Radiation protection dosimetry in radiation fields behind the shielding of high-energy accelerators such as CERN is a challenging task and the quantitative understanding of the detector response used for dosimetry is essential. Measurements with ionisation chambers are a standard method to determine absorbed dose (in the detector material). For applications in mixed radiation fields, ionisation chambers are often also calibrated in terms of ambient dose equivalent at conventional reference radiation fields. The response of a given ionisation chamber to the various particle types of a complex high-energy radiation field in terms of ambient dose equivalent depends of course on the materials used for the construction and the chamber gas used. This paper will present results of computational studies simulating the exposure of high-pressure ionisation chambers filled with different types of gases to the radiation field at CERN's CERN-EU high-energy reference field facility. At this facility complex high-energy radiation fields, similar to those produced by cosmic rays at flight altitudes, are produced. The particle fluence and spectra calculated with FLUKA Monte Carlo simulations have been benchmarked in several measurements. The results can be used to optimise the response of ionisation chambers for the measurement of ambient dose equivalent in high-energy mixed radiation field

Forkel-Wirth, D.

Fuerstner, M.

Mayer, S.

Roesler, S.

Theis, C.

Vincke, H.

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THE INFLUENCE OF THE TYPE OF FILLING GAS ON THERESPONSE OF IONISATION CHAMBERS TOA MIXEDHIGH-ENERGY RADIATION FIELDS. Mayer1,*, D. Forkel-Wirth2, M. Fuerstner2, S. Roesler2, C. Theis2 and H. Vincke21PSI, CH-5232 Villigen, Switzerland2CERN, CH-1211 Geneva 23, SwitzerlandRadiation protection dosimetry in radiation ﬁelds behind the shielding of high-energy accelerators such as CERN is a challengingtask and the quantitative understanding of the detector response used for dosimetry is essential. Measurements withionisation chambers are a standard method to determine absorbed dose (in the detector material). For applications in mixedradiation ﬁelds, ionisation chambers are often also calibrated in terms of ambient dose equivalent at conventional referenceradiation ﬁelds. The response of a given ionisation chamber to the various particle types of a complex high-energy radiationﬁeld in terms of ambient dose equivalent depends of course on the materials used for the construction and the chamber gasused. This paper will present results of computational studies simulating the exposure of high-pressure ionisation chambersﬁlled with different types of gases to the radiation ﬁeld at CERN’s CERN-EU high-energy reference ﬁeld facility. At thisfacility complex high-energy radiation ﬁelds, similar to those produced by cosmic rays at ﬂight altitudes, are produced. Theparticle ﬂuence and spectra calculated with FLUKA Monte Carlo simulations have been benchmarked in several measure-ments. The results can be used to optimise the response of ionisation chambers for the measurement of ambient dose equival-ent in high-energy mixed radiation ﬁelds.INTRODUCTIONSeveral radiation components (photons, neutrons,different types of charged particles), covering a widerange of energies, up to the GeV region, contributeto the total dose equivalent in the radiation ﬁeldbehind the shielding of high-energy accelerators suchas those at CERN. Radiation protection dosimetryin such complex radiation ﬁelds is therefore a chal-lenging task and a quantitative understanding of thedetector response used for dosimetry is required.Measurements with ionisation chambers are astandard method to determine absorbed dose (in thedetector material). For applications in mixedradiation ﬁelds, ionisation chambers are often alsocalibrated in terms of ambient dose equivalent incalibration ﬁelds realised by radioactive sources. Theresponse of a given ionisation chamber to thevarious particle types of a complex high-energy radi-ation ﬁeld in terms of ambient dose equivalentdepends of course on the materials used for theconstruction and the chamber’s gas ﬁlling.This paper compares the results of computationalstudies simulating the exposure of Centronics IG5high-pressure ionisation chambers ﬁlled withdifferent types of gases to the high-energy, mixedradiation ﬁeld at CERN’s CERN-EU high-energyreference ﬁeld (CERF) facility. First simulationstudies were restricted to the use of pure hydrogenand pure argon gas-ﬁllings. For the obtained resultsbenchmark measurements at CERF showed verygood agreement(1). Subsequent to these successfulinvestigations new simulations were carried out inorder to extend the studies to commercially availablechambers of the same type using other gas-ﬁllingssuch as pure nitrogen and a mixture of argon/nitro-gen gas (A17N3, 1.7 MPa Ar/ 0.3 MPa N2). Thesedifferent ﬁllings are superior compared to pureargon-ﬁllings in strongly pulsed ﬁelds where recom-bination effects are not negligible. This is becausethe collection efﬁciency of an ionisation chambercan be corrected for volume recombination effectsaccording to a model of Boag (2, 3), provided thatthe current is carried entirely by positive andnegative ions. That means that electrons attachthemselves to gas molecules and that no appreciablepart of the current is carried by free electrons. In agas such as argon, where electron attachment doesnot occur, the correction by Boag is not valid. Thislimitation of argon could be observed in a measure-ment campaign in strongly pulsed ﬁelds reported inthe work of Forkel-Wirth et al.(4).RESPONSE STUDIES OF IONISATIONCHAMBERS IN MIXED RADIATION FIELDSResponse to various particle typesThe responses of Centronics IG5 ionisationchambers with an active volume of 5.2 dm3 and aﬁlling-pressure of 2 MPa were simulated, using fourdifferent gas-ﬁllings: hydrogen (H20), argon (A20),nitrogen (N20) and a mixture of argon/nitrogen*Corresponding author: sabine.mayer@psi.ch# The Author 2007. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oxfordjournals.orgRadiation Protection Dosimetry (2007), Vol. 126, No. 1–4, pp. 294–298 doi:10.1093/rpd/ncm061Advance Access publication 16 June 2007(A17N3). For all calculations the radiation transportcode FLUKA (H20, A20: FLUKA version 2002;N20, A17N3: FLUKAversion 2003)(5, 6) was used.The primary quantity calculated by FLUKA isenergy deposition, which was recorded for the activevolume of the chamber. Dividing the energy depo-sition by the mean energy which is required toproduce an ion pair (W-value), yields the createdcharge in the chamber. The W-value is deﬁned andextensively discussed in the ICRU report 31(7). It isdependent on the gas type, the type of radiation andits energy. However, it was shown that the energydependence is weak and, thus, can be approximatedin most cases by a constant value for the respectivegas type and for speciﬁc particle types. TheW-values adopted in this study are listed in Table 1.Empirically determined values could be found forpure gas-ﬁllings in ICRU-report 31(7), whereas forthe A17N3-ﬁlling the case of a binary gas mixturewas assumed.According to the ICRU-report 31 for a largenumber of binary gas mixtures the W-value, denotedby Wij with the gas components i and j, is given by1Wij¼ 1Wi 1Wj  Zij þ 1Wj ð1ÞwhereZij ¼ PiPi þ aijPj ð2ÞWi, Wj . . . W-values for the pure components!WAr¼26.4 eV, WN¼34.8 eVPi, Pj . . . partial pressures of the two components!Pi¼1.7 MPa, Pj¼0.3 MPaaij . . . empirical constant, following the suggestionof ICRU-report 31(7) it can be assumed as the ratioaij¼Sj/SiSi, Sj . . . stopping powerDue to the fact that the ratio of the stopping powersSN/SAr that were taken from Berger et al.(8), isa function of energy, one obtains a W-functionrather than a constant. However, evaluating thefunction in the range from 1 keV up to 1 GeV showsonly weak energy dependence. Since the standarddeviation from the average value of 28.0 eV wasfound to be only 0.5% the W-function is approxi-mated by a constant value of WA17N3 ¼ 28.0 eV.The simulations which assume a parallel beam ofmono-energetic particles of a certain type focusedon the major radiation components encountered inmixed radiation ﬁelds such as neutrons, photons,electrons, protons, pions and muons. Further com-ponents of the mixed radiation ﬁeld were neglectedbecause of their minor contribution to the totaldose. In the case of photons the measurements thatwere performed using X-ray sources were simulatedby sampling the respective energy spectra fromstandardized distributions(9).In the present paper the responses of the ionis-ation chambers are shown exemplarily for neutronsand photons. In Figure 1 the photon response interms of created charge per energy released in unitmass of air is presented for the different gas-ﬁllingsof the IG5 chamber. The applied ﬂuence to airkerma conversion factors were taken from ICRP74(10). For pure argon- and hydrogen-ﬁlled chambersmeasurement results(11) were available and areincluded in the ﬁgure. The respective statisticaluncertainties of the calculations are so small that theerror bars are smaller than the data point symbols inall subsequent ﬁgures.Moreover, in Figure 2 the respective responseto photons expressed in terms of created chargeper unit ambient dose equivalent is illustrated.The values were obtained by the application ofTable 1. W-values used in this study as given in ICRU-report 31(7).W–value (eV)Argon A17N3 Nitrogen HydrogenPhotons 26.4 28.0 34.8 36.5Neutrons 26.6 28.0 34.8 36.6Protons 26.6 28.0 36.7 36.6Pions,Electrons,Muons26.6 28.0 34.8 36.6Figure 1. Photon response in terms of created charge perenergy released in unit mass of air presented for thedifferent gas-ﬁllings of the IG5 chamber. Fluence to airkerma conversion factors are taken from ICRP74(10). Inaddition, experimental results obtained by exposing thechamber to various calibration sources are shown.INFLUENCE OF FILLING GAS ON RESPONSE295ﬂuence-to-ambient dose equivalent conversionfactors according to Pellicioni(12). Similar to the cal-culations for photons the response functions forneutrons in terms of charge per unit ambient doseequivalent were obtained. The calculations werecarried out for neutrons within an energy rangefrom thermal energies up to 5 GeV. In the case ofneutrons elastic and inelastic reactions below19.6 MeV are simulated by FLUKA using tabulatedcross-sections. Consequently, the binning in theresponse function is corresponding to this energyrange. The calculated results for the respective gasﬁllings are shown in Figure 3. Note that the responseof the A17N3 gas-ﬁlling does not always lie betweenthe response of pure argon and pure nitrogen gas-ﬁllings. This can be explained by the fact that theW-value is assumed to be different for the variousgases and it appears as a scaling factor on the calcu-lated results. Additionally, it is mentioned in ICRU-report 31(7), that a very small amount added tonoble gases can change the ionisation characteristicsconsiderably. One should, therefore, still examine thebehaviour of the chambers experimentally.Response to mixed radiation ﬁeldsThe response of the chambers was then investigatedin a typical high-energy ﬁeld such as the CERN-EUhigh-energy reference ﬁeld (CERF)(13) facility. Thefacility offers various reference positions behind80 cm thick concrete shielding that are well charac-terised with FLUKA simulations(14). In Figure 4 thetypical ﬂuence spectra simulated for different par-ticle types at a reference position behind the concreteshield are given as an example.As can be seen in the ﬁgure, the ﬁeld is com-posed mainly of neutrons and photons rangingfrom thermal energies up to GeV. Thus, theambient dose equivalent is strongly dominated byneutrons (85% of the dose equivalent), the rest isdue to photons.Folding the results of the chamber response withthe appropriate particle ﬂuence spectra at CERFyielded the created charge within the active volumeof the detector per primary particle. Figure 5 illus-trates the relative contribution of each particle typeto the total charge per primary particle for the refer-ence position CS2. The contribution of kaons wasneglected in the ﬁgure because of their minor contri-bution to the total charge.Figure 2. Photon response functions of the IG5 chamberfor different gas-ﬁllings expressed in terms of createdcharge per unit ambient dose equivalent. Fluence toambient dose equivalent conversion factors are taken fromPelliccioni(12).Figure 3. Neutron response functions of the IG5 chamberfor different gas-ﬁllings. The response is expressed increated charge per unit ambient dose equivalent. Fluenceto ambient dose equivalent conversion factors are takenfrom Pelliccioni (12).Figure 4. Particle ﬂuence spectra calculated with FLUKAbehind the concrete shielding at position CS2 at CERF (14).S. MAYER ETAL.296The simulations show that in the CERF referenceﬁeld, the total created charge per primary particleof the argon- or nitrogen-ﬁlled chamber isapproximately ﬁve times higher than that of a hydro-gen-ﬁlled chamber. This would indicate that in aCERF-like ﬁeld the argon- or nitrogen-ﬁlledchamber would be the preferred instrument regard-ing response in terms of total created charge.However, the major contribution to the expectedambient dose equivalent outside the shielding orig-inates from neutrons as neutrons have the highestradiation quality factor. Therefore, it is crucial toknow the response of the detectors to neutrons to beable to choose the one which measures the corre-sponding dose contribution best. One can see fromFigure 5 that the hydrogen chamber is the one withthe highest relative sensitivity to neutrons regardingtotal charge.CONCLUSIONThe inﬂuence of the type of ﬁlling gas on theresponse of ionisation chambers was simulated fora typical high-energy radiation ﬁeld using theparameters of the CERF ﬁeld. For two of the ﬁllinggases former measurement campaigns validated thesimulations. These FLUKA simulations were thenextended to other commercially available ﬁllinggases such as nitrogen and a mixture of argon andnitrogen. The simulations showed that the responseto the various particle types is very similar betweenthe argon-ﬁlled and nitrogen-ﬁlled chamber.However, the advantage of nitrogen-ﬁlled IG5chambers is that they allow for a correction ofrecombination effects which is not possible forargon-ﬁlled chambers. The detailed exploration ofthe different responses to the various particle typespermits a qualiﬁed choice for the future use of theinvestigated chambers.REFERENCES1. Theis, C., Rettig, M., Roesler, S. and Vincke, H.Simulation and experimental veriﬁcation of the responsefunctions of Centronic high-pressure ionisation chambers.Technical Note, CERN-SC-2004-23-RP-TN (2004).2. Boag, J. W. Ionization measurements at very high inten-sities. Br. J. Radiol. 23, 601–611 (1950).3. International Commission on Radiation Units andMeasurements. Dosimetry of pulsed radiation. ICRUReport 34 (1982).4. Forkel-Wirth, D., Mayer, S., Menzel, H. G., Muller,A., Otto, T., Pangallo, M., Perrin, D., Rettig, M.,Roesler, S. and Scibile, L. et al. Performance require-ments for monitoring pulsed, mixed radiation ﬁeldsaround high energy accelerators, Proceedings of EPAC2004, Lucerne, P. 147 (2004).5. Fasso`, A., Ferrari, A., Ranft, J. and Sala, P. R.FLUKA: a multi-particle transport code. CERN yellowreport, INFN/TC_05/11, SLAC-R-773 (2005).6. Fasso`, A., Ferrari, A., Roesler, S., Sala, P. R.,Battistoni, G., Cerutti, F., Gadioli, E., Garzelli, M. V.,Ballarini, F. and Ottolenghi, A. et al. The physicsmodels of FLUKA: status and recent developments.Computing in high energy and nuclear physics 2003conference (CHEP2003), La Jolla, CA, USA, , March24–28, 2003, (paper MOMT005) Conf C0303241,arXiv:hep-ph/0306267 (2003).7. International commission on radiation units andmeasurements. Average energy required to produce anion pair. ICRU report 31, 7910 Woodmont Avenue,Washington, D. C. 20014, USA (1979).Figure 5. Relative contribution from each particle type to the total created charge for a mixed radiation ﬁeld encounteredat the reference position CS2 at CERF.INFLUENCE OF FILLING GAS ON RESPONSE2978. Berger, M. J., Coursey, J. S. and Zucker, M. A.Stopping-power and range tables for electrons, protons,and helium ions, physical reference data, NIST.Available on http://physics.nist.gov/PhysRefData/Star/Text/contents.html (2005).9. Ankerhold, U. Catalogue of X-ray spectra and theircharacteristic data ISO and DIN radiation qualities,therapy and diagnostic radiation qualities, unﬁlteredX-ray spectra. PTB Bericht PTB-Dos-34 (2000).10. International Commission for Radiological Protection.Conversion Coefﬁcients for Use in RadiologicalProtection, ICRP 74 (Oxford (UK): Pergamon Press)(1997).11. Hess, A. De´termination de la re´ponse de chambresd’ionisation pre´vues pour la surveillance du LHC.CERN/Haute Ecole Spe´cialise´e du Suisse Occidentale,(2002).12. Pelliccioni, M. Overview of ﬂuence-to-effective dose andﬂuence-to-ambient dose equivalent conversion coefﬁcientsfor high energy radiation calculated using the FLUKACode. Radiat. Prot. Dosim. 88, 279–297 (2000).13. Mitaroff, A. and Silari, M. The CERN-EU high-energyreference ﬁeld (CERF) facility for dosimetry at com-mercial ﬂight altitudes and in space. Radiat. Prot.Dosim. 102 (1), 7–22 (2002).14. Theis, C., Roesler, S. and Vincke, H. Comparison ofthe simulation and measurements of the responseof Centronic high-pressure ionisation chambers to themixed radiation ﬁeld of the CERF facility. TechnicalNote, CERN-SC-2004-24-RP-TN (2004).S. MAYER ETAL.298

The influence of the type of filling gas on the response of ionisation chambers to a mixed high-energy radiation field

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