This site and information found here on Liquid Scintillation (LS) are derived from “Liquid Scintillation – Measuring Procedures, New Developments” handbook. It contains the most important contemporary radioanalytical procedures applying this modern measuring technology. Additionally, it serves as a manual for the determination of radioisotopes by LS. New developments in this context are described with emphasis on research work on natural radionuclides published recently in two other handbooks.  It was also featured on the Proceedings of the “International Conferences on Liquid Scintillation Spectrometry” LSC2001, 2005, 2008, 2010, 2013 and 2017. This handbook is also available as printed book under ISBN 978-3-923704-95-8.

The results found in this site are based on literature compilations and experimental investigations to the best of our knowledge. The authors point out that in the implementation of these methods depend on specific, individual circumstances.

Hidex, the authors, DGFS e.V. and Karlsruhe Institute of Technology KIT exclude any liability for damages. Consequently, the material and information on this site regarding liquid scintillation measuring procedures and other topics may be used at your own discretion.

Links: DGFS e.V. https://www.dgfs-ev.eu

Introduction

• Liquid Scintillation Counting
• Quenching
• Separation of Alpha and Beta Gamma Radiation by Extractive Scintillators and Pulse Shape Discrimination
• Sample Preparation for α/β-Pulse Shape Discrimination
• Triple Coincidence Applications
• Cerenkov Counting
• Sample Preparation by Oxidation

Measuring Procedures

•  
• Liquid Scintillation Counting
• Quenching
• Separation of Alpha and Beta Gamma Radiation by Extractive Scintillators and Pulse Shape Discrimination
• Sample Preparation for α/β-Pulse Shape Discrimination
• Triple Coincidence Applications
• Cerenkov Counting
• Sample Preparation by Oxidation

• Measuring Procedures

• Introduction to Measuring Procedures
• Sample combustion with Hidex 600 OX Oxidizer
  • Biological tissue oxidation
  • Plant sample oxidation
  • Soil and sediment sample oxidation
  • Concrete sample oxidation
• Instrument Calibration Procedures
  • Dual Labeling (Exclusion Method)
  • Quench Correction Curves (Channel Ratio Method)
  • Calibration for Alpha Beta Discrimination (Triathler)
• Natural Radionuclides
  • Aqueous Samples
    • Gross Alpha Beta Survey in Drinking Water
    • Radon by Extraction
    • Radon by Gel Counting
    • Ra-226 through Radon Emanation
    • Radium by Derived Radium RAD Disk Method
    • Simultaneous Determination of Ra-226/228 and Pb-210 Using Radium RAD Disk and TDCR
    • Quick Method for Key Nuclides in Drinking Water
    • Uranium Isotopes by Extractive Scintillation
    • Tritium by Distillation
    • Sea Water Samples
  • Organic Samples
    • Radiocarbon in Biobased Products (Fuel)
• Radionuclides from Nuclear Fission Activities
  • Strontium by Strontium RAD Disk
  • Sr-90 and Pb-210 by Extraction Chromatography
  • Sr-90 and Pb-210 by Plastic Scintillator Using Microspheres
  • Strontium in Milk
  • Sr-89/90 by Cerenkov Counting
  • Strontium Isotopes (Sr-89/Sr-90 and Sr-90/Y-90) by TDCR Cerenkov Counting
  • Fe-55 by Extraction Chromatography
  • Ni-63 by Extraction Chromatography
  • Fe-55 and Ni-63 in Radioactive Waste
  • Ca Isotopes in Biological Shield
  • Fe-55 and Ca-41 in Decommissioning Activities by TDCR-LSC
  • Sample Preparation for Pu-241 Analysis (BioRad)
  • Pu-241 in Presence of Other Plutonium Isotopes (LS Alpha Spectrometry)
  • Tc by RAD Disk and PSresins
  • Multiple Radionuclide Analysis
• Radiation Protection
  • Radon in Air
    • Enrichment in Organic Cocktail
    • Adsorption on Active Carbon ‘PicoRad’
  • NORM Samples
    • NORM in Phosphogypsum
    • Rn in Crude Oil and Oil Fractions
    • Radium Isotopes and Pb-210 in Scale, Deposits and Production Water
  • Off-gas
    • Tritium
    • Radiocarbon
  • Contamination Control by Swipe Assays

• Quality Assurance and Uncertainty Budget

• Introduction to Quality Assurance and Uncertainty Budget
• Uncertainty Budget in LS Spectrometry
• Lower Limit of Detection
• Method Evaluation and Validation
• •