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NanoCuvette™ One
NanoCuvette™ One
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Basics
Application notes
Frequently Asked Questions (FAQ)
Troubleshooting
Teaching material
Solutions
Webinars
White papers
Peer-reviewed articles
NanoCuvette™ S
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Frequently Asked Questions (FAQ)
Validation reports
Application Notes
Webinar
Troubleshooting
SpectroWorks™
Introduction
User Guides
Account and cancellation
Frequently Asked Questions (FAQ) and Essential Information
Troubleshooting
Security, Privacy and the Cloud
Data analysis powered by Python
SpectroLink™
Introduction
User Guides
Troubleshooting
Frequently asked questions (FAQ) and Essential Information
Security and Privacy
SpectroShell™
Spectrophotometry fundamentals
Light
Instrument components
Calculations
Applications
Agilent Descriptions
Ocean Optics Descriptions
PerkinElmer Descriptions
Shimadzu Descriptions
VWR Descriptions
ACTTR Descriptions
Jenway Descriptions
Hitachi Descriptions
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UV-Vis Knowledge Base
NanoCuvette™ One
NanoCuvette™ One
Get started
Basics
Application notes
Frequently Asked Questions (FAQ)
Troubleshooting
Teaching material
Solutions
Webinars
White papers
Peer-reviewed articles
NanoCuvette™ S
Get started
Frequently Asked Questions (FAQ)
Validation reports
Application Notes
Webinar
Troubleshooting
SpectroWorks™
Introduction
User Guides
Account and cancellation
Frequently Asked Questions (FAQ) and Essential Information
Troubleshooting
Security, Privacy and the Cloud
Data analysis powered by Python
SpectroLink™
Introduction
User Guides
Troubleshooting
Frequently asked questions (FAQ) and Essential Information
Security and Privacy
SpectroShell™
Spectrophotometry fundamentals
Light
Instrument components
Calculations
Applications
Agilent Descriptions
Ocean Optics Descriptions
PerkinElmer Descriptions
Shimadzu Descriptions
VWR Descriptions
ACTTR Descriptions
Jenway Descriptions
Hitachi Descriptions
NanoCuvette™ One
NanoCuvette™ One measures surface refractive index and absorbance for accurate and fast liquid analysis for both 3 mL and 0.5 uL volumes.
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Do you have a short product guide for NanoCuvette™ One?
Get started with NanoCuvette™ One
NanoCuvette™ One brand page
How to calculate the refractive index using NanoCuvette™ One
Where to buy NanoCuvette™ One?
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Basics
Are you having problems with NanoCuvette™ One? Report your problem here and get technical support
NanoCuvette™ One - Product Brief
NanoCuvette™ One - Flyer
NanoCuvette™ One - Product Description
NanoCuvette™ One - Cleaning Manual
NanoCuvette™ One - Data sheet
NanoCuvette™ One - Made in Denmark
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Application notes
Application Note AN-1-102: Sugar content via °Brix index and refractometry with NanoCuvette™ One and UV-Vis spectrophotometer
Droplets and micro-volume sample applications for NanoCuvette™ One
Saliva and starch degradation
Protein concentrations and Refractometry
Honey and Water Content
Glycerol concentration and QC
Enzymes and kinetics
Coffee and Sugar
Buffers and QC
Apple juice and QC
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Frequently Asked Questions (FAQ)
How is refractive index different from absorbance, which is conventionally measured with a spectrophotometer?
What do I need in my lab to get started with Nanocuvette™ One?
What is an appropriate reference solution when using Nanocuvette™ One?
What path lengths are used to make measurements, and is the user required to make any calculations relevant to the path length when measuring with Nanocuvette™ One?
Which sample volumes can be used to make measurements with Nanocuvette™ One?
Which UV-Vis spectrophotometers are supported with NanoCuvette™ One?
Will the sample size of the volume affect the concentration when using Nanocuvette™ One?
What can I use the refractive index for?
What types of samples can be measured with Nanocuvette™ One?
What do you measure with Nanocuvette™ One?
Is it possible to do kinetics with Nanocuvette™ One?
Can you measure proteins with Nanocuvette™ One?
How to do 0.5 uL measurements with NanoCuvette™ One
How to do 3 mL measurements with NanoCuvette™ One
What is low volume use with NanoCuvette™ One?
What is full volume use with NanoCuvette™ One?
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Troubleshooting
Troubleshooting NanoCuvette™ One
Teaching material
Different honeys - student
Different honeys - teacher
Dilution series with honey - teacher
Unknown honey samples - student
Unknown honey samples- teacher
Dilution series with honey- student
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Solutions
Sugar/Beverages
Proteins
Enzyme/Kinetics
Clear Liquids
Webinars
Webinar about NanoCuvette™ one
White papers
White paper: Protein quantification using spectrophotometer, NanoCuvette™ One and SpectroWorks™ compared to micro-volume system
Peer-reviewed articles
Vannahme, C., Sørensen, K. T., Gade, C., Dufva, M., & Kristensen, A. (2015). Refractometric monitoring of dissolution and fluid flow. Optics Express, 23(5), 6562-6568
Vannahme, C., Dufva, M. & Kristensen, A. High frame rate multi-resonance imaging refractometry with distributed feedback dye laser sensor. Light Sci Appl 4, e269 (2015). DOI:10.1038/10.1038/lsa.2015.4
Tølbøl Sørensen, K.; Kristensen, A. Label-Free Monitoring of Diffusion in Microfluidics. Micromachines 2017, 8, 329. DOI: 10.3390/mi8110329
P.G. Hermannsson, C. Vannahme, C.L.C. Smith, K.T. Sørensen, A. Kristensen. Refractive index dispersion sensing using an array of photonic crystal resonant reflectors. Applied Physics Letters 107 (6)
P. Hermannsson, K. Sørensen, C. Vannahme, C. Smith, J. Klein, M. Russew, G. Grützner, and A. Kristensen, "All-polymer photonic crystal slab sensor," Opt. Express 23, 16529-16539 (2015).
P. G. Hermannsson, C. Vannahme, C. L. C. Smith, & A. Kristensen. Absolute analytical prediction of photonic crystal guided mode resonance wavelengths. Appl. Phys. Lett. 105, 071103 (2014)
P. G. Hermannsson, C. Vannahme, C. L. C. Smith & A. Kristensen. Accurate wavelength prediction of photonic crystal resonant reflection and applications in refractive index measurement. Sensors IEEE
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