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DC and AC characterization of a Vanadium Redox Flow Battery (VRFB) using a Pinflow 20 cm² test lab cell Battery – Application Note 71
The characterization of Vanadium Redox Battery Cells using BioLogic BCS-815 battery cyclers & a Pinflow® 20 cm² test cell.
RK-Spectro Technical Note 60: X-ray head
This technical note demonstrates how to fit a capillary into the holder, provided with the X-ray head
Double mixing stopped-flow using interrupted flow method – SFM-2000 seriesRapid kinetics – Application Note 21
AN21 Double mixing stopped-flow using interrupted flow method . Stopped Flow/Rapid Kinetics
Precise control of flow rate – SFM-2000 series -Rapid kinetics – Application Note 17
AN17. Precise control of flow rate. Stopped Flow/Rapid Kinetics
Enzyme Kinetics above Denaturation Temperature: A Temperature-Jump/Stopped-Flow Apparatus
CITATION: Bálint Kintses, Zoltán Simon,Máté Gyimesi, Júlia Tóth, Balázs Jelinek, Csaba Niedetzky, Mihály Kovács András Málnási-Csizmadia
An advanced EPR stopped-flow apparatus based on a dielectric ring resonator
CITATION: Günter Lassmann, Peter Paul Schmidt, WolfgangLubitz
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
Pore selectivity analysis of an aquaglyceroporin by stopped-flow spectrophotometry on bacterial cell suspensions
CITATION: Jean-Francois Hubert, Laurence Duchesne, Christian Delamarche, Amaury Vaysse, Herve Gueune and Celine Ragúenes-Nicol
RK-Spectro Technical Note 44: Pulsed flow method for Quench flow experiment
Pulsed flow method for Quench flow experiment
RK-Spectro Technical Note 34: Design of stopped flow sequence, determination of minimum washing volume
Design of stopped flow sequence, determination of minimum washing volume
Effect of channel dimensions of serpentine flow fields on the performance of a vanadium redox flow battery
CITATION: Ravendra Gundlapalli, Sreenivas Jayanti⁎
Measuring Intracellular Ca Changes in Human Sperm using Four Techniques: Conventional Fluorometry, Stopped Flow Fluorometry, Flow Cytometry and Single Cell Imaging
CITATION: Esperanza Mata-Martínez, Omar José, Paulina Torres-Rodríguez, Alejandra Solís-López, Ana A. Sánchez-Tusie, Yoloxochitl, Sánchez-Guevara, Marcela B. Treviño, and Claudia L. Treviño
RK-Spectro Technical Note 18: Create a stopped-flow sequence using MPS32 software
Create a stopped-flow sequence using MPS32 software
Kinetics of thermo-induced micelle-to-vesicle transitions in a catanionic surfactant system investigated by stopped-flow temperature jump
CITATION: Jingyan Zhang and Shiyong Liu
Stopped-flow in cryogenic conditions – SFM-2000 series – Rapid kinetics – Application Note 25
AN25 Stopped Flow, Stopped-flow in cryogenic conditions. Rapid Kinetics
Salt-induced cluster formation of gold nanoparticles followed by stopped-flow SAXS, DLS and extinction spectroscopy
CITATION: Nico Carl, Sylvain Prévost, Joseph P. S. Fitzgerald and Matthias Karg
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
Stopped-flow in the mid-IR using dual comb spectroscopy – AN38
Obtain very fast reaction speeds by combining stopped flow with dual comb spectrometers.
Cyclic electron flow in C3 plantsPhotosynthesis – Application Note 3
AN 3. Cyclic electron flow in C3 plants. Spectroscopy
The mystery of potentiostat stability explained (Potentiostat stability) Battery – Application Note 4
AN 4. Potentiostat stability - Electrochemistry & Battery. Electrochemistry
Cyclic and linear electron flow in plants revealed by JTS-10 spectrometerPhotosynthesis – Application Note 2
AN 2. Cyclic and linear electron flow in plants revealed by JTS-10. Spectroscopy/Photosynthesis
RK-Spectro Technical Note 33: Stopped-flow_Diode array detection using Kinspec
Stopped-flow_Diode array detection using Kinspec
Supercapacitor characterization by galvanostatic polarization method (DC characterizations) Supercapacitor – Application Note 51
AN51. DC characterizations - Supercapacitor. Electrochemistry
Stopped-flow Accessory catalog
All of these accessories are user changeable, enabling you to adapt the SFM-2000/3000/4000 to your labs needs without buying a completely new system.
Stopped-flow in cryogenic conditions using an external cryostat – Rapid Kinetics – Application Note 25b
Stopped-flow in cryogenic conditions using an external cryostat - Application Note 25b
Precautions for good impedance measurements (EIS) Battery & Electrochemistry – Application Note 5
AN5. EIS precautions - Electrochemistry & Battery. Electrochemistry
RK-Spectro Technical Note 52: Designing double mixing quench flow experiments
Designing double mixing quench flow experiments
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 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.
SCAN-Lab Technical Notes 21: Introducing software for the SDS470 Pump
Introducing software control for the SDS470 pump
RK-Spectro Technical Note 54: Determination of your experimental dead time in fluorescence mode
Determination of your experimental dead time in fluorescence mode
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
RK-Spectro Technical Note 53: Determination of your experimental dead time in fluorescence mode
Determination of your experimental dead time in fluorescence mode
RK-Spectro Technical Note 73: Determination of your experimental dead time in fluorescence mode using μFC-08 and SFM-4000/S
Determination of your experimental dead time in fluorescence mode using μFC-08 and SFM-4000/S
RK-Spectro Technical Note 85: SFM-X000 used in anaerobic conditions_ loading of instrument
SFM-X000 used in anaerobic conditions_ loading of instrument
How to interpret lower frequencies impedance in batteries (EIS low frequency diffusion) Battery – Application Note 61
AN61. EIS low frequencies diffusion - Battery. 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
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.
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.
RK-Spectro Technical Note 05: Quenched-flow mode_ Rate constant determination using Biokine
Quenched-flow mode_ Rate constant determination using Biokine
Protocols for studying intercalation electrodes materials- I: Galvanostatic cycling/potential limitations (GCPL) GITT Battery – Application Note 1
AN 1. GITT - Electrochemistry & Battery Application. Electrochemistry
Submicrosecond dead time determination – SFM-2000 series – Rapid kinetics – Application Note 15
AN15. Submicrosecond dead time determination. Stopped Flow/Rapid Kinetics