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ISO/ASTM 51649:2005

(Main)

Practice for dosimetry in an electron beam facility for radiation processing at energies between 300 keV and 25 MeV

Practice for dosimetry in an electron beam facility for radiation processing at energies between 300 keV and 25 MeV

ISO/ASTM 51649:2005 covers dosimetric procedures to be followed in Installation Qualification, Operational Qualification and Performance Qualifications (IQ, OQ, PQ), and routine processing at electron beam facilities to ensure that the product has been treated with an acceptable range of absorbed doses. Other procedures related to IQ, OQ, PQ, and routine product processing that may influence absorbed dose in the product are also discussed.

Pratique de la dosimétrie dans une installation de traitement par irradiation utilisant un faisceau d'électrons d'énergies comprises entre 300 keV et 25 MeV

General Information

Status
Withdrawn
Publication Date
19-Jul-2005
Withdrawal Date
19-Jul-2005
ICS
17.240 - Radiation measurements
Technical Committee
ISO/TC 85 - Nuclear energy, nuclear technologies, and radiological protection
Drafting Committee
ISO/TC 85 - Nuclear energy, nuclear technologies, and radiological protection
Current Stage
9599 - Withdrawal of International Standard
Completion Date
17-Mar-2015
Ref Project

Relations

Revised
ISO/ASTM 51649:2015 - Practice for dosimetry in an electron beam facility for radiation processing at energies between 300 keV and 25 MeV
Effective Date
07-Jun-2014
Revises
ISO/ASTM 51649:2002 - Practice for dosimetry in an electron-beam facility for radiation processing at energies between 300 keV and 25 MeV
Effective Date
15-Apr-2008

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ISO/ASTM 51649:2005 - Practice for dosimetry in an electron beam facility for radiation processing at energies between 300 keV and 25 MeVISO/ASTM 51649:2005 - Practice for dosimetry in an electron beam facility for radiation processing at energies between 300 keV and 25 MeV
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ISO/ASTM 51649:2005 - Practice for dosimetry in an electron beam facility for radiation processing at energies between 300 keV and 25 MeV
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INTERNATIONAL ISO/ASTM
STANDARD 51649
Second edition
2005-05-15
Practice for dosimetry in an electron
beam facility for radiation processing at
energies between 300 keV and 25 MeV
Pratique de la dosimétrie dans une installation de traitement par
irradiation utilisant un faisceau d’électrons d’énergies comprises
entre 300 keV et 25 MeV
Reference number
ISO/ASTM 51649:2005(E)
© ISO/ASTM International 2005

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ISO/ASTM 51649:2005(E)
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ii © ISO/ASTM International 2005 – All rights reserved

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ISO/ASTM FDIS 51649:2005(E)
Contents Page
1 Scope . 1
2 Referenced documents . 1
3 Terminology . 2
4 Significance and use . 5
5 Radiation source characteristics . 6
6 Types of irradiation facilities . 6
7 Dosimetry systems . 6
8 Process parameters . 7
9 Installation qualification . 7
10 Operational qualification . 8
11 Performance qualification . 9
12 Routine product processing . 11
13 Measurement uncertainty . 12
14 Certification . 12
15 Keywords . 12
Annexes . 12
Bibliography . 29
Figure 1 Example pulse current (I ), average beam current (I ), pulse width (W) and
pulse avg
repetition rate (f) for a pulsed accelerator . 2
Figure 2 Diagram showing beam length and width for a scanned beam using a conveyor
system . 3
Figure 3 Example of electron-beam dose distribution along the beam width with the width noted
at some defined fractional level f of the average maximum dose D . 3
max
Figure 4 A typical depth-dose distribution for an electron beam in a homogeneous material . 4
Figure 5 Typical pulse current waveform from an S-Band linear accelerator . 5
Figure A1.1 Calculated depth-dose distribution curves in various homogeneous polymers for
normally incident monoenergetic electrons at 5.0 MeV using the Program ITS3 . 13
Figure A1.2 Calculated depth-dose distribution curves in various homogeneous metals for
normally incident monoenergetic electrons at 5.0 MeV using the Program ITS3 . 14
Figure A1.3 Calculated depth-dose distribution curves in polystyrene for normally incident
electrons at monoenergetic energies from 300 to 1000 keV using the Program ITS3 . 15
Figure A1.4 Calculated depth-dose distribution curves in polystyrene for normally incident, plane
parallel incident electrons at monoenergetic energies from 1.0 to 5.0 MeV using the program ITS3
.................................................................................................................................................. 16
Figure A1.5 Calculated depth-dose distribution curves in polystyrene for normally incident, plane
parallel incident electrons at monoenergetic energies from 5.0 to 12.0 MeV using the program
ITS3 . 17
Figure A1.6 Calculated depth-dose distribution curves in Al and Ta for normally incident, plane
parallel incident electrons at a monoenergetic energy of 25 MeV using the program ITS3 . 18
Figure A1.7 Electron energy deposition D (0) at the entrance surface of a polystyrene absorber
e
as a function of incident electron energy from 0.3 MeV to 12 MeV corresponding to the Monte
Carlo calculated data shown in Figs. A1.3-A1.5 . 18
Figure A1.8 Electron energy deposition D (0) at the entrance surface of a polystyrene absorber
e
as a function of incident electron energy from 0.3 MeV to 2.0 MeV corresponding to the Monte
Carlo calculated data shown in Fig. A1.3 and Fig. A1.4 . 19
Figure A1.9 Superposition of theoretically calculated depth-dose distribution curves for aluminum
© ISO/ASTM International 2005 – All rights reserved iii

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ISO/ASTM FDIS 51649:2005(E)
irradiated with 5 MeV monoenergetic electrons from both sides with different thicknesses (T) and
from one side using experimental data presented in Refs (12 and 25) . 19
Figure A1.10 Calculated correlations between optimum electron range R , half-value depth R ,
opt 50
half-entrance depth R , and practical range R , and incident electron energy for polystyrene
50e p
using Fig. A1.3 and Fig. A1.4 . 20
Figure A1.11 Calculated correlations between optimum electron range R , half-value depth R ,
opt 50
half-entrance depth R , and practical range R , and incident electron energy for polystyrene
50e p
using Figs. A1.4 and A1.5 . 20
Figure A1.12 Measured depth-dose distribution curves for nominal 10 MeV electron beams
,
incident on polystyrene for two electron beam facilities . 21
Figure A1.13 Depth-dose distribution curves in stacks of cellulose acetate films backed with
wood, aluminum, and iron for incident electrons with 400 keV energy . 22
Figure A1.14 Depth-dose distributions with 2 MeV electrons incident on polystyrene absorbers at
various angles from the normal direction . 22
Figure A3.1 Measured depth-dose distribution curve in aluminum for a 10 MeV electron beam in
comparison with the calculated relative depth-dose distribition using ITS3 . 25
Figure A3.2 Stack energy measurement device . 26
Figure A3.3 Wedge energy measurement device . 27
Table A1.1 Key parameters for measured depth-dose distribution curves presented in Fig. A1.12 . 21
Table A1.2 Electron energy deposition D (0) at the entrance surface of a polystyrene absorber as
e
a function of incident electron energy from 0.3 MeV to 12 MeV corresponding to the calculated
curves shown in Figs. A1.3-A1.5 . 21
Table A1.3 Compatible units for the quantities used in Eq A1.1 . 22
Table A3.1 Some relevant properties of common reference materials . 24
Table A3.2 Half-value depth R , half-entrance depth R , optimum thickness R and practical
50 50e opt
range R in polystyrene for monoenergetic electron energies E from 0.3 to 12 MeV derived from
p
Monte Carlo calculations . 24
Table A3.3 Half-value depth R , practical range R and extrapolated range R in aluminum for
50 p ex
monoenergetic electron energies E from 2.5 to 25 MeV derived from Monte Carlo calculations . 25
iv © ISO/ASTM International 2005 – All rights reserved

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ISO/ASTM 51649:2005(E)
Foreword
ISO(theInternationalOrganizationforStandardization)isaworldwidefederationofnationalstandardsbodies
(ISO member bodies). The work of preparing International Standards is normally carried out through ISO
technical committees. Each member body interested in a subject for which a technical committee has been
established has the right to be represented on that committee. International organizations, governmental and
non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the
International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
Draft International Standards adopted by the technical committees are circulated to the member bodies for
voting. Publication as an International Standard requires approval by at least 75% of the member bodies
casting a vote.
ASTM International is one of the world’s largest voluntary standards development organizations with global
participation from affected stakeholders. ASTM technical committees follow rigorous due process balloting
procedures.
A project between ISO and ASTM International has been formed to develop and maintain a group of
ISO/ASTM radiation processing dosimetry standards. Under this project, ASTM Subcommittee E10.01,
Dosimetry for Radiation Processing, is responsible for the development and maintenance of these dosimetry
standards with unrestricted participation and input from appropriate ISO member bodies.
Attention is drawn to the possibility that some of the elements of this document may be the subject of patent
rights. Neither ISO nor ASTM International shall be held responsible for identifying any or all such patent
rights.
International Standard ISO/ASTM 51649 was developed byASTM Committee E10, Nuclear Technology and
Applications, through Subcommittee E10.01, and by Technical Committee ISO/TC 85, Nuclear energy.
This second edition cancels and replaces the first edition (ISO/ASTM 51649:2002), which has been
technically revised.
© ISO/ASTM International 2005 – All rights reserved v

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ISO/ASTM 51649:2005(E)
Standard Practice for
Dosimetry in an Electron Beam Facility for Radiation
1
Processing at Energies Between 300 keV and 25 MeV
This standard is issued under the fixed designation ISO/ASTM 51649; the number immediately following the designation indicates the
year of original adoption or, in the case of revision, the year of last revision.
1. Scope 2. Referenced documents
2
1.1 This practice covers dosimetric procedures to be fol- 2.1 ASTM Standards:
lowed in Installation Qualification, Operational Qualification E 170 Terminology Relating to Radiation Measurements
and Performance Qualifications (IQ, OQ, PQ), and routine and Dosimetry
processing at electron beam facilities to ensure that the product E 1026 Practice for Using the Fricke Reference Standard
has been treated with an acceptable range of absorbed doses. Dosimetry System
Other procedures related to IQ, OQ, PQ, and routine product E 2232 Guide for Selection and Use of Mathematical Meth-
processing that may influence absorbed dose in the product are odsforCalculatingAbsorbedDoseinRadiationProcessing
also discussed. Applications
E 2303 Guide to Dose Mapping in Radiation Processing
NOTE 1—For guidance in the selection and calibration of dosimeters,
Facilities
see ISO/ASTM Guide 51261. For further guidance in the use of specific
2
2.2 ISO/ASTM Standards:
dosimetry systems, and interpretation of the measured absorbed dose in
51205 PracticeforUseofaCeric-CerousSulfateDosimetry
the product, also see ISO/ASTM Practices 51275, 51276, 51431, 51607,
51631, 51650, and 51956. For use with electron energies above 5 MeV,
System
see Practice E 1026, and ISO/ASTM Practices 51205, 51401, 51538, and
51261 Guide for Selection and Calibration of Dosimetry
51540 for discussions of specific large volume dosimeters. For discussion
Systems for Radiation Processing
of radiation dosimetry for pulsed radiation, see ICRU Report 34.
51275 Practice for Use of a Radiochromic Film Dosimetry
1.2 The electron beam energy range covered in this practice
System
is between 300 keV and 25 MeV, although there are some
51276 Practice for Use of a Polymethylmethacrylate Do-
discussions for other energies.
simetry System
1.3 Dosimetry is only one component of a total quality
51400 Practice for Characterization and Performance of a
assurance program for an irradiation facility. Other measures
High-Dose Radiation Dosimetry Calibration Laboratory
besides dosimetry may be required for specific applications
51401 Practice for Use of a Dichromate Dosimetry System
such as medical device sterilization and food preservation.
51431 Practice for Dosimetry in Electron and X-ray
1.4 Other specific ISO and ASTM standards exist for the
(Bremsstrahlung) Irradiation Facilities for Food Process-
irradiation of food and the radiation sterilization of health care
ing
products. For food irradiation, see ISO/ASTM Practice 51431.
51538 Practice for Use of an Ethanol-Chlorobenzene Do-
For the radiation sterilization of health care products, see ISO
simetry System
11137. In those areas covered by ISO 11137, that standard
51539 Guide for the Use of Radiation-Sensitive Indicators
takes precedence.
51540 Practice for Use of a Radiochromic Liquid Solution
1.5 This standard does not purport to address all of the
Dosimetry System
safety concerns, if any, associated with its use. It is the
51607 Practice for Use of the Alanine–EPR Dosimetry
responsibility of the user of this standard to establish appro-
System
priate safety and health practices and determine the applica-
51631 Practice for Use of Calorimetric Dosimetry Systems
bility of regulatory requirements prior to use.
for Electron Beam Measurements and Dosimeter Calibra-
tions
51650 Practice for Use of a Cellulose Triacetate Dosimetry
1
This practice is under the jurisdiction of ASTM Committee E10 on Nuclear System
Technology and Applications and is the direct responsibility of Subcommittee
51707 Guide for Estimating Uncertainties in Dosimetry for
E10.01 on Dosimetry for Radiation Processing, and is also under the jurisdiction of
Radiation Processing
ISO/TC 85/WG 3.
Current edition approved by ASTM June 1, 2004. Published May 15, 2005.
OriginallypublishedasE 1649–94.LastpreviousASTMeditionE 1649–00.ASTM
e1 2
E 1649–94 was adopted by ISO in 1998 with the intermediate designation ISO For referenced ASTM and ISO/ASTM standards, visit the ASTM website,
15569:1998(E). The present International Standard ISO/ASTM 51649:2005(E) is a www.astm.org, or contact ASTM Customer Service at service@astm.org. For
major revision of the last previous edition ISO/ASTM 51649:2002(E), which Annual Book of ASTM Standards volume information, refer to the standard’s
replaced ISO 15569. Document Summary page on the ASTM website.
© ISO/ASTM International 2005 – All rights reserved
1

---------------------- Page: 6 ----------------------
ISO/ASTM 51649:2005(E)
– –
51956 Practice for Thermoluminescence Dosimetry (TLD)
ship is the quotient of de by dm, where de is the mean
Systems for Radiation Processing
incremental energy imparted by ionizing radiation to matter of
3
2.3 ISO Standard:
incremental mass dm.
ISO 11137 Sterilization of Health Care Products–Require-

D 5 de/dm
ments for Validation and Routine Control–Radiation Ster-
ilization
3.1.1.1 Discussion—The discontinued unit for absorbed
2.4 International Commission on Radiation Units and
dose is the rad (1 rad = 100 erg/g = 0.01 Gy). Absorbed dose
4
Measurements (ICRU) Reports:
is sometimes referred to simply as dose.
ICRU Report 34 The Dosimetry of Pulsed Radiation
3.1.2 average beam current—time-averaged electron beam
ICRUReport35 RadiationDosimetry:ElectronBeamswith
current; for a pulsed machine, the averaging shall be done over
Energies Between 1 and 50 MeV
a large number of pulses (see Fig. 1).
ICRU Report 37 Stopping Powers for Electrons and
3.1.3 beam length—dimension of the irradiation zone, per-
Positrons
pendicular to the beam width and direction of the electron
ICRU Report 60 Fundamental Quantities and Units for
beam at a specified distance from the accelerator window (see
Ionizing Radiation
Fig. 2).
3. Terminology 3.1.4 beam power—product of the average electron beam
energy and the average beam current.
3.1 Definitions:
3.1.5 beam spot—shape of the unscanned electron beam
3.1.1 absorbed dose (D)—quantity of ionizing radiation
incident on the reference plane.
energy imparted per unit mass of a specified material. The SI
unit of absorbed dose is the gray (Gy), where 1 gray is 3.1.6 beam width—dimension of the irradiation zone in the
equivalent to the absorption of 1 joule per kilogram in the direction that the beam is scanned, perpendicular to the beam
specified material (1 Gy = 1 J/kg). The mathematical relation- lengthanddirectionoftheelectronbeamataspecifieddistance
from the accelerator window (see Fig. 2).
3.1.6.1 Discussion—For a radiation processing facility with
3
Available from International Organization for Standardization, 1 Rue de
a conveyor system, the beam width is usually perpendicular to
Varembé, Case Postale 56, CH-1211 Geneva 20, Switzerland.
4 the flow of motion of the conveyor (see Fig. 2). Beam width is
Available from the International Commission on Radiation Units and Measure-
ments, 7910 Woodmont Ave., Suite 800, Bethesda MD 20814, U.S.A. the distance between two points along the dose profile, which
FIG. 1 Example pulse current (I ), average beam current (I ), pulse width (W) and repetition rate (f) for a pulsed accelerator
pulse avg
© ISO/ASTM International 2005 – All rights reserved
2

---------------------- Page: 7 ----------------------
ISO/ASTM 51649:2005(E)
configuration, or simulated product used at the beginning or
end of a production run, to compensate for the absence of
product.
3.1.7.1 Discussion—Simulatedproductorphantommaterial
may be used during irradiator characterization as a substitute
for the actual product, material or substance to be irradiated.
3.1.8 continuous-slowing-down-approximation (CSDA)
range (r )—average pathlength traveled by a charged particle
0
as it slows down to rest, calculated in the continuous-slowing-
down-aproximation method.
3.1.8.1 Discussion—In this approximation, the rate of en-
ergy loss at every point along the track is assumed to be equal
to the total stopping power. Energy-loss fluctuations are
neglected. The CSDA range is obtained by integrating the
reciprocal of the total stopping power with respect to energy.
Values of r for a wide range of electron energies and for many
0
materials can be obtained from ICRU Report 37.
3.1.9 depth-dose distribution—variation of absorbed dose
FIG. 2 Diagram showing beam length and width for a scanned
beam using a conveyor system
with depth from the incident surface of a material exposed to
a given radiation.
3.1.9.1 Discussion—Typical distributions in homogeneous
are at a defined level from the maximum dose region in the materials produced by an electron beam along the beam axis
are shown in Figs. A1.1 and A1.2. See Annex A1.
profile (see Fig. 3). Various techniques may be employed to
produce an electron beam width adequate to cover the process-
3.1.10 dose uniformity ratio—ratio of the maximum to the
ing zone, for example, use of electromagnetic scanning of a minimum absorbed dose within the process load. The concept
pencil beam (in which case beam width is also referred to as
is also referred to as the max/min dose ratio.
scan width), defocussing elements, and scattering foils.
3.1.11 dosimetry system—system used for determining ab-
3.1.7 compensating dummy—simulatedproductusedduring sorbed dose, consisting of dosimeters, measurement instru-
routine production runs in process loads that contain less ments and their associated reference standards, and procedures
product than specified in the documented product-loading for the system’s use.
NOTE—McKeown, J., AECL Accelerators, private communication, 1993. Example of a beam width profile of an AECL Impela accelerator.
FIG. 3 Example of electron-beam dose distribution along the beam width with the width noted at some defined fractional level f of the
average maximum dose D
max
© ISO/ASTM International 2005 – All rights reserved
3

---------------------- Page: 8 ----------------------
ISO/ASTM 51649:2005(E)
3.1.12 duty cycle—for a pulsed accelerator, the fraction of 3.1.19 optimum thickness (R )—depth in homogeneous
opt
time the beam is effectively on; it is the product of the pulse material at which the absorbed dose equals the absorbed dose
width in seconds and the pulse rate in pulses per second. at the surface where the electron beam enters (see Fig. 4).
3.1.13 electron beam energy—average kinetic energy of the 3.1.20 practical electron range (R )—depth in homoge-
p
accelerated electrons in the beam. Unit: J neous material to the point where the tangent at the steepest
3.1.13.1 Discussion—Electron volt (eV) is often used as the point (the inflection point) on the almost straight descending
-19
portion of the depth-dose distribution curve meets the extrapo-
unit for electron beam energy where 1 eV = 1.602·10 J
(approximately). In radiation processing, where beams with a latedX-raybackground(seeFig.4andFig.A1.6inAnnexA1).
broad electron energy spectrum are frequently used, the terms 3.1.21 extrapolated electron range (R )—depth in homo-
ex
most probable energy (E ) and average energy (E ) are geneous material to the point where the tangent at the steepest
p a
common. They are linked to the practical electron range R point (the inflection point) on the almost straight descending
p
and half-value depth R by empirical equations. portion of the depth-dose distribution curve meets the depth
50
3.1.14 electron beam facility—establishment that uses ener- axis (see Fig. A1.6 in Annex A1).
getic electrons produced by particle accelerators to irradiate 3.1.22 process load—volume of product with a specified
product. loading configuration processed as a single entity; this term is
not relevant to bulk-flow processing.
3.1.15 electron energy spectrum—particle fluence distribu-
tion of electrons as a function of energy. 3.1.23 production run—seriesofprocessloadsconsistingof
materials,orproductshavingsimilarradiation-absorptionchar-
3.1.16 electron range—penetration distance in a specific,
acteristics, that are irradiated sequentially to a specified range
totally absorbing material along the beam axis of the electrons
of absorbed dose.
incident on the material (equivalent to practical electron range,
3.1.24 pulse beam current, for a pulsed accelerator—beam
R ).
P
current averaged over the top ripples (aberrations) of the pulse
3.1.16.1 Discussion—R can be measured from experimen-
P
current waveform; this is equal to I /wf, where I is the
tal depth-dose distributions in a given material. Other forms of
avg avg
average beam current, w is the pulse width, and f is the pulse
electron range are found in the dosimetry literature, for
rate (see Fig. 5).
example, extrapolated range derived from depth-dose data and
3.1.25 pulse rate, for a pulsed accelerator—pulse repetition
the continuous-slowing-down-approximation range (the calcu-
lated pathlength traversed by an electron in a material in the frequency in hertz, or pulses per second; this is also referred to
as the repetition (rep) rate.
course of completely slowing down). Electron range is usually
-2
expressed in terms of mass per unit area (kg·m ), but some- 3.1.26 pulse width, for a pulsed accelerator—time interval
times in terms of thickness (m) for a specified material. between two points on the leading and trailing edges of the
pulse current waveform where the current is 50 % of its peak
3.1.17 half-entrance depth (R )—depth in homogeneous
50e
material at which the absorbed dose has decreased down to value (see Fig. 5).
50 % of the absorbed dose at the surface of the material (see 3.1.27 reference material—homogeneous material of
Fig. 4). known radiation absorption and scattering properties used to
establish characteristics of the irradiation process, such as scan
3.1.18 half-value depth (R )—depth in homogeneous ma-
50
uniformity, depth-dose distribution, throughput rate, and repro-
terial at which the absorbed dose has decreased down to 50 %
ducibility of dose delivery.
of its maximum value (see Fig. 4).
3.1.28 reference plane—selected plane in the radiation zone
that is perpendicular to the electron beam axis.
3.1.29 scannedbeam—electronbeamthatissweptbackand
forth with a varying magnetic field.
3.1.29.1 Discussion—This is most commonly done along
one dimension (beam width), although two-dimensional scan-
ning (beam width and length) may be used with high-current
electron beams to avoid overheating the beam exit window of
the accelerator or product under the scan horn.
3.1.30 scan frequency—number of complete scanning
cycles per second expressed in Hz.
3.1.31 scan uniformity—degree of uniformity of the dose
measured along the scan direction.
3.1.32 simulated product—mass of material with attenua-
tion and scattering properties similar to those of the product,
material or substance to be irradiated.
3.1.32.1 Discussion—Simulated product is used during ir-
radiator characterization as a substitute for the actual product,
material or substance to be irradiated. When used in routine
FIG. 4 A typical depth-dose distribution for an electron beam in a
homogeneous material production runs, it is sometimes referred to as compensating
© ISO/ASTM International 2005 – All rights reserved
4

---------------------- Page: 9 ----------------------
ISO/ASTM 51649:2005(E)
FIG. 5 Typical pulse current waveform from an S-Band linear accelerator
dummy. When used for absorbed-dose mapping, simulated 4.1.3 Curing of composite materials,
product is sometimes referred to as phantom material. 4.1.4 Sterilization of medical devices,
3.1.33 standardized depth (z)—thickness of the absorbing 4.1.5 Disinfection of consumer products,
material expressed as the mass per unit area, which is equal to 4.1.6 Food irradiation (parasite and pathogen control, insect
the depth in the material t times the density r.If m is the mass disinfestation, and shelf-life extension),
of the material beneath that area and A is the area of the 4.1.7 Control of pathogens and toxins in drinking water,
material through which the beam passes, then: 4.1.8 Control of pathogens and toxins in liquid or solid
waste,
z 5 m/A 5 tr
4.1.9 Modification of characteristics of semiconductor de-
If t is in meters and r in kilograms per cubic meter, then z is
vices,
in kilograms per square meter.
4.1.10 Color enhancement of gemstones and other materi-
3.1.33.1 Discussion—It is common practice to express t in
als, and
3
centimeters and r in grams per cm , then z is in grams per
4.1.11 Rese
...

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ISO
ISO/ASTM 51940:2022(Main)
Guidance for dosimetry for sterile insects release programs

1.1 This document outlines dosimetric procedures to be followed for the radiation-induced reproductive sterilization of live insects for use in pest management programs. The primary use of such insects is in the Sterile Insect Technique, where large numbers of reproductively sterile insects are released into the field to mate with and thus control pest populations of the same species. A secondary use of sterile insects is as benign hosts for rearing insect parasitoids. A third use is for testing detection traps for fruit flies and moths, and testing mating disruption products for moths. The procedures outlined in this document will help ensure that insects processed with ionizing radiation from gamma, electron, or X-ray sources receive absorbed doses within a predetermined range. Information on effective dose ranges for specific applications of insect sterilization, or on methodology for determining effective dose ranges, is not within the scope of this document. NOTE 1—Dosimetry is only one component of a total quality assurance program to ensure that irradiated insects are adequately sterilized and fully competitive or otherwise suitable for their intended purpose. 1.2 This document provides information on dosimetry for the irradiation of insects for these types of irradiators: selfcontained dry-storage 137Cs or 60Co irradiators, self-contained low-energy X-ray irradiators (maximum processing energies from 150 keV to 300 keV), large-scale gamma irradiators, and electron accelerators (electron and X-ray modes). NOTE 2—Additional, detailed information on dosimetric procedures to be followed in installation qualification, operational qualification, performance qualification, and routine product processing can be found in ISO/ASTM Practices 51608 (X-ray [bremsstrahlung] facilities processing at energies over 300 keV), 51649 (electron beam facilities), 51702 (large-scale gamma facilities), and 52116 (self-contained dry-storage gamma facilities), and in Ref (1)2 (self-contained X-ray facilities). 1.3 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard except for the non-SI units of minute (min) hour (h) and day (d). These non-SI units are accepted for use within the SI system. 1.4 This document is one of a set of standards that provides recommendations for properly implementing and utilizing radiation processing. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.5 The absorbed dose for insect sterilization is typically within the range of 20 Gy to 600 Gy. 1.6 This document refers, throughout the text, specifically to reproductive sterilization of insects. It is equally applicable to radiation sterilization of invertebrates from other taxa (for example, Acarina, Gastropoda) and to irradiation of live insects or other invertebrates for other purposes (for example, inducing mutations), provided the absorbed dose is within the range specified in 1.5. 1.7 This document also covers the use of radiation-sensitive indicators for the visual and qualitative indication that the insects have been irradiated (see ISO/ASTM Guide 51539). 1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.9 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 51310:2022(Main)
Practice for use of a radiochromic optical waveguide dosimetry system

1.1 This is a practice for using a radiochromic optical waveguide dosimetry system to measure absorbed dose in materials irradiated by photons and high energy electrons in terms of absorbed dose to water. The radiochromic optical waveguide dosimetry system is generally used as a routine dosimetry system. 1.2 The optical waveguide dosimeter is classified as a Type II dosimeter on the basis of the complex effect of influence quantities (see ISO/ASTM Practice 52628). 1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 for an optical waveguide dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.4 This practice applies to radiochromic optical waveguide dosimeters that can be used within part or all of the specified ranges as follows: 1.4.1 The absorbed dose range is from 1 Gy to 20 000 Gy. 1.4.2 The absorbed dose rate is from 0.001 Gy/s to 1000 Gy/s. 1.4.3 The radiation photon energy range is from 1 MeV to 10 MeV. 1.4.4 The radiation electron energy range is from 3 MeV to 25 MeV. 1.4.5 The irradiation temperature range is from –78 °C to +60 °C. 1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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    6 pages
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ISO
ISO/ASTM 51818:2020(Main)
Practice for dosimetry in an electron beam facility for radiation processing at energies between 80 and 300 keV

This practice covers dosimetric procedures to be followed in installation qualification, operational qualification and performance qualification (IQ, OQ, PQ), and routine processing at electron beam facilities to ensure that the product has been treated with an acceptable range of absorbed doses. Other procedures related to IQ, OQ, PQ, and routine product processing that may influence absorbed dose in the product are also discussed. The electron beam energy range covered in this practice is between 80 and 300 keV, generally referred to as low energy. Dosimetry is only one component of a total quality assurance program for an irradiation facility. Other measures may be required for specific applications such as medical device sterilization and food preservation. Other specific ISO and ASTM standards exist for the irradiation of food and the radiation sterilization of health care products. For the radiation sterilization of health care products, see ISO 11137-1. In those areas covered by ISO 11137-1, that standard takes precedence. For food irradiation, see ISO 14470. Information about effective or regulatory dose limits for food products is not within the scope of this practice (see ASTM F1355 and F1356). This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628. It is intended to be read in conjunction with ISO/ASTM 52628. This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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  • Draft
    13 pages
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ISO
ISO/ASTM 52628:2020(Main)
Standard practice for dosimetry in radiation processing

This practice describes the basic requirements that apply when making absorbed dose measurements in accordance with the ASTM E61 series of dosimetry standards. In addition, it provides guidance on the selection of dosimetry systems and directs the user to other standards that provide specific information on individual dosimetry systems, calibration methods, uncertainty estimation and radiation processing applications. This practice applies to dosimetry for radiation processing applications using electrons or photons (gamma- or X-radiation). This practice addresses the minimum requirements of a measurement management system, but does not include general quality system requirements. This practice does not address personnel dosimetry or medical dosimetry. This practice does not apply to primary standard dosimetry systems. This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.

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ISO
ISO/ASTM 51631:2020(Main)
Practice for use of calorimetric dosimetry systems for dose measurements and dosimetry system calibration in electron beams

This practice covers the preparation and use of semiadiabatic calorimetric dosimetry systems for measurement of absorbed dose and for calibration of routine dosimetry systems when irradiated with electrons for radiation processing applications. The calorimeters are either transported by a conveyor past a scanned electron beam or are stationary in a broadened beam. This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for a calorimetric dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. The calorimeters described in this practice are classified as Type II dosimeters on the basis of the complex effect of influence quantities. See ISO/ASTM Practice 52628. This practice applies to electron beams in the energy range from 1.5 to 12 MeV. The absorbed dose range depends on the calorimetric absorbing material and the irradiation and measurement conditions. Minimum dose is approximately 100 Gy and maximum dose is approximately 50 kGy. The average absorbed-dose rate range shall generally be greater than 10 Gy·s-1. The temperature range for use of these calorimetric dosimetry systems depends on the thermal resistance of the calorimetric materials, on the calibration range of the temperature sensor, and on the sensitivity of the measurement device. This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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    9 pages
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ISO
ISO/ASTM 51276:2019(Main)
Practice for use of a polymethylmethacrylate dosimetry system

1.1 This is a practice for using polymethylmethacrylate (PMMA) dosimetry systems to measure absorbed dose in materials irradiated by photons or electrons in terms of absorbed dose to water. The PMMA dosimetry system is generally used as a routine dosimetry system. 1.2 The PMMA dosimeter is classified as a Type II dosim-eter on the basis of the complex effect of influence quantities (see ISO/ASTM Practice 52628). 1.3 This document is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM 52628 "Prac-tice for Dosimetry in Radiation Processing" for a PMMA dosimetry system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.4 This practice covers the use of PMMA dosimetry systems under the following conditions: 1.4.1 the absorbed dose range is 0.1 kGy to 150 kGy. 1.4.2 the absorbed dose rate is1×10−2 to1×107 Gy·s−1. 1.4.3 the photon energy range is 0.1 to 25 MeV. 1.4.4 the electron energy range is 3 to 25 MeV. 1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appro-priate safety, health, and environmental practices and deter-mine the applicability of regulatory limitations prior to use. 1.6 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for the Development of International Standards, Guides and Recom-mendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ISO
ISO/ASTM 51538:2017(Main)
Practice for use of the ethanol-chlorobenzene dosimetry system

1.1 This practice covers the preparation, handling, testing, and procedure for using the ethanol-chlorobenzene (ECB) dosimetry system to measure absorbed dose to water when exposed to ionizing radiation. The system consists of a dosimeter and appropriate analytical instrumentation. For simplicity, the system will be referred to as the ECB system. The ECB dosimeter is classified as a type I dosimeter on the basis of the effect of influence quantities. The ECB dosimetry system may be used as a reference standard dosimetry system or as a routine dosimetry system. 1.2 ISO/ASTM 51538 is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for the ECB system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.3 This practice describes the mercurimetric titration analysis as a standard readout procedure for the ECB dosimeter when used as a reference standard dosimetry system. Other readout methods (spectrophotometric, oscillometric) that are applicable when the ECB system is used as a routine dosimetry system are described in Annex A1 and Annex A2. 1.4 This practice applies only to gamma radiation, X-radiation/bremsstrahlung, and high energy electrons. 1.5 This practice applies provided the following conditions are satisfied: 1.5.1 The absorbed dose range is between 10 Gy and 2 MGy for gamma radiation and between 10 Gy and 200 kGy for high current electron accelerators (1, 2) (Warning?the boiling point of ethanol chlorobenzene solutions is approximately 80 °C. Ampoules may explode if the temperature during irradiation exceeds the boiling point. This boiling point may be exceeded if an absorbed dose greater than 200 kGy is given in a short period of time.) 1.5.2 The absorbed-dose rate is less than 106 Gy s−1(2). 1.5.3 For radionuclide gamma-ray sources, the initial pho-ton energy is greater than 0.6 MeV. For bremsstrahlung photons, the energy of the electrons used to produce the bremsstrahlung photons is equal to or greater than 2 MeV. For electron beams, the initial electron energy is greater than 8 MeV (3). NOTE 1 The same response relative to 60Co gamma radiation was obtained in high-power bremsstrahlung irradiation produced bya5MeV electron accelerator (4). NOTE 2 The lower energy limits are appropriate for a cylindrical dosimeter ampoule of 12-mm diameter. Corrections for dose gradients across the ampoule may be required for electron beams. The ECB system may be used at lower energies by employing thinner (in the beam direction) dosimeters (see ICRU Report 35). The ECB system may also be used at X-ray energies as low as 120 kVp (5). However, in this range of photon energies the effect caused by the ampoule wall is considerable. NOTE 3 The effects of size and shape of the dosimeter on the response of the dosimeter can adequately be taken into account by performing the appropriate calculations using cavity theory (6). 1.5.4 The irradiation temperature of the dosimeter is within the range from −30 °C to 80 °C. NOTE 4 The temperature dependence of dosimeter response is known only in this range (see 5.2). For use outside this range, the dosimetry system should be calibrated for the required range of irradiation tempera-tures. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use. Specific warnings are given in 1.5.1, 9.2 and 10.2. 1.7 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for the Development of International Standards, Guides and Recom-mendations issued by the World Trade Organization Technical

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ISO
ISO/ASTM 51205:2017(Main)
Practice for use of a ceric-cerous sulfate dosimetry system

1.1 This practice covers the preparation, testing, and procedure for using the ceric-cerous sulfate dosimetry system to measure absorbed dose to water when exposed to ionizing radiation. The system consists of a dosimeter and appropriate analytical instrumentation. For simplicity, the system will be referred to as the ceric-cerous system. The ceric-cerous dosimeter is classified as a type 1 dosimeter on the basis of the effect of influence quantities. The ceric-cerous system may be used as a reference standard dosimetry system or as a routine dosimetry system. 1.2 ISO/ASTM 51205:2017 is one of a set of standards that provides recommendations for properly implementing dosimetry in radiation processing, and describes a means of achieving compliance with the requirements of ISO/ASTM Practice 52628 for the ceric-cerous system. It is intended to be read in conjunction with ISO/ASTM Practice 52628. 1.3 This practice describes both the spectrophotometric and the potentiometric readout procedures for the ceric-cerous system. 1.4 This practice applies only to gamma radiation, X-radiation/bremsstrahlung, and high energy electrons.

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