Adel Shaher, profile picture
Uploaded byAdel Shaher
PPTX, PDF31,995 views

Radiation Dosimeters

The document discusses the general requirements and characteristics of dosimeters. A dosimeter is a device that measures radiation quantities like exposure, absorbed dose, and equivalent dose. It should be accurate, precise, and have a linear response over a wide dose range with little dependence on factors like energy, dose rate, or direction. Common types of personal dosimeters mentioned are film badges, pocket ion chambers, thermoluminescent dosimeters (TLD), optically stimulated luminescence (OSL) dosimeters, and solid state dosimeters. The document also discusses appropriate uses of personal dosimeters and factors to consider for different work environments.

Embed presentation

Downloaded 940 times
General requirements for dosimeters #Dosimeter is a device that measures directly or indirectly • Exposure • Kerma • Absorbed dose • Equivalent dose • Or other related quantities. #The dosimeter along with its reader is referred to as a dosimetry system.
A useful dosimeter exhibits the following properties: • High accuracy and precision • Linearity of signal with dose over a wide range • Small dose and dose rate dependence • Flat Energy response • Small directional dependence • High spatial resolution • Large dynamic range
 Accuracy specifies the proximity of the mean value of a measurement to the true value.  Precision specifies the degree of reproducibility of a measurement. Note: High precision is equivalent to small standard deviation.
Examples for use of precision and accuracy: High precision High precision Low precision Low precision and and and and High accuracy Low accuracy High accuracy Low accuracy
Note: The accuracy and precision associated with a measurement is often expressed in terms of its uncertainty.
New Concept by the International Organization for Standardization (ISO) "Guide to the expression of uncertainty in measurement“  This new guide serves as a clear procedure for characterizing the quality of a measurement.  It is easily understood and generally accepted.  It defines uncertainty as a quantifiable attribute.
 Standard uncertainty: is the uncertainty of a result expressed as standard deviation.  Type A standard uncertainty is evaluated by statistical analysis of a series of observations.  Type B standard uncertainty is evaluated by means other than statistical analysis. This classification is for convenience of discussion only.  It is not meant to indicate that there is a difference in the nature of  the uncertainty such as random or systematic.
 Combined uncertainties: The determination of the final result is normally based on several components. Linearity:  The dosimeter reading should be linearly proportional to the dosimetric quantity.  Beyond a certain range, usually a non-linearity sets in.  This effect depends on the type of dosimeter.
Two possible cases Case A: • linearity • supralinearity • saturation Case B: • linearity • saturation
Dose rate dependence :  M/D may be called the response of a dosimeter system  When an integrated response is measured, the dosimetric quantity should be independent of the dose rate dD/dt of the quantity.  Other formulation: The response M/D should be constant for different dose rates (dD/dt)1 and (dD/dt) 2. M = 􀀁 (M / D)(dD / dt)dt M = (M / D)􀀁 (dD / dt)dt
 Energy: The response of a dosimetric system is generally a function of the radiation energy.  The term "radiation quality" is often used to express a specific distribution of the energy of radiation.  Therefore, a dependence on energy can also be called a dependence on radiation quality.  Since calibration is done at a specified beam quality, a reading should generally be corrected if the user's beam quality is not identical to the calibration beam quality.
A small radiation monitoring device worn by persons entering environments that may contain radiation . # Desirable characteristics  Should be lightweight, durable, and reliable  Should be inexpensive
 Healthcare or laboratory workers in non- emergency environments that may contain radiation  Examples: radiology, nuclear medicine, and radiation oncology department staff  Workers in emergency environments that may contain radiation  Examples: first responders and first receivers  Workers in industrial environments where radiation is used  Examples: nuclear power plant workers or employees at radiation sterilizing facilities
 Flat badges are usually worn on the torso, at the collar or chest level, but can be worn on the belt, or forearm  Ring shaped badges can be worn on the finger when dose to the finger may exceed dose to the badge worn elsewhere on the body  First responders and first receivers  Wear water-resistant personal dosimeters on the outer layer of personal protective equipment (PPE).  Should be able to easily see and hear a dosimeter alarm while wearing PPE  May wear a personal dosimeter underneath waterproof outerwear
 Film badge  Pocket ionization chambers  Thermo luminescent dosimeters (TLD)  Optically stimulated luminescence (OSL)  Solid State
 Most widely used and most economical  Consists of three parts:  Plastic film holder  Metal filters  Film packet  Can read x, gamma, and beta radiation  Accurate from 10mrem - 500rem  Developed and read by densitometer  A certain density value equals a certain level of radiation  Read with a control badge  Results generally sent as a printout
 Lightweight, durable, portable  Cost efficient  Permanent legal record  Can differentiate between scatter and primary beam  Can discriminate between x, gamma, and beta radiation  Can indicate direction from where radiation came from  Control badge can indicate if exposed in transit  Only records exposure where it’s worn  Not effective if not worn  Can be affected by heat and humidity  Sensitivity is decreased above and below 50 keV  Exposure cannot be determined on day of exposure  Accuracy limited to + or - 20%
 The most sensitive personnel dosimeter  Two types  Self-reading  Non self-reading  Can only be read once  Detects gamma or x-radiation
 Small, compact, easy to use  Reasonably accurate and sensitive  Provides immediate reading  Expensive  Readings can be lost  Must be read each day  No permanent record  Susceptible to false readout if dropped or jarred
 Looks like a film badge  Contains a lithium fluoride crystal  Responds to radiation similarly to skin  Measured by a TLD analyzer  Crystal will luminescence if exposed to radiation, then heated  More accurate than a film badge
 Crystals contained in TLD interact with ionizing radiation as tissue does  Determines dose more accurately  The initial cost is greater than that of a film badge  Can only be read once  Records exposure only where worn
• “Captures” information in an Aluminum Oxide matrix • Releases information by laser stimulation • Can be reread after processing • Durable • Landauer Only
 Provides instantaneous information regarding dose accumulation  Simple to use  Not a “legal” record  Dose range device dependent
Radiation Dosimeters
Radiation Dosimeters

More Related Content

PPTX
RADIATION MONITORING DEVICES.pptx
byDrSushmitaKoduru
 
PDF
Dosimetry
byNishthaSomkuwar1
 
PPTX
Dosimeter advancements
byDeepaknegi09
 
PPTX
Radiation units
bymansibarthwal1989
 
PPTX
Thermoluminsence dosimeter
byKhursheed Ganie
 
PPTX
TLD
byNAYANA KRISHNAN
 
PPTX
Dosimetry
byNandhu Angela
 
PPTX
Thermoluminesence dosimetry
byKiran Ramakrishna
 
RADIATION MONITORING DEVICES.pptx
byDrSushmitaKoduru
 
Dosimetry
byNishthaSomkuwar1
 
Dosimeter advancements
byDeepaknegi09
 
Radiation units
bymansibarthwal1989
 
Thermoluminsence dosimeter
byKhursheed Ganie
 
TLD
byNAYANA KRISHNAN
 
Dosimetry
byNandhu Angela
 
Thermoluminesence dosimetry
byKiran Ramakrishna
 

What's hot

PPTX
Thermoluminescent dosimeter
byDr Vijay Raturi
 
PPTX
radIATION UNITS
bySAlonii Chawla
 
PDF
Radiation Protection
bySantam Chakraborty
 
PPTX
Basic dosimetric principle and dosimeters
byVinay Desai
 
PPTX
Radiation units
byDr Vijay Raturi
 
PPTX
Half value layer.pptx
byGokulAnanth9
 
PPTX
RADIATION PROTECTION
bySubrata Roy
 
PPTX
X ray filters
bySaruGosain
 
PPTX
Radiation Protection and Dosimetry
byVibhuti Kaul
 
PPTX
Automatic processing of X-ray film.pptx
byRony Ibne Masud
 
PPTX
Radiation protection
byALL INDIA INSTITUTE OF MEDICAL SCIENCES,Bhubaneswar
 
PPT
Radiographic exposure and image quality
byRad Tech
 
PPTX
Ct tube and detectors
bysandip suman
 
PPTX
Dosimetry concepts and dosimeters
bysailakshmi pullookkara
 
PDF
Filters
byaslam bs
 
PPTX
Radiographic factor
byDr,saket Jain
 
PPTX
Radiation units
byAmina Abdurahman
 
PPTX
MACRORADIOGRAPHY.pptx
byThejaTej6
 
PPTX
X-RAY TUBE (ANODE)
byNik Noor Ashikin Nik Ab Razak
 
PPTX
X ray film
byJay Patel
 
Thermoluminescent dosimeter
byDr Vijay Raturi
 
radIATION UNITS
bySAlonii Chawla
 
Radiation Protection
bySantam Chakraborty
 
Basic dosimetric principle and dosimeters
byVinay Desai
 
Radiation units
byDr Vijay Raturi
 
Half value layer.pptx
byGokulAnanth9
 
RADIATION PROTECTION
bySubrata Roy
 
X ray filters
bySaruGosain
 
Radiation Protection and Dosimetry
byVibhuti Kaul
 
Automatic processing of X-ray film.pptx
byRony Ibne Masud
 
Radiation protection
byALL INDIA INSTITUTE OF MEDICAL SCIENCES,Bhubaneswar
 
Radiographic exposure and image quality
byRad Tech
 
Ct tube and detectors
bysandip suman
 
Dosimetry concepts and dosimeters
bysailakshmi pullookkara
 
Filters
byaslam bs
 
Radiographic factor
byDr,saket Jain
 
Radiation units
byAmina Abdurahman
 
MACRORADIOGRAPHY.pptx
byThejaTej6
 
X-RAY TUBE (ANODE)
byNik Noor Ashikin Nik Ab Razak
 
X ray film
byJay Patel
 

Viewers also liked

PPTX
Radiation protection
byjyotimannath
 
PDF
Dosimetry
bystudious girl
 
PPTX
RADIATION DOSIMETRY
bysanchu yadav
 
PPT
Radio isotopes
byDr.M.Prasad Naidu
 
PPTX
Slideshare ppt
byMandy Suzanne
 
PPTX
World bank ppt
bySudarshana Jaiman
 
PDF
Haematinics
byUrmila Aswar
 
PPTX
Emetics and antiemetics
byhttp://neigrihms.gov.in/
 
PPT
Haematinics
byhttp://neigrihms.gov.in/
 
PPT
World Bank Ppt
bymilanmadhukar
 
Radiation protection
byjyotimannath
 
Dosimetry
bystudious girl
 
RADIATION DOSIMETRY
bysanchu yadav
 
Radio isotopes
byDr.M.Prasad Naidu
 
Slideshare ppt
byMandy Suzanne
 
World bank ppt
bySudarshana Jaiman
 
Haematinics
byUrmila Aswar
 
Emetics and antiemetics
byhttp://neigrihms.gov.in/
 
Haematinics
byhttp://neigrihms.gov.in/
 
World Bank Ppt
bymilanmadhukar
 

Similar to Radiation Dosimeters

PPTX
Measurement of Radiation and Dosimetric Procedure.pptx
byDr. Dheeraj Kumar
 
PPTX
DOSIMETERS.pptx
byvishalmehrotra10
 
PPT
Radiation detection & measurement
bymahbubul hassan
 
PPTX
Radiation monitoring devices used in medical science.pptx
byRamJoshi36
 
PPTX
Dosimetry
byMd. Motiur Rahman
 
PPTX
RADIATION UNITS AND PERSONNEL MONITORING.pptx
byjustinfan550
 
PDF
Chapter3 radiation dosimeters
byJeju National University
 
PPTX
Measurement of absorbed dose in Radiotherapy
bySACHINS700327
 
PPTX
radiation safety.pptx
bySaikatChakraborty80
 
PPTX
Personnel Monitoring on Quality Assurance and Quality Control
byTerenceFloresca
 
PDF
RADIATION PROTECTION AND BIOLOGY FINAL pdf.pdf
byonlyforstudyppt
 
PPTX
personal dosimetry.Shabnam.pptx. for radiographers
bySeyedeh Shabnam Mousavi Gezafroudi
 
PPTX
PRINCIPLES OF RADIATION DETECTION AND MEASUREMENT-1.pptx
byUrooj Mushtaq Bhat
 
PPTX
radiation protection and safetya-141003084618-phpapp02.pptx
bysudheendrapv
 
PDF
Radiation dose measurements.pdf for radiology student
bySudhanshuSingh852726
 
PPT
L13 radiation monitoring-industrial facility
byMahbubul Hassan
 
PPTX
personal dosimeter by mohit RIT(2nd) 2315693.pptx
bysueimohit05
 
PPTX
significance of dosimetry in radiotherapy
byNkjayapalan1
 
PPTX
Various Dosimetry systems in radiotherapy.pptx
byNkjayapalan1
 
PDF
15-Dosimetry and Personnel Radiation Monitoring.pdf
bysamantaram323
 
Measurement of Radiation and Dosimetric Procedure.pptx
byDr. Dheeraj Kumar
 
DOSIMETERS.pptx
byvishalmehrotra10
 
Radiation detection & measurement
bymahbubul hassan
 
Radiation monitoring devices used in medical science.pptx
byRamJoshi36
 
Dosimetry
byMd. Motiur Rahman
 
RADIATION UNITS AND PERSONNEL MONITORING.pptx
byjustinfan550
 
Chapter3 radiation dosimeters
byJeju National University
 
Measurement of absorbed dose in Radiotherapy
bySACHINS700327
 
radiation safety.pptx
bySaikatChakraborty80
 
Personnel Monitoring on Quality Assurance and Quality Control
byTerenceFloresca
 
RADIATION PROTECTION AND BIOLOGY FINAL pdf.pdf
byonlyforstudyppt
 
personal dosimetry.Shabnam.pptx. for radiographers
bySeyedeh Shabnam Mousavi Gezafroudi
 
PRINCIPLES OF RADIATION DETECTION AND MEASUREMENT-1.pptx
byUrooj Mushtaq Bhat
 
radiation protection and safetya-141003084618-phpapp02.pptx
bysudheendrapv
 
Radiation dose measurements.pdf for radiology student
bySudhanshuSingh852726
 
L13 radiation monitoring-industrial facility
byMahbubul Hassan
 
personal dosimeter by mohit RIT(2nd) 2315693.pptx
bysueimohit05
 
significance of dosimetry in radiotherapy
byNkjayapalan1
 
Various Dosimetry systems in radiotherapy.pptx
byNkjayapalan1
 
15-Dosimetry and Personnel Radiation Monitoring.pdf
bysamantaram323
 

Recently uploaded

PPTX
Enteric-Typhoid-and-Paratyphoid-Fever-2025-Update.pptx
byamarnath970868
 
PPTX
Drugs and Drug Targets: An Overview - Medicinal Chemistry Lecture 4
byAhmed167099
 
PPTX
Biochemistry
byDr. Sankalp Bhargava
 
PPTX
Pulmonary thromboembolism PTE ppt, Cardiovascular System
byNasirAbubakarMailafi
 
PPTX
Adjacent Implants soft & hard tissue Augmentation.pptx
byMostafaElGendy37
 
PDF
Marburg Viral Disease (MVD) an outbreak at Jinka, Ethiopia 2025
byAbdelaKedir3
 
PDF
SHOULDER JOINT - Prof.Dr.N.Mugunthan.pdf
byKanyakumari Medical Mission Research Center, Muttom
 
PPTX
electrocardiography in acute coronary syndrome.pptx
bysud_1187
 
PDF
DMLT (1st Year) : Blood Hemoglobin, Blood Glucose estimation and Urine routin...
byPrabhatNigam6
 
PPTX
CONNECTIVE TISSUE (Classification, Structure, Location and Functions).pptx
byPranaliChandurkar2
 
PDF
Top 5 Places to Buy Aged LinkedIn Accounts and Should ....pdf
byche3h5jojp4zk2gkv4s
 
PPTX
PASSIVE MOVEMENT PPT FILE by gokul.pptx.
byGOKULAKRISHNAN JANARTHANAN
 
PPTX
Human Organ Transplantation Act 2014, THOTA- 2014 Legal basics by Dr MB Singh...
byBalajiSinghM
 
PDF
PECTORAL REGION . Prof.Dr.N.Mugunthan.pdf
byKanyakumari Medical Mission Research Center, Muttom
 
PPTX
Drug Induced Liver Disease- Pharm-D Therapy
byAnusha Are
 
PPTX
BRAINSTEM & MIDBRAIN: BASICS OF NEUROANATOMY.pptx
byRAMA UNIVERSITY
 
PDF
Mechanisms of Drug Action (PH 1.8) - Complete Pharmacology Flowcharts
byShivankan Kakkar
 
PPTX
Gastrointestinal Disorders.pptx congenital malformation in GI TRACT
byshivadwivedi9
 
PPT
2.Approach to apatient with acute abdomen.ppt
byhikaemi8
 
PPTX
A Detailed Description of Raktagulma wrt PTSR
byDr Chandrika Kulkarni
 
Enteric-Typhoid-and-Paratyphoid-Fever-2025-Update.pptx
byamarnath970868
 
Drugs and Drug Targets: An Overview - Medicinal Chemistry Lecture 4
byAhmed167099
 
Biochemistry
byDr. Sankalp Bhargava
 
Pulmonary thromboembolism PTE ppt, Cardiovascular System
byNasirAbubakarMailafi
 
Adjacent Implants soft & hard tissue Augmentation.pptx
byMostafaElGendy37
 
Marburg Viral Disease (MVD) an outbreak at Jinka, Ethiopia 2025
byAbdelaKedir3
 
SHOULDER JOINT - Prof.Dr.N.Mugunthan.pdf
byKanyakumari Medical Mission Research Center, Muttom
 
electrocardiography in acute coronary syndrome.pptx
bysud_1187
 
DMLT (1st Year) : Blood Hemoglobin, Blood Glucose estimation and Urine routin...
byPrabhatNigam6
 
CONNECTIVE TISSUE (Classification, Structure, Location and Functions).pptx
byPranaliChandurkar2
 
Top 5 Places to Buy Aged LinkedIn Accounts and Should ....pdf
byche3h5jojp4zk2gkv4s
 
PASSIVE MOVEMENT PPT FILE by gokul.pptx.
byGOKULAKRISHNAN JANARTHANAN
 
Human Organ Transplantation Act 2014, THOTA- 2014 Legal basics by Dr MB Singh...
byBalajiSinghM
 
PECTORAL REGION . Prof.Dr.N.Mugunthan.pdf
byKanyakumari Medical Mission Research Center, Muttom
 
Drug Induced Liver Disease- Pharm-D Therapy
byAnusha Are
 
BRAINSTEM & MIDBRAIN: BASICS OF NEUROANATOMY.pptx
byRAMA UNIVERSITY
 
Mechanisms of Drug Action (PH 1.8) - Complete Pharmacology Flowcharts
byShivankan Kakkar
 
Gastrointestinal Disorders.pptx congenital malformation in GI TRACT
byshivadwivedi9
 
2.Approach to apatient with acute abdomen.ppt
byhikaemi8
 
A Detailed Description of Raktagulma wrt PTSR
byDr Chandrika Kulkarni
 
In this document
Powered by AI

Dosimeters measure exposure, kerma, absorbed dose, and equivalent dose, forming a dosimetry system.

Effective dosimeters must have accuracy, precision, wide dose range, and high spatial resolution.

Accuracy is closeness to true values; precision is reproducibility. Expressed in terms of uncertainty.

ISO guides detail how to express measurement uncertainty using standard deviations and various types.

Dosimeter readings should be linearly proportional to quantities measured; cases of linearity and saturation.

Dosimetric response should be independent of varying dose rates, maintaining consistent readings.

Dosimeter response varies with radiation energy, requiring calibration corrections for different energy types.

Personal monitoring devices are useful in varied environments for workers exposed to radiation.

Positioning of dosimeters on the body is important for effective monitoring, especially for first responders.

Film badges are cost-effective, read various radiations, and indicate levels of radiation exposure.

Features and limitations of pocket ionization chambers as personnel dosimeters with immediate readings.

TLDs use lithium fluoride crystals for accurate dose readings, sensitive to radiation but expensive.

OSL dosimeters capture and release radiation exposure data through laser stimulation, offering durability.

Radiation Dosimeters

  • 2.
    General requirements fordosimeters #Dosimeter is a device that measures directly or indirectly • Exposure • Kerma • Absorbed dose • Equivalent dose • Or other related quantities. #The dosimeter along with its reader is referred to as a dosimetry system.
  • 3.
    A useful dosimeterexhibits the following properties: • High accuracy and precision • Linearity of signal with dose over a wide range • Small dose and dose rate dependence • Flat Energy response • Small directional dependence • High spatial resolution • Large dynamic range
  • 4.
     Accuracy specifiesthe proximity of the mean value of a measurement to the true value.  Precision specifies the degree of reproducibility of a measurement. Note: High precision is equivalent to small standard deviation.
  • 5.
    Examples for useof precision and accuracy: High precision High precision Low precision Low precision and and and and High accuracy Low accuracy High accuracy Low accuracy
  • 6.
    Note: The accuracyand precision associated with a measurement is often expressed in terms of its uncertainty.
  • 7.
    New Concept bythe International Organization for Standardization (ISO) "Guide to the expression of uncertainty in measurement“  This new guide serves as a clear procedure for characterizing the quality of a measurement.  It is easily understood and generally accepted.  It defines uncertainty as a quantifiable attribute.
  • 8.
     Standard uncertainty:is the uncertainty of a result expressed as standard deviation.  Type A standard uncertainty is evaluated by statistical analysis of a series of observations.  Type B standard uncertainty is evaluated by means other than statistical analysis. This classification is for convenience of discussion only.  It is not meant to indicate that there is a difference in the nature of  the uncertainty such as random or systematic.
  • 9.
     Combined uncertainties: Thedetermination of the final result is normally based on several components. Linearity:  The dosimeter reading should be linearly proportional to the dosimetric quantity.  Beyond a certain range, usually a non-linearity sets in.  This effect depends on the type of dosimeter.
  • 10.
    Two possible cases CaseA: • linearity • supralinearity • saturation Case B: • linearity • saturation
  • 11.
    Dose rate dependence:  M/D may be called the response of a dosimeter system  When an integrated response is measured, the dosimetric quantity should be independent of the dose rate dD/dt of the quantity.  Other formulation: The response M/D should be constant for different dose rates (dD/dt)1 and (dD/dt) 2. M = 􀀁 (M / D)(dD / dt)dt M = (M / D)􀀁 (dD / dt)dt
  • 12.
     Energy: Theresponse of a dosimetric system is generally a function of the radiation energy.  The term "radiation quality" is often used to express a specific distribution of the energy of radiation.  Therefore, a dependence on energy can also be called a dependence on radiation quality.  Since calibration is done at a specified beam quality, a reading should generally be corrected if the user's beam quality is not identical to the calibration beam quality.
  • 13.
    A small radiationmonitoring device worn by persons entering environments that may contain radiation . # Desirable characteristics  Should be lightweight, durable, and reliable  Should be inexpensive
  • 14.
     Healthcare orlaboratory workers in non- emergency environments that may contain radiation  Examples: radiology, nuclear medicine, and radiation oncology department staff  Workers in emergency environments that may contain radiation  Examples: first responders and first receivers  Workers in industrial environments where radiation is used  Examples: nuclear power plant workers or employees at radiation sterilizing facilities
  • 15.
     Flat badgesare usually worn on the torso, at the collar or chest level, but can be worn on the belt, or forearm  Ring shaped badges can be worn on the finger when dose to the finger may exceed dose to the badge worn elsewhere on the body  First responders and first receivers  Wear water-resistant personal dosimeters on the outer layer of personal protective equipment (PPE).  Should be able to easily see and hear a dosimeter alarm while wearing PPE  May wear a personal dosimeter underneath waterproof outerwear
  • 16.
     Film badge Pocket ionization chambers  Thermo luminescent dosimeters (TLD)  Optically stimulated luminescence (OSL)  Solid State
  • 17.
     Most widelyused and most economical  Consists of three parts:  Plastic film holder  Metal filters  Film packet  Can read x, gamma, and beta radiation  Accurate from 10mrem - 500rem  Developed and read by densitometer  A certain density value equals a certain level of radiation  Read with a control badge  Results generally sent as a printout
  • 18.
     Lightweight, durable, portable Cost efficient  Permanent legal record  Can differentiate between scatter and primary beam  Can discriminate between x, gamma, and beta radiation  Can indicate direction from where radiation came from  Control badge can indicate if exposed in transit  Only records exposure where it’s worn  Not effective if not worn  Can be affected by heat and humidity  Sensitivity is decreased above and below 50 keV  Exposure cannot be determined on day of exposure  Accuracy limited to + or - 20%
  • 19.
     The mostsensitive personnel dosimeter  Two types  Self-reading  Non self-reading  Can only be read once  Detects gamma or x-radiation
  • 20.
     Small, compact, easyto use  Reasonably accurate and sensitive  Provides immediate reading  Expensive  Readings can be lost  Must be read each day  No permanent record  Susceptible to false readout if dropped or jarred
  • 21.
     Looks likea film badge  Contains a lithium fluoride crystal  Responds to radiation similarly to skin  Measured by a TLD analyzer  Crystal will luminescence if exposed to radiation, then heated  More accurate than a film badge
  • 22.
     Crystals contained inTLD interact with ionizing radiation as tissue does  Determines dose more accurately  The initial cost is greater than that of a film badge  Can only be read once  Records exposure only where worn
  • 23.
    • “Captures” informationin an Aluminum Oxide matrix • Releases information by laser stimulation • Can be reread after processing • Durable • Landauer Only
  • 24.
     Provides instantaneousinformation regarding dose accumulation  Simple to use  Not a “legal” record  Dose range device dependent