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SDS Reservoir Head Scanning Probes –  Application Note 25
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Getting the most from a 50 μl stock of sample using the μSFM for refolding experiments – μSFM – Rapid kinetics – Application Note 27
AN27. Getting the most from a 50 μl stock of sample using the μSFM for refolding experiments. Stopped Flow
Micro-Volume Stopped-Flow – µSFM brochure
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Membrane transport kinetics as measured by stopped-flow – SFM 2000 Series- µSFM- Rapid Kinetics – Application Note 35
AN35 Membrane transport kinetics as measured by stopped-flow
Rapid mixing stopped-flow small-angle X-ray scattering study of lipoplex formation at beamline ID02@ESRF
CITATION: Borislav Angelov, Angelina Angelova, Markus Drechsler, Sylviane Lesieur
The mystery of potentiostat stability explained (Potentiostat stability) Battery – Application Note 4
AN 4. Potentiostat stability - Electrochemistry & Battery. Electrochemistry
Supercapacitor characterization by galvanostatic polarization method (DC characterizations) Supercapacitor – Application Note 51
AN51. DC characterizations - Supercapacitor. Electrochemistry
Sweep scan with Height Tracking Scanning Probes –  Application Note 26
The characterization of Vanadium Redox Battery Cells using BioLogic BCS-815 battery cyclers & a Pinflow® 20 cm² test cell.
Precautions for good impedance measurements (EIS) Battery & Electrochemistry – Application Note 5
AN5. EIS precautions - Electrochemistry & Battery. Electrochemistry
How to interpret lower frequencies impedance in batteries (EIS low frequency diffusion) Battery – Application Note 61
AN61. EIS low frequencies diffusion - Battery. Electrochemistry
Levich and Koutecký-Levich analysis tools: Electrochemical reaction kinetics measurement Kinetics – Application Note 56
AN56. Levich Koutecky Levich. Electrochemistry
Sensor pulsed techniques: SWV, DPV & NPV Electroanalysis & Electrochemistry Sensor – Application Note 67
AN67. Sensor pulsed techniques: SWV, DPV & NPV 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.
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
Protocols for intercalation electrodes materials-2, Potentiodynamic Cycling/Galvanostatic Acceleration (PCGA) PITT Battery – Application Note 2
AN 2. PITT - Electrochemistry & Battery. Electrochemistry
Centrifugally Spun α-Fe2O3/TiO2/Carbon Composite Fibers as Anode Materials for Lithium-Ion Batteries
CITATION: Luis Zuniga , Gabriel Gonzalez , Roberto Orrostieta Chavez , Jason C. Myers , Timothy P. Lodge and Mataz Alcoutlabi
Protocols for studying intercalation electrodes materials- I: Galvanostatic cycling/potential limitations (GCPL) GITT Battery – Application Note 1
AN 1. GITT - Electrochemistry & Battery Application. Electrochemistry
SECM height relief with OSP: An application in corrosion Scanning Probes –  Application Note 2
AN2. SECM height relief with OSP: An application in corrosion. Scanning Probe Electrochemistry.
CASP: a new method for the determination of corrosion parameters (CASP Rp determination) Corrosion – Application Note 37
AN37. CASP Rp determination. Electrochemistry
Graphical and analysis tools in M370/M470 software Scanning Probes –  Application Note 8
Application Note 8. AN 8. Scanning Probe Electrochemistry.
Measurement of non-photochemical quenching using the JTS-150 pump probe spectrometerPhotosynthesis – Application Note 5
This application note describes how to measure non-photochemical quenching using the JTS-150 pump probe spectrometer
Sensitivity Detection limits using proteinsEkkO – Spectroscopy – Application Note 32
AN32. Sensitivity Detection limits using proteins. Spectroscopy
In-situ electrochemical study of LiFePO4 electrodes by quartz crystal microbalance Battery – Application Note 68
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Determination of the diffusion coefficient of an inserted species in a host electrode with EIS, PITT and GITT techniques Battery – Application Note 70
This application note shows the various relationships and methods needed to extract the diffusion coefficient of an inserted species into a host electrodes using Electrochemical Impedance Spectroscopy (EIS), Potentiostatic Intermittent Titermittent Technique (PITT) and Galvanostatic Intermittent Titration technique (GITT). The main results are that when the system is composed of several charge transfer resistances and double layer capacitances, only EIS can simply lead to the diffusion time constants and hence diffusion coefficients.
ZnO Nanorod Integrated Flexible Carbon Fibers for Sweat Cortisol Detection
CITATION: Sekar Madhu Allen Joseph Anthuuvan Sriramprabha Ramasamy Pandiaraj Manickam*S hekhar Bhansali Ponpandian Nagamony Viswanathan Chinnuswamy*
Linear vs. non-linear systems in impedance measurements (EIS linearity) Battery – Application Note 9
AN 9. EIS linearity – Electrochemistry & Battery. Electrochemistry
CV Sim: Simulation of the simple redox reaction (E) – Part I: The effect of scan rate Kinetics – Application Note 41-1
AN 41-1. CV simulation #1 . Electrochemistry
THD: parameters affecting its value & comparison with other methods of linearity assessment Battery & Corrosion – Application Note 65
AN65. EIS Quality Indicators THD Electrochemistry
Utilization of hydrophobic ligands for water-insoluble Fe(II) water oxidation catalysts – Immobilization and characterization
CITATION: SM Al-Zuraiji, T Benkó, L Illés, M Németh, K Frey
Copper Thiophosphate (Cu3PS4) as an Electrode Material for Lithium Solid-State Batteries with Lithium Thiophosphate (β–Li3PS4) Electrolyte
CITATION: Zhenggang Zhang, Katherine A. Mazzio, Luise M. Riegger, Wolfgang Brehm, Jürgen Janek, Joachim Sann, Philipp Adelhelm
A High-Performance Electrocatalyst Based on Hybrid Nife-Pyromellitic Acid for Oxygen Evolution Reaction
CITATION: Lin Li, Guoqi Li, Wenlong Li, Fusheng Li, Chunze Yuan, Nian Zhang, Hui Zhang, Tsu-Chien Weng
Ohmic Drop Part II: Intro. to Ohmic Drop measurement techniques (Ohmic drop measurement) Battery – Application Note 28
AN28, Ohmic drop measurement techniques, Electrochemistry
Ohmic Drop Part III: Suitable use of the ZIR techniques (Ohmic drop & ZIR techniques) Battery – Application Note 29
AN29< Ohmic drop & ZIR techniques, Electrochemistry
Distribution of Relaxation Times (DRT): an introduction Battery – Application Note 60
AN60. EIS-Distribution of Relaxation Times DRT. Electrochemistry
Intermittent Contact (ic) SECM for relief of major topographic features Scanning Probes –  Application Note 16
Scanning Probe Electrochemistry. AN 16. Application Note 16
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.
Constructing a pathway for mixed ion and electron transfer reactions for O2 incorporation…
CITATION: Di Chen, Zixuan Guan, Dawei Zhang, Lena Trotochaud, Ethan Crumlin, Slavomir Nemsak, Hendrik Bluhm, Harry L. Tuller & William C. Chueh
Corrosion current determination with mass transfer limitation Corrosion – Application Note 47
AN4. Mass transfer limitation. Electrochemistry
EIS Quality Indicators: THD, NSD & NSR Battery & Corrosion – Application Note 64
AN64. EIS Quality Indicators: THD, NSD & NSR. Electrochemistry
Introduction to Foil Cell Scanning Probes –  Application Note 20
AN20. Introduction to Foil Cell. Scanning Probe Electrochemistry
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
How to read EIS accuracy contour plots Electrochemistry & Battery – Application Note 54
AN54. EIS contour plot. Electrochemistry
Electrical characterization of a ceramic with MTZ-35 and HTSH-1100 test fixture Material Science – Application Note 1
AN1. Electrical characterization of a ceramic with MTZ-35 and HTSH-1100 test fixture. Materials Science
Achieving micron scale measurements using the SECM150 Scanning Probes –  Application Note 18
AN18. Achieving micron scale measurements. Scanning Probe Electrochemistry.
How to check and correct non-stationary EIS measurements using EC-Lab® (Part 2) Battery – Application Note 69-2
No description
ZFit and equivalent electrical circuits (EIS Equivalent Circuit) Battery – Application Note 14
AN14. EIS Equivalent Circuit – Electrochemistry & Battery Application. Electrochemistry
Two questions about Kramers-Kronig transformations (EIS Kramers-Kronig) Battery – Application Note 15
EIS Kramers Kronig - Battery & Electrochemistry
Staircase Potentio Electrochemical Impedance Spectroscopy (SPEIS) and automatic successive ZFit analysis Battery – Application Note 18
AN 18. EIS Zfit - Electrochemistry, Battery & corrosion. Electrochemistry
EIS measurements on Li-ion batteries EC-Lab® software parameters adjustment (EIS optimizations) Battery – Application Note 23
AN 23, EIS optimizations, Electrochemistry
Electrochemical Noise Measurements Part III: Determination of the noise resistance Rn Corrosion – Application Note 39-3
AN 39-3. Electrochemical noise measurement ENA ASTM #3. Electrochemistry