AN 1. Height tracking with the SKP370 or SKP470 module. Scanning Probe Electrochemistry.
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Height tracking with the SKP370 or SKP470 moduleScanning Probes – Application Note 1
Advantages of the intermittent contact SECM : two examples in corrosion – Scanning Probes – Application Note 6
AN 6. Advantages of the intermittent contact SECM : two examples in corrosion. Scanning Probe Electrochemistry.
Investigation of the diffusion of ferricyanide through porous membranes using the SECM150 Scanning Probes – Application Note 19
AN19. Investigation of the diffusion of ferricyanide through porous membranes using the SECM150. Scanning Probe Electrochemistry
SECM height relief with OSP: an application in sensors Scanning Probes – Application Note 3
AN3. SECM height relief with OSP: an application in sensors. Scanning Probe Electrochemistry.
Sweep scan with Height TrackingScanning Probes – Application Note 26
The characterization of Vanadium Redox Battery Cells using BioLogic BCS-815 battery cyclers & a Pinflow® 20 cm² test cell.
SECM height relief with OSP: An application in corrosion Scanning Probes – Application Note
AN2. SECM height relief with OSP: An application in corrosion. Scanning Probe Electrochemistry.
Measurement of a nano-patterned gold sample by ic-/ac-SECM Scanning Probes – Application Note 11
AN11. Measurement of a nano-patterned gold sample by ic-/ac-SECM. Scanning Probe Electrochemistry.
The use of the SVP470 for Vibrating Probe measurements of plants – Scanning Probes. Application Note 22.
AN22. SVP470 for Vibrating Probe measurements of plants. Scanning Probe Electrochemistry.
Introducing the Microscopic Image Rapid Analysis (MIRA) software Scanning Probes – Application Note 5
AN5. Introducing the Microscopic Image Rapid Analysis (MIRA) software. Scanning Probe Electrochemistry.
EC-Lab Technical Notes 26: How to configure an experiment with a platinum temperature probe?
EC-Lab Technical Notes 26. TN26. Electrochemistry, Platinum temperature probe configuration
SCAN-Lab Technical Notes 11: Determining the probe diameter and RG ratio in an SECM experiment
Determining the probe diameter and RG ratio in an SECM experiment
ac-SECM to investigate battery electrode materials in non-aqueous electrolyte Scanning Probes – Application Note 7
AN 7. ac-SECM to investigate battery electrode materials in non-aqueous electrolyte. Scanning Probe Electrochemistry.
SCAN-Lab Technical Notes 09: 150 μm SKP probe: description, advantage and user’s guidelines
150 μm SKP probe: description, advantage and user’s guidelines
SCAN-Lab Technical Notes 03: Relating Work Function Difference Measured by Scanning Kelvin Probe (SKP) to Corrosion Potential.
Practical methods to correlate the SVP voltage to a current at a sample’s surface
dc- and ac-SECM Measurements on Si Nanowire Arrays Scanning Probes – Application Note 10
Application Note 10. AN 10. Scanning Probe Electrochemistry.
Application of scanning probe electrochemistry for biological studies – Tutorial – Lifesciences
Tutorial presentation related to scanning probe electrochemistry (biology)
Measurement of non-photochemical quenching using the JTS-150 pump probe spectrometer – Application Note 5.
This application note describes how to measure non-photochemical quenching using the JTS-150 pump probe spectrometer
Graphical and analysis tools in M370/M470 softwareScanning Probes – Application Note 8
Application Note 8. AN 8. Scanning Probe Electrochemistry.
SKP imaging example of a corroded Zn-plated Fe sample Scanning Probes – Application Note 9
Application Note 9. AN 9. Scanning Probe Electrochemistry.
Intermittent Contact (ic) SECM for relief of major topographic features – Scanning Probes – Application Note 16
Scanning Probe Electrochemistry. AN 16. Application Note 16
SCAN-Lab Technical Notes 15: 5 μm SECM Probes: Description, Advantage, and User Guidelines
5 μm SECM Probes: Description, Advantage, and User Guidelines
Post-treatment and optimization of area scan experimentsScanning Probes – Application Note 4
AN4. Post-treatment and optimization of area scan experiments. Scanning Probe Electrochemistry.
The use of height tracking SECM to measure mechanically exfoliated graphite – Scanning Probes. Application Note 17.
AN17. Height tracking SECM to measure mechanically exfoliated graphite. Scanning Probe Electrochemistry
Introduction to Foil Cell – Scanning Probes. Application Note 20
AN20. Introduction to Foil Cell. Scanning Probe Electrochemistry
SCAN-Lab Technical Notes 22: Approach Curve Topography Extrapolation Experiment
Introducing software control for the SDS470 pump
SCAN-Lab Technical Notes 05: Using custom probes for LEIS, SVP and SKP experiments
Using custom probes for LEIS, SVP and SKP experiments
3D Map production using the 3DIsoPlot software – Scanning Probes – Application Note 12
AN12. 3D Map production using the 3DIsoPlot software.Scanning probe electrochemistry.
Investigation of an interdigitated array electrode using ic-SECM – Scanning Probes – Application Note 13
AN13. Investigation of an interdigitated array electrode using ic-SECM.. Scanning probe electrochemistry
Introduction to the Modular Map Experiment: an Interdigitated Array electrode example – Scanning Probes – Application Note 14
AN 14. Introduction to the Modular Map Experiment: an Interdigitated Array electrode example. Scanning Probe Electrochemistry.
Introduction to the USB-PIO: measuring the effect of light on a live leaf – Scanning Probes. Application Note 15
AN 15. Application Note 15. Scanning Probe Electrochemistry
Achieving micron scale measurements using the SECM150 – Scanning Probes. Application Note 18
AN18. Achieving micron scale measurements. Scanning Probe Electrochemistry.
Using the SECM150 to Measure an NMC Battery Electrode – Scanning Probes. Application Note 21
AN21. Measure an NMC Battery Electrode. Scanning probe electrochemistry
Ic-SECM – Bipolar Plates – Scanning Probes – Application Note 23
Ic-SECM - Bipolar Plates - Scanning Probes - Application Note 23
SCAN-Lab Technical Notes 08: Scanning Vibrating Electrode Technique (SVET): factors affecting the measurement
Scanning Vibrating Electrode Technique (SVET): factors affecting the measurement
Measurement of electrochromic bandshift at 520 nm with real-time scatter correction at 546 nmLife Sciences – Application Note 4
AN#4 JTS, Photosynthesis Measurement of electrochromic bandshift at 520 nm with real-time scatter correction at 546 nm
SCAN-Lab Technical Notes 02: Practical methods to correlate the SVP voltage to a current at a sample’s surface
Practical methods to correlate the SVP voltage to a current at a sample’s surface
SCAN-Lab Technical Notes 07: M470 positioner : how high resolution and high accuracy are achieved
M470 positioner : how high resolution and high accuracy are achieved
SCAN-Lab Technical Notes 10: The application of Gwyddion imaging software to M370/M470 results
he application of Gwyddion imaging software to M370/M470 results
SCAN-Lab Technical Notes 14: Height Tracking Inputs for SKP Investigations
Height Tracking Inputs for SKP Investigations
EC-Lab Technical Notes 41: Climate Chamber control with EXTAPP
EC-Lab Technical Notes 41 Climate Chamber control with EXTAPP
SCAN-Lab Technical Notes 01: Magnitudes and principles used in Scanning Vibrating Electrode Technique
Magnitudes and principles used in Scanning Vibrating Electrode Technique
SCAN-Lab Technical Notes 04: The importance of the Counter Electrode in LEIS measurement
The importance of the Counter Electrode in LEIS measurement
SCAN-Lab Technical Notes 06: Ultra Micro-Electrodes (UMEs) for SECM techniques
Ultra Micro-Electrodes (UMEs) for SECM techniques
SCAN-Lab Technical Notes 12: ac-SECM and LEIS: differences and similarities
ac-SECM and LEIS: differences and similarities
SCAN-Lab Technical Notes 13: Connecting to the SP-300 by Ethernet connection (instead of USB)
Connecting to the SP-300 by Ethernet connection (instead of USB)