Table of Content

• 210-Po and 210-Pb
• 234m-Pa Radionuclide Generator
• A few Definitions used in this exercise
• Accuracy and Precision
• Alpha\Beta-Discrimination
• Analysis of Sediment Containing Pu and Am
• Analyzing a Two-component Decay Curve
• Analyzing the Production Curve of n-activated Ag
• Argon-Argon
• Background for Calculations on Uranium
• Basic Laboratory Procedures for Radiochemistry
• Basic Usage of a HPGe-detector - Laboratory Exercise
• Basics about Efficiency Calibration of Gamma Detectors
• Bruce Hanson
• Calculation Exercises
• Cesium
• CINCH Project and Consortium
• CINCH-exercise
• Computing in Science Education (CSE) Exercises
• Contamination and dose rate monitoring
• Cosmogenic Radionuclides
• CSE Exercise - Simulating a Gamma-ray Detector
• CSE Exercise - Simulation of Radionuclide Genetic-Dependency (Mother-Daughter relationship)
• CSE Exercise - Simulation of Transuranium Waste Generation
• CSE Exercise Simulating Transuranium Waste - Examples of Results Obtained
• CSE Teachers Guide - Simulation of Transuranium Waste Generation
• Detection and Quantification
• Detection of radioactivity laboratory exercises
• Determination of 210-Po from Vegetation
• Determination of 90-Sr from Milk Powder
• Determination of Chemical Yield
• Determination of Fe-55 in Nuclear Waste
• Determination of Low Solubilities
• Determination of Plutonium and Americium from a Sediment Sample
• Determination of the 238-U 234-U Ratio
• Determination of the Specific Surface Area of an Insoluble Substance
• Determination of Uranium Concentration and the 234-U 238-U Isotopic Ratio in a Solution
• DOPAS brochure
• Energy Calibration of Gamma-ray Spectra - Laboratory Preparation Exercise
• Energy calibration procedure
• Environmental laboratory exercises
• EuroMaster Certificate in Nuclear and Radiochemistry (NRC)
• Evaluation of Type A and Type B Uncertainties
• Execution of PHREEQC Calculations
• Exercises with Amount of Radioactive Material (number of nuclei, number of moles, weight) and the Law of Radioactive Decay
• Exercises with Fission and Nuclear Reactors
• Exercises with Mass, Binding Energy and the Liquid Drop Model
• Exercises with Mother Daughter Relations and Equilibrium
• Exercises with Particles and Nuclear Reactions
• Exercises with Radiation Dosage and Radiation Protection
• Exercises with the Chart of Nuclides
• Experimental procedure for determination of low solubilities
• Experimental procedure for determination of the specific surface are of an insoluble substance
• Experimental Procedure for Gamma Spectroscopy
• Experimental procedure for Introduction to Radioimmunoassay
• Experimental procedure for Isotopic dilution
• Experimental procedure for quench corrections in liquid scintillation counting
• experimental procedure for radiolabelling of aspirin
• Experimental procedure for the Measurement of Isotopes using Cerenkov Radiation
• Experimental procedure for the separation of 234mPa from 238U and measurement of its half-life
• Experimental procedure for the separation of radioisotopes by solvent extraction
• Extraction and Measurement of 99mTc from a Isotope Generator
• FAQ
• Feedback from Teachers and Students about the CSE Simulation of a Nuclear Reactor
• Gamma Detection and Spectroscopy - Laboratory Exercise
• Gamma Spectroscopy
• Gamma Spectroscopy and Detectors
• Gamma Spectroscopy of NORM and TENORM
• Gamma-ray energy tables
• Gamma-ray interaction with detector
• Geiger-Müller Counter and Counting Efficiency
• General Description of Computing in Science Education (CSE) exercises
• Heading1
• home
• How to Calculate End-of-Irradiation Yields of Ag-isotopes
• How to Measure the Decay of n-activated Silver
• How to use NucWik
• Interfering Processes
• Introduction to Detection of Gamma Radiation
• Introduction to Isotopic Exchange Reactions
• Introduction to liquid scintillation counting
• Introduction to Naturally Occurring Radioactivity
• Introduction to Radioactivity (short)
• Introduction to Radiochemistry
• Introduction to Radioimmunoassay
• Introduction to Statistics
• Introductory laboratory exercises
• Ion exchange on insoluble crystal surfaces
• Isotopic Dilution
• Isotopic Exchange Reactions
• Isotopic Ratio of Natural Uranium
• KJM 3700 Environmental Chemistry I
• Laboratory Exercises
• Links to external tools
• Liquid Scintillation Counting
• Liquid-liquid Extraction of 99mTc
• List of Individual Courses
• Loughborough University Module CMB008
• LSC Principles
• Master in Radioecology
• Measurement of 55Fe by Liquid-Scintillation Counting
• Measurement of Isotopes using Cerenkov Radiation
• Measurement, uncertainty and Detection Limits
• Milk Powder and Strontium
• Mojmir
• NAA of Chlorine
• Naturally Occuring Radioactivity - NORM and TENORM
• Neutron Activation Analysis
• Neutron Activation of Ag
• Neutron Activation of Ag with a Pu\Be n-source
• Neutron Activation of Silver and two Component Decay
• new page
• NORM and TENORM
• NRC EuroMaster - List of Minimum Knowledge Skills, and Abilities
• Nuclear and Radiochemistry Textbook and Compendia
• Nuclear Chemistry Textbook
• Nuclear Methods in Materials Dating
• Nuclear Waste simulation solved in Labview
• Nuclear waste simulation, general programming tips
• NucWik Talks and Presentations
• NucWik Training Course for Teachers
• Page Å
• Page Ö
• PHREEQC
• PHREEQC files for Uranium Calculations
• Polonium Deposition on Silver Disc
• Polonium-Lead
• Potassium-Argon
• Practical Exercise for Liquid Scintillation
• Preparation of 14-C Labelled Aspirin
• Preparation of an Uraniumoxide Sample
• Principle Behind Mother-Daughter Relationship
• Probability and Distribution
• Procedure for Energy Efficiency calibration
• Procedure to Isotopic Exchange Reactions
• Production and Creation of Fe-55
• Production and Measurement of a 234mPa Nuclide Generator
• Programming tips for Nuclear Fuel Composition Labview
• Quench corrections in liquid scintillation counting
• Questions for Introduction to Radiochemistry
• Radiocarbon
• Radionuclide generator
• RoboLab Exercise - Absorption and Detection of gamma-radiation
• RoboLab Exercise - Autodeposition on different metals
• RoboLab Exercise - HPGe γ-spectroscopy of environmental samples
• RoboLab Exercise - Ion Exchange Column with On-line Detection
• RoboLab Exercise - n-activation of Ag
• RoboLab Exercise - Separation and Detection of 234mPa
• RoboLab Exercises
• RoboLab n-activation of Ag - Preparations
• Robolab procedure for absorption of γ-radiation
• Rubidium-Strontium
• Safe working Practice in the Radionuclide Laboratory and preparation of Counting Samples
• Safety Rules in Radiochemistry
• Samarium-Neodynium
• Scale and Radioactivity
• Separation of 234mPa from 238U and measurement of its half-life
• Separation of 55Fe
• Separation of Strontium from Milk Powder
• Simulation of NRC Related Processes
• Simulation of Two-component Decay
• SLH Page
• space.menu
• space.template.Computers in Education (CiE) exercises
• space.template.Lab exercise template
• Speciation Calculation of Uranium in Oxic Conditions as a Function of pH using PHREEQC
• Speciation of Uranium
• Stable and Unstable Nuclei
• Student Guide - Introduction to Simulation of Transuranium Waste Generation
• Student Guide - Simulation of Genetically Dependent Radionuclids (Mother-Daughter relationship) CSE Exercise
• Student Guide on how to Write a Program for Simulation of Gamma Detection
• Student Guide to a Computer Program which Simulate Gamma-ray Detection
• Suggested assumptions for nuclear fuel simulation
• Suggested Solutions to Amount of Radioactive Material (number of nuclei, number of moles, weight) and the Law of Radioactive Decay
• Suggested Solutions to Exercises with the Chart of the Nuclides
• Suggested Solutions to Fission and Nuclear Reactors
• Suggested Solutions to Mass, Binding Energy and the Liquid Drop Model
• Suggested Solutions to Mother Daughter Relations and Equilibrium
• Suggested Solutions to Particles and Nuclear Reactions
• Suggested Solutions to Radiation Dosage and Radiation Protection
• Test 1
• Test page
• Test work with NucWik
• TESTING
• Textbook Main Chapter - Radiation Safety and Health Hazards
• Textbook Sub-chapter - Interaction between Radiation and Matter
• Textbook Sub-chapter - Liquid Scintillation Detectors
• Textbook Sub-chapter - Naturally Occuring Radioactivty
• Textbook Sub-chapter - Neutron Activation Analysis
• Textbook Sub-chapter - Radiation Dose
• Textbook Sub-chapter - Radioactive Disintegration
• Textbook Sub-chapter - The Oil and Gas Industry
• The Measurement of Isotopes using Cerenkov Radiation
• The separation of radioisotopes by solvent extraction
• Theoretical Background for Isotopic Dilution
• Theoretical background for radioimmunoassay
• Theoretical Background to Isotopic Exchange Reactions
• Theory behind Extraction of 55Fe
• Tracers and solubility
• Uncertainty and Errors
• Uncertainty Classes, Significant Figures and Uncertainty Estimation
• Uranium Series Disequilbrium
• User Feedback from RoboLab Exercise on Gamma-absorption
• user10
• user12
• user13
• user14
• user15
• user16
• user17
• user18
• user19
• user20
• user23
• user24
• user25
• user26
• user27
• user28
• user5
• user6
• user7
• user9
• Wet Digestion of Plant Samples
• Working With Radioactive Material
• Yield in Neutron Activation and Nuclear Reactions

Loughborough Lab exercises / Exercise

• Contamination and dose rate monitoring
• Determination of Low Solubilities
• Determination of the Specific Surface Area of an Insoluble Substance
• Determination of volume using dilution technique with a single tritium tracer
• Experimental procedure for Contamination and dose rate monitoring
• Experimental Procedure for Determination of a volume using dilution technique with a single tritium tracer
• Experimental procedure for determination of low solubilities
• Experimental procedure for determination of the specific surface are of an insoluble substance
• Experimental procedure for Gamma Spectroscopy
• Experimental procedure for Introduction to Radioimmunoassay
• Experimental procedure for Isotopic dilution
• Experimental procedure for quench corrections in liquid scintillation counting
• experimental procedure for radiolabelling of aspirin
• Experimental procedure for the absorption of gamma rays
• Experimental procedure for the Measurement of Isotopes using Cerenkov Radiation
• Experimental procedure for the separation of 234mPa from 238U and measurement of its half-life
• Experimental procedure for the separation of 234Th from 238U
• Experimental procedure for the separation of radioisotopes by solvent extraction
• Gamma Spectroscopy
• Gamma-ray energy tables
• home
• Introduction to Radioimmunoassay
• Ion exchange on insoluble crystal surfaces
• Isotopic Dilution
• Laboratory template
• Preparation of 14-C-labelled aspirin
• Quench corrections in liquid scintillation counting
• Questions - Gamma Spectroscopy
• Questions - Quench corrections in liquid scintillation counting
• Questions - Separation of 234mPa from 238U and measurement of its half-life
• Questions - The Absorption of Gamma Rays
• Questions - The separation of 234U from 238U
• Questions for Contamination and dose rate monitoring
• Questions for for Determination of a volume using dilution technique with a single tritium tracer
• Questions for Introduction to Radioimmunoassay
• Questions for Isotopic dilution
• Separation of 234mPa from 238U and measurement of its half life
• space.template.Lab exercise
• The Absorption of Gamma Rays
• The Measurement of Isotopes using Cerenkov Radiation
• The separation of 234Th from 238U
• The separation of radioisotopes by solvent extraction
• Tracers and solubility