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Roentgen (unit)

April 11, 2024

Not to be confused with roentgen equivalent man or roentgen equivalent physical.

The roentgen or röntgen (/ˈrɛntɡən, -ən, ˈrʌnt-/;[2] symbol R) is a legacy unit of measurement for the exposure of X-rays and gamma rays, and is defined as the electric charge freed by such radiation in a specified volume of air divided by the mass of that air (statcoulomb per kilogram). In 1928, it was adopted as the first international measurement quantity for ionizing radiation to be defined for radiation protection, as it was then the most easily replicated method of measuring air ionization by using ion chambers.[3] It is named after the German physicist Wilhelm Röntgen, who discovered X-rays and was awarded the first Nobel Prize in Physics for the discovery.

Roentgen
Display of quartz fiber dosimeter, in units of roentgen.[1]
General information
Unit systemLegacy unit
Unit ofExposure to ionizing radiation
SymbolR
Named afterWilhelm Röntgen
Conversions
1 R in ...... is equal to ...
   SI base units   2.58×10−4 As/kg

However, although this was a major step forward in standardising radiation measurement, the roentgen has the disadvantage that it is only a measure of air ionisation, and not a direct measure of radiation absorption in other materials, such as different forms of human tissue. For instance, one roentgen deposits 0.00877 grays (0.877 rads) of absorbed dose in dry air, or 0.0096 Gy (0.96 rad) in soft tissue.[3] One roentgen of X-rays may deposit anywhere from 0.01 to 0.04 Gy (1.0 to 4.0 rad) in bone depending on the beam energy.[4]

As the science of radiation dosimetry developed, it was realised that the ionising effect, and hence tissue damage, was linked to the energy absorbed, not just radiation exposure. Consequently new radiometric units for radiation protection were defined which took this into account. In 1953 the International Commission on Radiation Units and Measurements (ICRU) recommended the rad, equal to 100 erg/g, as the unit of measure of the new radiation quantity absorbed dose. The rad was expressed in coherent cgs units.[5] In 1975 the unit gray was named as the SI unit of absorbed dose. One gray is equal to 1 J/kg (i.e. 100 rad). Additionally, a new quantity, kerma, was defined for air ionisation as the exposure for instrument calibration, and from this the absorbed dose can be calculated using known coefficients for specific target materials. Today, for radiation protection, the modern units, absorbed dose for energy absorption and the equivalent dose (sievert) for stochastic effect, are overwhelmingly used, and the roentgen is rarely used. The International Committee for Weights and Measures (CIPM) has never accepted the use of the roentgen.

The roentgen has been redefined over the years. It was last defined by the U.S.'s National Institute of Standards and Technology (NIST) in 1998 as 2.58×10−4 C/kg, with a recommendation that the definition be given in every document where the roentgen is used.[6]

History edit

The roentgen has its roots in the Villard unit defined in 1908 by the American Roentgen Ray Society as "the quantity of radiation which liberates by ionisation one esu of electricity per cm3 of air under normal conditions of temperature and pressure."[7][8] Using 1 esu ≈ 3.33564×10−10 C and the air density of ~1.293 kg/m3 at 0 °C and 101 kPa, this converts to 2.58 × 10−4 C/kg, which is the modern value given by NIST.

esu/cm3 × 3.33564 × 10−10 C/esu × 1,000,000 cm3/m3 ÷ 1.293 kg/m3 = 2.58 × 10−4 C/kg

This definition was used under different names (e, R, and German unit of radiation) for the next 20 years. In the meantime, the French Roentgen was given a different definition which amounted to 0.444 German R.

ICR definitions edit

In 1928, the International Congress of Radiology (ICR) defined the roentgen as "the quantity of X-radiation which, when the secondary electrons are fully utilised and the wall effect of the chamber is avoided, produce in 1 cc of atmospheric air at 0 °C and 76 cm of mercury pressure such a degree of conductivity that 1 esu of charge is measured at saturation current."[7] The stated 1 cc of air would have a mass of 1.293 mg at the conditions given, so in 1937 the ICR rewrote this definition in terms of this mass of air instead of volume, temperature and pressure.[9] The 1937 definition was also extended to gamma rays, but later capped at 3 MeV in 1950.

GOST definition edit

The USSR all-union committee of standards (GOST) had meanwhile adopted a significantly different definition of the roentgen in 1934. GOST standard 7623 defined it as "the physical dose of X-rays which produces charges each of one electrostatic unit in magnitude per cm3 of irradiated volume in air at 0 °C and normal atmospheric pressure when ionization is complete."[10] The distinction of physical dose from dose caused confusion, some of which may have led Cantrill and Parker report that the roentgen had become shorthand for 83 ergs per gram (0.0083 Gy) of tissue.[11] They named this derivative quantity the roentgen equivalent physical (rep) to distinguish it from the ICR roentgen.

ICRP definition edit

The introduction of the roentgen measurement unit, which relied upon measuring the ionisation of air, replaced earlier less accurate practices that relied on timed exposure, film exposure, or fluorescence.[12] This led the way to setting exposure limits, and the National Council on Radiation Protection and Measurements of the United States established the first formal dose limit in 1931 as 0.1 roentgen per day.[13] The International X-ray and Radium Protection Committee, now known as the International Commission on Radiological Protection (ICRP) soon followed with a limit of 0.2 roentgen per day in 1934.[14] In 1950, the ICRP reduced their recommended limit to 0.3 roentgen per week for whole-body exposure.

The International Commission on Radiation Units and Measurements (ICRU) took over the definition of the roentgen in 1950, defining it as "the quantity of X or γ-radiation such that the associated corpuscular emission per 0.001293 gram of air produces, in air, ions carrying 1 electrostatic unit of quantity of electricity of either sign."[15] The 3 MeV cap was no longer part of the definition, but the degraded usefulness of this unit at high beam energies was mentioned in the accompanying text. In the meantime, the new concept of roentgen equivalent man (rem) had been developed.

Starting in 1957, the ICRP began to publish their recommendations in terms of rem, and the roentgen fell into disuse. The medical imaging community still has a need for ionization measurements, but they gradually converted to using C/kg as legacy equipment was replaced.[16] The ICRU recommended redefining the roentgen to be exactly 2.58 × 10−4 C/kg in 1971.[17]

European Union edit

In 1971 the European Economic Community, in Directive 71/354/EEC, catalogued the units of measure that could be used "for ... public health ... purposes".[18] The directive included the curie, rad, rem, and roentgen as permissible units, but required that the use of the rad, rem and roentgen be reviewed before 31 December 1977. This document defined the roentgen as exactly 2.58 × 10−4 C/kg, as per the ICRU recommendation. Directive 80/181/EEC, published in December 1979, which replaced directive 71/354/EEC, explicitly catalogued the gray, becquerel, and sievert for this purpose and required that the curie, rad, rem and roentgen be phased out by 31 December 1985.[19]

NIST definition edit

Today the roentgen is rarely used, and the International Committee for Weights and Measures (CIPM) never accepted the use of the roentgen. From 1977 to 1998, the US NIST's translations of the SI brochure stated that the CIPM temporarily accepted the use of the roentgen (and other radiology units) with SI units since 1969.[20] However, the only related CIPM decision shown in the appendix are with regards to the curie in 1964. The NIST brochures defined the roentgen as 2.58 × 10−4 C/kg, to be employed with exposures of x or γ radiation, but did not state the medium to be ionized. The CIPM's current SI brochure excludes the roentgen from the tables of non-SI units accepted for use with the SI.[21] The US NIST clarified in 1998 that it was providing its own interpretations of the SI system, whereby it accepted the roentgen for use in the US with the SI, while recognizing that the CIPM did not.[22] By then, the limitation to x and γ radiation had been dropped. NIST recommends defining the roentgen in every document where this unit is used.[6] The continued use of the roentgen is strongly discouraged by the NIST.[23]

Development of replacement radiometric quantities edit

 
External modern radiation quantities used in radiological protection

Although a convenient quantity to measure with an air ion chamber, the roentgen had the disadvantage that it was not a direct measure of either the intensity of X-rays or their absorption, but rather was a measurement of the ionising effect of X-rays in a specific circumstance; which was dry air at 0 °C and 1 standard atmosphere of pressure.[24]

Because of this the roentgen had a variable relationship to the amount of energy absorbed dose per unit mass in the target material, as different materials have different absorption characteristics. As the science of radiation dosimetry developed, this was seen as a serious shortcoming.

In 1940, Louis Harold Gray, who had been studying the effect of neutron damage on human tissue, together with William Valentine Mayneord and the radiobiologist John Read, published a paper in which a unit of measure, dubbed the "gram roentgen" (symbol: gr) defined as "that amount of neutron radiation which produces an increment in energy in unit volume of tissue equal to the increment of energy produced in unit volume of water by one roentgen of radiation"[25] was proposed. This unit was found to be equivalent to 88 ergs in air. In 1953 the ICRU recommended the rad, equal to 100 erg/g, as the new unit of measure of absorbed radiation. The rad was expressed in coherent cgs units.[26]

In the late 1950s the General Conference on Weights and Measures (CGPM) invited the ICRU to join other scientific bodies to work with the International Committee for Weights and Measures (CIPM) in the development of a system of units that could be used consistently over many disciplines. This body, initially known as the "Commission for the System of Units", renamed in 1964 as the "Consultative Committee for Units" (CCU), was responsible for overseeing the development of the International System of Units (SI).[27] At the same time it was becoming increasingly obvious that the definition of the roentgen was unsound, and in 1962 it was redefined.[28] The CCU decided to define the SI unit of absorbed radiation in terms of energy per unit mass, which in MKS units was J/kg. This was confirmed in 1975 by the 15th CGPM, and the unit was named the "gray" in honour of Louis Harold Gray, who had died in 1965. The gray was equal to 100 rad. The definition of the roentgen had had the attraction of being relatively simple to define for photons in air, but the gray is independent of the primary ionizing radiation type, and can be used for both kerma and absorbed dose in a wide range of matter.[29]

When measuring absorbed dose in a human due to external exposure, the SI unit the gray, or the related non-SI rad are used. From these can be developed the dose equivalents to consider biological effects from differing radiation types and target materials. These are equivalent dose, and effective dose for which the SI unit sievert or the non-SI rem are used.

Radiation-related quantities edit

The following table shows radiation quantities in SI and non-SI units:

Ionizing radiation related quantities
Quantity Unit Symbol Derivation Year SI equivalent
Activity (A) becquerel Bq s−1 1974 SI unit
curie Ci 3.7 × 1010 s−1 1953 3.7×1010 Bq
rutherford Rd 106 s−1 1946 1,000,000 Bq
Exposure (X) coulomb per kilogram C/kg C⋅kg−1 of air 1974 SI unit
röntgen R esu / 0.001293 g of air 1928 2.58 × 10−4 C/kg
Absorbed dose (D) gray Gy J⋅kg−1 1974 SI unit
erg per gram erg/g erg⋅g−1 1950 1.0 × 10−4 Gy
rad rad 100 erg⋅g−1 1953 0.010 Gy
Equivalent dose (H) sievert Sv J⋅kg−1 × WR 1977 SI unit
röntgen equivalent man rem 100 erg⋅g−1 × WR 1971 0.010 Sv
Effective dose (E) sievert Sv J⋅kg−1 × WR × WT 1977 SI unit
röntgen equivalent man rem 100 erg⋅g−1 × WR × WT 1971 0.010 Sv

See also edit

References edit

  1. ^ Frame, Paul (2007-07-25). "Pocket Chambers and Pocket Dosimeters". Health physics historical instrument museum collection. Oak Ridge Associated Universities. Retrieved 2021-10-07.
  2. ^ "Röntgen". Random House Webster's Unabridged Dictionary.
  3. ^ a b . Archived from the original on 2015-02-22. Retrieved 10 May 2012.
  4. ^ Sprawls, Perry. "Radiation Quantities and Units". The Physical Principles of Medical Imaging, 2nd Ed. Retrieved 10 May 2012.
  5. ^ Guill, JH; Moteff, John (June 1960). "Dosimetry in Europe and the USSR". Third Pacific Area Meeting Papers — Materials in Nuclear Applications. Symposium on Radiation Effects and Dosimetry - Third Pacific Area Meeting American Society for Testing Materials, October 1959, San Francisco, 12–16 October 1959. American Society Technical Publication. Vol. 276. ASTM International. p. 64. LCCN 60014734. Retrieved 2012-05-15.
  6. ^ a b Hebner, Robert E. (1998-07-28). "Metric System of Measurement: Interpretation of the International System of Units for the United States" (PDF). Federal Register. 63 (144). US Office of the Federal Register: 40339. Retrieved 9 May 2012.
  7. ^ a b Van Loon, R.; and Van Tiggelen, R., Radiation Dosimetry in Medical Exposure: A Short Historical Overview 2007-10-24 at the Wayback Machine, 2004>
  8. ^ "Instruments de mesure à lecture directe pour les rayons x. Substitution de la méthode électrométrique aux autres méthodes de mesure en radiologie. Scleromètre et quantimètre". Archives d'électricité médicale. 16. Bordeaux: 692–699. 1908.
  9. ^ Guill, JH; Moteff, John (June 1960). Dosimetry in Europe and the USSR. Symposium on Radiation Effects and Dosimetry. Baltimore: ASTM International. p. 64. LCCN 60-14734. Retrieved 15 May 2012.
  10. ^ Ardashnikov, S. N.; Chetverikov, N. S. (1957). "The definition of the roentgen in the "Recommendations of the International Commission on Radiological Units. 1953"". Atomic Energy. 3 (9): 1027–1032. doi:10.1007/BF01515739. S2CID 95827816.
  11. ^ Cantrill MD, S.T.; Parker, H.M. (1945-01-05). The Tolerance Dose (Report). US Atomic Energy Commission, Argonne National Laboratory. from the original on April 7, 2021. Retrieved 14 May 2012.
  12. ^ Mutscheller, A. (1925). Physical standards of protection against Roentgen ray dangers, AJR. American Journal of Roentgenology, 13, 65–69.
  13. ^ Meinhold, Charles B. (April 1996). One Hundred Years of X Rays and Radioactivity – Radiation Protection: Then and Now (PDF). International Congress. Vienna, Austria: International Radiation Protection Association. Retrieved 14 May 2012.
  14. ^ Clarke, R.H.; J. Valentin (2009). "The History of ICRP and the Evolution of its Policies" (PDF). Annals of the ICRP. ICRP Publication 109. 39 (1): 75–110. doi:10.1016/j.icrp.2009.07.009. S2CID 71278114. Retrieved 12 May 2012.
  15. ^ Recommendations of the International Commission on Radiological Protection and of the International Commission on Radiological Units (PDF). National Bureau of Standards Handbook. Vol. 47. US Department of Commerce. 1950. Retrieved 14 November 2012.
  16. ^ Carlton, Richard R.; Adler, Arlene McKenna (1 January 2012). "Radiation Protection Concepts and Equipment". Principles of Radiographic Imaging: An Art and a Science (5th ed.). Cengage Learning. p. 145. ISBN 978-1-4390-5872-5. Retrieved 12 May 2012.
  17. ^ ICRU Report 19, 1971
  18. ^ "Council Directive 71/354/EEC: On the approximation of the laws of the Member States relating to units of measurement". The Council of the European Communities. 18 October 1971. Retrieved 19 May 2012.
  19. ^ The Council of the European Communities (1979-12-21). "Council Directive 80/181/EEC of 20 December 1979 on the approximation of the laws of the Member States relating to Unit of measurement and on the repeal of Directive 71/354/EEC". Retrieved 19 May 2012.
  20. ^ International Bureau of Weights and Measures (1977). United States National Bureau of Standards (ed.). The international system of units (SI). NBS Special Publication 330. Dept. of Commerce, National Bureau of Standards. p. 12. Retrieved 18 May 2012.
  21. ^ International Bureau of Weights and Measures (2006), The International System of Units (SI) (PDF) (8th ed.), ISBN 92-822-2213-6, (PDF) from the original on 2021-06-04, retrieved 2021-12-16
  22. ^ Lyons, John W. (1990-12-20). "Metric System of Measurement: Interpretation of the International System of Units for the United States". Federal Register. 55 (245). US Office of the Federal Register: 52242–52245.
  23. ^ Thompson, Ambler; Taylor, Barry N. (2008). Guide for the Use of the International System of Units (SI) (2008 ed.). Gaithersburg, MD: National Institute of Standards and Technology. p. 10. SP811. from the original on 16 May 2008. Retrieved 28 November 2012.
  24. ^ Lovell, S (1979). "4: Dosimetric quantities and units". An introduction to Radiation Dosimetry. Cambridge University Press. pp. 52–64. ISBN 0-521-22436-5. Retrieved 2012-05-15.
  25. ^ Gupta, S. V. (2009-11-19). "Louis Harold Gray". Units of Measurement: Past, Present and Future : International System of Units. Springer. p. 144. ISBN 978-3-642-00737-8. Retrieved 2012-05-14.
  26. ^ Guill, JH; Moteff, John (June 1960). "Dosimetry in Europe and the USSR". Third Pacific Area Meeting Papers — Materials in Nuclear Applications. Symposium on Radiation Effects and Dosimetry - Third Pacific Area Meeting American Society for Testing Materials, October 1959, San Francisco, 12–16 October 1959. American Society Technical Publication. 276. ASTM International. p. 64. LCCN 60014734. Retrieved 2012-05-15.
  27. ^ "CCU: Consultative Committee for Units". International Bureau of Weights and Measures (BIPM). Retrieved 2012-05-18.
  28. ^ Anderson, Pauline C; Pendleton, Alice E (2000). "14 Dental Radiography". The Dental Assistant (7th ed.). Delmar. p. 554. ISBN 0-7668-1113-1.
  29. ^ Lovell, S (1979). "3. The effects of ionizing radiation on matter in bulk". An introduction to Radiation Dosimetry. Cambridge University Press. pp. 43–51. ISBN 0-521-22436-5. Retrieved 2012-05-15.

External links edit

  • NIST: Units outside the SI
  • Radiation Dose Units – Health Physics Society

April 11, 2024
roentgen, unit, confused, with, roentgen, equivalent, roentgen, equivalent, physical, roentgen, röntgen, symbol, legacy, unit, measurement, exposure, rays, gamma, rays, defined, electric, charge, freed, such, radiation, specified, volume, divided, mass, that, . Not to be confused with roentgen equivalent man or roentgen equivalent physical The roentgen or rontgen ˈ r ɛ n t ɡ e n dʒ e n ˈ r ʌ n t 2 symbol R is a legacy unit of measurement for the exposure of X rays and gamma rays and is defined as the electric charge freed by such radiation in a specified volume of air divided by the mass of that air statcoulomb per kilogram In 1928 it was adopted as the first international measurement quantity for ionizing radiation to be defined for radiation protection as it was then the most easily replicated method of measuring air ionization by using ion chambers 3 It is named after the German physicist Wilhelm Rontgen who discovered X rays and was awarded the first Nobel Prize in Physics for the discovery RoentgenDisplay of quartz fiber dosimeter in units of roentgen 1 General informationUnit systemLegacy unitUnit ofExposure to ionizing radiationSymbolRNamed afterWilhelm RontgenConversions1 R in is equal to SI base units 2 58 10 4 A s kgHowever although this was a major step forward in standardising radiation measurement the roentgen has the disadvantage that it is only a measure of air ionisation and not a direct measure of radiation absorption in other materials such as different forms of human tissue For instance one roentgen deposits 0 00877 grays 0 877 rads of absorbed dose in dry air or 0 0096 Gy 0 96 rad in soft tissue 3 One roentgen of X rays may deposit anywhere from 0 01 to 0 04 Gy 1 0 to 4 0 rad in bone depending on the beam energy 4 As the science of radiation dosimetry developed it was realised that the ionising effect and hence tissue damage was linked to the energy absorbed not just radiation exposure Consequently new radiometric units for radiation protection were defined which took this into account In 1953 the International Commission on Radiation Units and Measurements ICRU recommended the rad equal to 100 erg g as the unit of measure of the new radiation quantity absorbed dose The rad was expressed in coherent cgs units 5 In 1975 the unit gray was named as the SI unit of absorbed dose One gray is equal to 1 J kg i e 100 rad Additionally a new quantity kerma was defined for air ionisation as the exposure for instrument calibration and from this the absorbed dose can be calculated using known coefficients for specific target materials Today for radiation protection the modern units absorbed dose for energy absorption and the equivalent dose sievert for stochastic effect are overwhelmingly used and the roentgen is rarely used The International Committee for Weights and Measures CIPM has never accepted the use of the roentgen The roentgen has been redefined over the years It was last defined by the U S s National Institute of Standards and Technology NIST in 1998 as 2 58 10 4 C kg with a recommendation that the definition be given in every document where the roentgen is used 6 Contents 1 History 1 1 ICR definitions 1 2 GOST definition 1 3 ICRP definition 1 4 European Union 1 5 NIST definition 2 Development of replacement radiometric quantities 3 Radiation related quantities 4 See also 5 References 6 External linksHistory editThe roentgen has its roots in the Villard unit defined in 1908 by the American Roentgen Ray Society as the quantity of radiation which liberates by ionisation one esu of electricity per cm3 of air under normal conditions of temperature and pressure 7 8 Using 1 esu 3 33564 10 10 C and the air density of 1 293 kg m3 at 0 C and 101 kPa this converts to 2 58 10 4 C kg which is the modern value given by NIST 1 esu cm3 3 33564 10 10 C esu 1 000 000 cm3 m3 1 293 kg m3 2 58 10 4 C kgThis definition was used under different names e R and German unit of radiation for the next 20 years In the meantime the French Roentgen was given a different definition which amounted to 0 444 German R ICR definitions edit In 1928 the International Congress of Radiology ICR defined the roentgen as the quantity of X radiation which when the secondary electrons are fully utilised and the wall effect of the chamber is avoided produce in 1 cc of atmospheric air at 0 C and 76 cm of mercury pressure such a degree of conductivity that 1 esu of charge is measured at saturation current 7 The stated 1 cc of air would have a mass of 1 293 mg at the conditions given so in 1937 the ICR rewrote this definition in terms of this mass of air instead of volume temperature and pressure 9 The 1937 definition was also extended to gamma rays but later capped at 3 MeV in 1950 GOST definition edit The USSR all union committee of standards GOST had meanwhile adopted a significantly different definition of the roentgen in 1934 GOST standard 7623 defined it as the physical dose of X rays which produces charges each of one electrostatic unit in magnitude per cm3 of irradiated volume in air at 0 C and normal atmospheric pressure when ionization is complete 10 The distinction of physical dose from dose caused confusion some of which may have led Cantrill and Parker report that the roentgen had become shorthand for 83 ergs per gram 0 0083 Gy of tissue 11 They named this derivative quantity the roentgen equivalent physical rep to distinguish it from the ICR roentgen ICRP definition edit The introduction of the roentgen measurement unit which relied upon measuring the ionisation of air replaced earlier less accurate practices that relied on timed exposure film exposure or fluorescence 12 This led the way to setting exposure limits and the National Council on Radiation Protection and Measurements of the United States established the first formal dose limit in 1931 as 0 1 roentgen per day 13 The International X ray and Radium Protection Committee now known as the International Commission on Radiological Protection ICRP soon followed with a limit of 0 2 roentgen per day in 1934 14 In 1950 the ICRP reduced their recommended limit to 0 3 roentgen per week for whole body exposure The International Commission on Radiation Units and Measurements ICRU took over the definition of the roentgen in 1950 defining it as the quantity of X or g radiation such that the associated corpuscular emission per 0 001293 gram of air produces in air ions carrying 1 electrostatic unit of quantity of electricity of either sign 15 The 3 MeV cap was no longer part of the definition but the degraded usefulness of this unit at high beam energies was mentioned in the accompanying text In the meantime the new concept of roentgen equivalent man rem had been developed Starting in 1957 the ICRP began to publish their recommendations in terms of rem and the roentgen fell into disuse The medical imaging community still has a need for ionization measurements but they gradually converted to using C kg as legacy equipment was replaced 16 The ICRU recommended redefining the roentgen to be exactly 2 58 10 4 C kg in 1971 17 European Union edit In 1971 the European Economic Community in Directive 71 354 EEC catalogued the units of measure that could be used for public health purposes 18 The directive included the curie rad rem and roentgen as permissible units but required that the use of the rad rem and roentgen be reviewed before 31 December 1977 This document defined the roentgen as exactly 2 58 10 4 C kg as per the ICRU recommendation Directive 80 181 EEC published in December 1979 which replaced directive 71 354 EEC explicitly catalogued the gray becquerel and sievert for this purpose and required that the curie rad rem and roentgen be phased out by 31 December 1985 19 NIST definition edit Today the roentgen is rarely used and the International Committee for Weights and Measures CIPM never accepted the use of the roentgen From 1977 to 1998 the US NIST s translations of the SI brochure stated that the CIPM temporarily accepted the use of the roentgen and other radiology units with SI units since 1969 20 However the only related CIPM decision shown in the appendix are with regards to the curie in 1964 The NIST brochures defined the roentgen as 2 58 10 4 C kg to be employed with exposures of x or g radiation but did not state the medium to be ionized The CIPM s current SI brochure excludes the roentgen from the tables of non SI units accepted for use with the SI 21 The US NIST clarified in 1998 that it was providing its own interpretations of the SI system whereby it accepted the roentgen for use in the US with the SI while recognizing that the CIPM did not 22 By then the limitation to x and g radiation had been dropped NIST recommends defining the roentgen in every document where this unit is used 6 The continued use of the roentgen is strongly discouraged by the NIST 23 Development of replacement radiometric quantities edit nbsp External modern radiation quantities used in radiological protectionAlthough a convenient quantity to measure with an air ion chamber the roentgen had the disadvantage that it was not a direct measure of either the intensity of X rays or their absorption but rather was a measurement of the ionising effect of X rays in a specific circumstance which was dry air at 0 C and 1 standard atmosphere of pressure 24 Because of this the roentgen had a variable relationship to the amount of energy absorbed dose per unit mass in the target material as different materials have different absorption characteristics As the science of radiation dosimetry developed this was seen as a serious shortcoming In 1940 Louis Harold Gray who had been studying the effect of neutron damage on human tissue together with William Valentine Mayneord and the radiobiologist John Read published a paper in which a unit of measure dubbed the gram roentgen symbol gr defined as that amount of neutron radiation which produces an increment in energy in unit volume of tissue equal to the increment of energy produced in unit volume of water by one roentgen of radiation 25 was proposed This unit was found to be equivalent to 88 ergs in air In 1953 the ICRU recommended the rad equal to 100 erg g as the new unit of measure of absorbed radiation The rad was expressed in coherent cgs units 26 In the late 1950s the General Conference on Weights and Measures CGPM invited the ICRU to join other scientific bodies to work with the International Committee for Weights and Measures CIPM in the development of a system of units that could be used consistently over many disciplines This body initially known as the Commission for the System of Units renamed in 1964 as the Consultative Committee for Units CCU was responsible for overseeing the development of the International System of Units SI 27 At the same time it was becoming increasingly obvious that the definition of the roentgen was unsound and in 1962 it was redefined 28 The CCU decided to define the SI unit of absorbed radiation in terms of energy per unit mass which in MKS units was J kg This was confirmed in 1975 by the 15th CGPM and the unit was named the gray in honour of Louis Harold Gray who had died in 1965 The gray was equal to 100 rad The definition of the roentgen had had the attraction of being relatively simple to define for photons in air but the gray is independent of the primary ionizing radiation type and can be used for both kerma and absorbed dose in a wide range of matter 29 When measuring absorbed dose in a human due to external exposure the SI unit the gray or the related non SI rad are used From these can be developed the dose equivalents to consider biological effects from differing radiation types and target materials These are equivalent dose and effective dose for which the SI unit sievert or the non SI rem are used Radiation related quantities editThe following table shows radiation quantities in SI and non SI units Ionizing radiation related quantities viewtalkedit Quantity Unit Symbol Derivation Year SI equivalentActivity A becquerel Bq s 1 1974 SI unitcurie Ci 3 7 1010 s 1 1953 3 7 1010 Bqrutherford Rd 106 s 1 1946 1 000 000 BqExposure X coulomb per kilogram C kg C kg 1 of air 1974 SI unitrontgen R esu 0 001293 g of air 1928 2 58 10 4 C kgAbsorbed dose D gray Gy J kg 1 1974 SI uniterg per gram erg g erg g 1 1950 1 0 10 4 Gyrad rad 100 erg g 1 1953 0 010 GyEquivalent dose H sievert Sv J kg 1 WR 1977 SI unitrontgen equivalent man rem 100 erg g 1 WR 1971 0 010 SvEffective dose E sievert Sv J kg 1 WR WT 1977 SI unitrontgen equivalent man rem 100 erg g 1 WR WT 1971 0 010 SvSee also editGray unit SI unit of absorbed dose Orders of magnitude radiation Rad unit cgs unit of absorbed dose Roentgen equivalent man or rem a unit of radiation dose equivalent Sievert symbol Sv the SI derived unit of dose equivalent Wilhelm RontgenReferences edit Frame Paul 2007 07 25 Pocket Chambers and Pocket Dosimeters Health physics historical instrument museum collection Oak Ridge Associated Universities Retrieved 2021 10 07 Rontgen Random House Webster s Unabridged Dictionary a b Princeton Radiation Safety Guide Appendix E Roentgens RADs REMs and other Units Archived from the original on 2015 02 22 Retrieved 10 May 2012 Sprawls Perry Radiation Quantities and Units The Physical Principles of Medical Imaging 2nd Ed Retrieved 10 May 2012 Guill JH Moteff John June 1960 Dosimetry in Europe and the USSR Third Pacific Area Meeting Papers Materials in Nuclear Applications Symposium on Radiation Effects and Dosimetry Third Pacific Area Meeting American Society for Testing Materials October 1959 San Francisco 12 16 October 1959 American Society Technical Publication Vol 276 ASTM International p 64 LCCN 60014734 Retrieved 2012 05 15 a b Hebner Robert E 1998 07 28 Metric System of Measurement Interpretation of the International System of Units for the United States PDF Federal Register 63 144 US Office of the Federal Register 40339 Retrieved 9 May 2012 a b Van Loon R and Van Tiggelen R Radiation Dosimetry in Medical Exposure A Short Historical Overview Archived 2007 10 24 at the Wayback Machine 2004 gt Instruments de mesure a lecture directe pour les rayons x Substitution de la methode electrometrique aux autres methodes de mesure en radiologie Sclerometre et quantimetre Archives d electricite medicale 16 Bordeaux 692 699 1908 Guill JH Moteff John June 1960 Dosimetry in Europe and the USSR Symposium on Radiation Effects and Dosimetry Baltimore ASTM International p 64 LCCN 60 14734 Retrieved 15 May 2012 Ardashnikov S N Chetverikov N S 1957 The definition of the roentgen in the Recommendations of the International Commission on Radiological Units 1953 Atomic Energy 3 9 1027 1032 doi 10 1007 BF01515739 S2CID 95827816 Cantrill MD S T Parker H M 1945 01 05 The Tolerance Dose Report US Atomic Energy Commission Argonne National Laboratory Archived from the original on April 7 2021 Retrieved 14 May 2012 Mutscheller A 1925 Physical standards of protection against Roentgen ray dangers AJR American Journal of Roentgenology 13 65 69 Meinhold Charles B April 1996 One Hundred Years of X Rays and Radioactivity Radiation Protection Then and Now PDF International Congress Vienna Austria International Radiation Protection Association Retrieved 14 May 2012 Clarke R H J Valentin 2009 The History of ICRP and the Evolution of its Policies PDF Annals of the ICRP ICRP Publication 109 39 1 75 110 doi 10 1016 j icrp 2009 07 009 S2CID 71278114 Retrieved 12 May 2012 Recommendations of the International Commission on Radiological Protection and of the International Commission on Radiological Units PDF National Bureau of Standards Handbook Vol 47 US Department of Commerce 1950 Retrieved 14 November 2012 Carlton Richard R Adler Arlene McKenna 1 January 2012 Radiation Protection Concepts and Equipment Principles of Radiographic Imaging An Art and a Science 5th ed Cengage Learning p 145 ISBN 978 1 4390 5872 5 Retrieved 12 May 2012 ICRU Report 19 1971 Council Directive 71 354 EEC On the approximation of the laws of the Member States relating to units of measurement The Council of the European Communities 18 October 1971 Retrieved 19 May 2012 The Council of the European Communities 1979 12 21 Council Directive 80 181 EEC of 20 December 1979 on the approximation of the laws of the Member States relating to Unit of measurement and on the repeal of Directive 71 354 EEC Retrieved 19 May 2012 International Bureau of Weights and Measures 1977 United States National Bureau of Standards ed The international system of units SI NBS Special Publication 330 Dept of Commerce National Bureau of Standards p 12 Retrieved 18 May 2012 International Bureau of Weights and Measures 2006 The International System of Units SI PDF 8th ed ISBN 92 822 2213 6 archived PDF from the original on 2021 06 04 retrieved 2021 12 16 Lyons John W 1990 12 20 Metric System of Measurement Interpretation of the International System of Units for the United States Federal Register 55 245 US Office of the Federal Register 52242 52245 Thompson Ambler Taylor Barry N 2008 Guide for the Use of the International System of Units SI 2008 ed Gaithersburg MD National Institute of Standards and Technology p 10 SP811 Archived from the original on 16 May 2008 Retrieved 28 November 2012 Lovell S 1979 4 Dosimetric quantities and units An introduction to Radiation Dosimetry Cambridge University Press pp 52 64 ISBN 0 521 22436 5 Retrieved 2012 05 15 Gupta S V 2009 11 19 Louis Harold Gray Units of Measurement Past Present and Future International System of Units Springer p 144 ISBN 978 3 642 00737 8 Retrieved 2012 05 14 Guill JH Moteff John June 1960 Dosimetry in Europe and the USSR Third Pacific Area Meeting Papers Materials in Nuclear Applications Symposium on Radiation Effects and Dosimetry Third Pacific Area Meeting American Society for Testing Materials October 1959 San Francisco 12 16 October 1959 American Society Technical Publication 276 ASTM International p 64 LCCN 60014734 Retrieved 2012 05 15 CCU Consultative Committee for Units International Bureau of Weights and Measures BIPM Retrieved 2012 05 18 Anderson Pauline C Pendleton Alice E 2000 14 Dental Radiography The Dental Assistant 7th ed Delmar p 554 ISBN 0 7668 1113 1 Lovell S 1979 3 The effects of ionizing radiation on matter in bulk An introduction to Radiation Dosimetry Cambridge University Press pp 43 51 ISBN 0 521 22436 5 Retrieved 2012 05 15 External links editNIST Units outside the SI Radiation Dose Units Health Physics Society Retrieved from https en wikipedia org w index php title Roentgen unit amp oldid 1182216378, wikipedia, wiki, book, books, library,

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