first semesters. At this point, Gamry provides a product that enables both those responsible in the laboratory and students with a sufficient number of accessories and theoretical and experimental guidelines to carry out a large number of electrochemical experiments without, for example, having to maintain a complex mercury drop electrode.
The available kits enable various experiments to be carried out easily with the accessories supplied, ranging from the qualitative characterisation of unknown electroactive species to the electrochemical polymerisation of monomers and the quantitative analysis of active ingredients in fever syrup for infants.
With the possession of a Gamry system already used in research or with the new acquisition of an entry-level model “T”(eaching) tailored for the course, every scientist and every engineer can easily familiarise themselves with and learn current techniques in modern electrochemistry with the “Practical Experiments in Electrochemistry” in the course of a semester of undergraduate studies. As a prerequisite, the student should have attended lectures and practical courses in general chemistry for at least 2 semesters. The laboratory experiments have been developed to build on each other according to the sequence in the textbook included, but can also be carried out individually for the purpose of a single course. Data recording, analysis and questions are separated from the theory section and the performance of experiments and can be separated from the book for the laboratory assistant.
The Gamry system, basic kit and accessories for each experiment are available individually or can be purchased as a comprehensive kit or cost-effective reduced kit for intuitive electrochemistry laboratory set-up.
Downloads
Videos
The Gamry Interface 1010 Potentiostat Starter PackSpecifications
Gamry System:• 992-00171 Interface 1010T Potentiostat/Galvanostat/ZRA with Starter Pack
Contents:
• 992-00126 Interface 1010T Potentiostat/Galvanostat/ZRA
• 990-00420 Screen-printed electrode stand
• 935-00120 Carbon WE SPE (6pcs)
• 990-00197 PTC1 Paint Test Cell (w/o RE)
• 820-00141 Mild steel sample (2 pcs)
• 240-00015 1 µF capacitor
• 240-00017 2.2 µF capacitor
• 100-00040 20 ohm resistor
• 100-00011 100 ohm resistor
Further optional laboratory experiment kits:
1. 990-00456 Cyclic
Voltammetry Experiment
• Carbon Screen Printed Electrode, 20
• Cyclic Voltammetry Student Manual, 20
2. 990-00457 Determination of Working Area of an Electrode Experiment
• Carbon Screen Printed Electrode, 20
• Determination of Working Area of an Electrode Student Manual, 20
3. 990-00458 Comparison of Pulse Techniques Experiment
• Carbon Screen Printed Electrodes, 20
• Comparison of Pulse Techniques Student Manual, 20
4. 990-00459 Quantitative Determination of Ions by Stripping
Voltammetry Experiment
• Carbon Screen-Printed Electrodes, 20
• Quantitative Determination of Ions by Stripping Voltammetry Student Manual, 20
5. 990-00460 Determination of Acetaminophen Experiment
• Platinum Screen-Printed Electrodes, 20
• Determination of Acetaminophen Student Manual, 20
6. 990-00461 Simulations of Cyclic Voltammetry Data Experiment
• DigiElch Student Edition Six-Month Licence
• Simulations of Cyclic Voltammetry Data Student Manual, 20
7. 990-00462
Microelectrodes Experiment
• Ag/AgCl Reference Electrode
• 10 µm Platinum Microelectrode
• Dr. Bob Cell Kit
• Polishing Kit
• Microelectrodes Student Manual, 20
8. 990-00463 Detection of Glucose in a Carbonated Beverage Experiment
• Ag/AgCl Reference Electrode
• Platinum Working Electrode
• Dr. Bob Cell Kit
• Polishing Kit
• Detection of Glucose in a Carbonated Beverage Student Manual, 20
9. 990-00464 Electrochemical Polymerisation of a Monomer Experiment
• Platinum Screen-Printed Electrodes, 20
• Electrochemical Polymerisation of a Monomer Student Manual, 20
10. 990-00465 Electrochemical Impedance Spectroscopy Experiment
• AC Dummy Cell
• Electrochemical Impedance Spectroscopy Student Manual, 20
11. 990-00466 Corrosion of Mild Steel at Different pHs Experiment
• Samples of Mild Steel, 30
• Ag/AgCl Reference Electrode
• Eurocell Electrochemical Cell Kit
• Corrosion of Mild Steel at Different pHs Student Manual, 20
Options and Accessories
Measurement cells and accessories:
• Interface 1010 Bipotentiostat
• Interface 1010 / Interface 5000 bipotentiostat
• ECM8
• RDE710
• eQCM15M
• EuroCell
• Flexcell
• Lithium Battery Materials Cell
• Low Inductance Battery Holder (Dual-CR2032 / Dual-18650)
Applications
Applications:
– Basics of Electrochemical Impedance Spectroscopy [Link AN 5657]
– Equivalent Circuit Modelling in EIS [Link AN 5658]
– Comparison of Corrosion Rates Calculated by EFM, LPR and EIS [Link AN 5660]
– Tsujikawa-Hisamatsu-Electrochemical (THE) Method for Crevice Corrosion Repassivation Potentials [Link AN 5671]
– Basics of Electrochemical Corrosion Measurements [Link AN 5677]
– EIS Measurement of a Very Low Impedance Lithium Ion Battery [Link AN 5682]
– Steps for Creating an Application Using GamryCOM [Link AN 5687]
– Electrochemical Impedance at a Rotating Disk Electrode [Link AN 5695]
– Measuring the Impedance of Your Reference Electrode [Link AN 5697]
– Testing Super-Capacitors: Part 1 – CV, EIS and Leakage Current [Link AN 5710]
– Demystifying Transmission Lines: What are they? Why are they useful? [Link AN 5711]
– Basics of a Quartz Crystal Microbalance [Link AN 5717]
– OptiEIS™ – A Multisine Implementation [Link AN 5718]
– Testing Supercapacitors: Part 2 – CCD and Stacks [Link AN 5724]
– Calibration of an Au-coated Quartz Crystal [Link AN 5727]
– EQCM Investigations of a Thin Polymer Film [Link AN 5728]
– Measuring Surface-Related Currents using Digital Staircase Voltammetry [Link AN 5731]
– Testing Supercapacitors: Part 3 – Electrochemical Impedance Spectroscopy [Link AN 5732]
– Monitoring Layer-by-Layer Assembly of Polyelectrolyte Film using a Quartz Crystal Microbalance [Link AN 5736]
– Characterisation of a Supercapacitor using an Electrochemical Quartz Crystal Microbalance [Link AN 5737]
– Spectroelectrochemistry – Part 1: Getting started [Link AN 5739]
– Spectroelectrochemistry – Part 2: Experiments and Data evaluation [Link AN 5740]
– Raman Spectroelectrochemistry [Link AN 5741]
– How Cabling and Signal Amplitudes Affect EIS Results [Link AN 5747]
– Testing Lithium-Ion Batteries [Link AN 5748]
– Dye Solar Cells – Part 1: Basic principles and measurements [Link AN 5749]
– The Art of Electrochemistry in an Autoclave [Link AN 5751]
– Dye Solar Cells – Part 2: Impedance measurement [Link AN 5752]
– Measuring Batteries using the Right Setup: Dual-cell CR2032 and 18650 Battery Holder [Link AN 5753]
– Getting Started With Your First Experiment: DC105 Corrosion Techniques – Polarisation Resistance [Link AN 5754]
– Getting Started With Your First Experiment: EIS300 Electrochemical Impedance Techniques – Potentiostatic Electrochemical Impedance Spectroscopy [Link AN 5755]
– Dye Solar Cells – Part 3: IMPS and IMVS measurements [Link AN 5756]
– The Implementation of Transmission Lines Using Generalised Circuit Blocks [Link AN 5757]
– Use of Transmission Lines for Electrochemical Impedance Spectroscopy [Link AN 5758]
– A Snapshot of Electrochemical Impedance Spectroscopy [Link AN 5759]
– Determination of the correct value of Cdl from the impedance results fitted by commercially available software [Link AN 5760]
– EIS of Organic Coatings and Paints [Link AN 5763]
