charged particle therapy, ion range verification, prompt ...2.1 physical rationale for particle...
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Charged particle therapy, ion range verification, promptradiationMauro Testa
To cite this version:Mauro Testa. Charged particle therapy, ion range verification, prompt radiation. Physics [physics].Université Claude Bernard - Lyon I, 2010. English. tel-00556628
THESE DE L‘UNIVERSITE DE LYON
Délivrée par
L’UNIVERSITE CLAUDE BERNARD LYON 1
ECOLE DOCTORALE PHAST
DIPLOME DE DOCTORAT
Présentée à Lyon le 14 octobre 2010
par
Mauro TESTA
Physical measurements for ion range verification in charged particle therapy
Directeur de thèse : M. Chevallier
Jury : M. M. Chevallier Directeur de thèse M. R. Ferrand M. F. Haas Rapporteur
M. C. Lacasta M. J-M. Moreau Président du jury Mme K. Parodi M. C. Ray M. D. Schardt Rapporteur
ABCDE
I
Acknowledgements
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1
Contents 1 Overview ........................................... ......................................................... 3
1.1 Particle radiation therapy.................................................................................. 3 1.2 Prompt -camera for dose verification and ion range monitoring in particle therapy. ......................................................................................................................... 4 1.3 Outline of the thesis.......................................................................................... 6
2 Radiation therapy: introduction.................... ........................................... 7 2.1 Physical rationale for particle radiation therapy............................................... 8 2.2 Radiobiological rationale for particle radiation therapy................................. 10 2.3 Particle vs conventional radiation therapy: clinical results and cost analysis 12
2.3.1 Clinical results ........................................................................................ 13 2.3.2 Cost analysis ........................................................................................... 15
2.4 Current and future ion therapy centers ........................................................... 16 3 Radiation therapy with ion beams ................... ...................................... 18
3.1 The physics of interaction of ions with matter ............................................... 18 3.1.1 Inverse depth dose profile: stopping of ions in matter ........................... 18 3.1.2 Range scattering ..................................................................................... 20 3.1.3 Lateral scattering .................................................................................... 22 3.1.4 Ion fragmentation: models and fragments .............................................. 23
3.2 The physics of interaction of photons with matter ......................................... 26 3.2.1 Photoelectric effect, Compton scattering, Pair production..................... 26
3.3 The physics of interaction of neutrons with matter ........................................ 30 4 Current and proposed methods for dose verification and monitoring in particle therapy ................................ .......................................................... 32
4.1 PET and TOF-PET ......................................................................................... 32 4.1.1 Ion range verification with PET ............................................................. 36
4.2 Prompt photon radiation ................................................................................. 37 4.2.1 Collimated Prompt Gamma Camera....................................................... 41 4.2.1 Compton Camera.................................................................................... 43
4.3 Interaction Vertex Imaging (IVI) ................................................................... 45 5 Physical measurements of the prompt radiation origi nated from ion fragmentation ...................................... ........................................................... 48
5.1 Properties of scintillation detectors ................................................................ 48 5.1.1 Characteristics of BaF2 – NaI(Tl) – LYSO – BC501 scintillators ......... 50 5.1.2 Pulse shape discrimination (PSD) for BaF2 and BC501 scintillators..... 54 5.1.2.1 PSD test measurements with a 241Am-Be source ................................... 54 5.1.2.2 PSD test measurements with 14 MeV neutrons ..................................... 58
5.2 Measurements of prompt -rays produced from C-ion fragmentation ........... 61 5.2.1 GANIL and GSI single-detector experimental set-up ............................ 61 5.2.1.1 Calculation of detection solid angle and field pf view ........................... 64 5.2.2 GANIL multi-detector experimental set-up ........................................... 66
5.3 Results and discussion.................................................................................... 68 5.3.1 GANIL and GSI single-detector experimental results ........................... 68 5.3.1.1 Time of flight (TOF) spectra analysis .................................................... 68 5.3.1.2 Time of flight (TOF) spectra conditioned by PSD................................. 73 5.3.1.3 Photon and neutron scan profiles............................................................ 77 5.3.1.4 TOF-spectra and prompt photon scan profiles comparisons between measurements and Geant4 Monte Carlo simulations ............................................. 82 5.3.2 GANIL multi-detector preliminary experimental results ....................... 84
2
5.3.2.1 Time of flight (TOF) spectra analysis .................................................... 84 5.3.2.2 Multi detector prompt photon scan profiles ........................................... 86
5.4 Conclusions and perspectives......................................................................... 88 6 Geant4 Monte Carlo simulations for the design of a multi-detector multi-collimator Prompt Gamma Camera............... ...................................... 92
6.1 Application of Monte Carlo simulation codes in medical physics................. 92 6.1.1 A short overview of the code architecture and physical models used in Geant4……………………………………………………………………………..93
6.2 Simulations of a simplified multi-collimated and multi-detector Prompt Gamma Camera .......................................................................................................... 94
6.2.1 Basic principles of collimator design ..................................................... 94 6.2.2 Description of the simulation set-up....................................................... 95 6.2.3 Basic description of collimator imaging properties................................ 99
6.3 Simulations results and discussion ............................................................... 101 6.3.1 Influence of the collimator design on the detection efficiency ............ 101 6.3.1.1 Influence of the collimator thickness and position on the visibility of the collimator slit-pattern ........................................................................................... 101 6.3.1.2 Influence of the collimator thickness and position on the detection efficiency ............................................................................................................. 104 6.3.1.3 Influence of the collimator tiles and slit dimension on the detection efficiency ............................................................................................................. 108 6.3.2 Influence of the collimator design on the spatial resolution................. 109 6.3.2.1 Influence of the collimator position on the spatial resolution .............. 111 6.3.2.2 Influence of the crystal detector width on the spatial resolution.......... 115 6.3.2.3 Influence of the detection statistics on the spatial resolution ............... 116 6.3.3 Conclusions and perspectives............................................................... 117
7 Summary and outlook................................ ........................................... 121 8 Appendix........................................... ..................................................... 124
8.1 NaI(Tl) calibration for beam intensity monitoring....................................... 124 8.2 Electronics and acquisition set-up ................................................................125
8.2.1 GANIL single-detector experiment...................................................... 125 8.2.2 GSI single-detector experiment ............................................................ 127 8.2.3 GANIL multi-detector experiment ....................................................... 127
Bibliography ....................................... .......................................................... 129
3
1 Overview
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1.2 Prompt -camera for dose verification and ion range monitoring in particle therapy
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2 Radiation therapy: introduction
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figure 2-1: Comparison of depth-dose profiles for carbon ions and photons from (Schardt et al. 2010). The inverse depth dose profile of carbon ions compared to photons is favorable to treat deep-seated tumours.
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figure 2-2: Superposition of several C-ions Bragg-curves with different energies (red lines) to produce a Spread-Off-Bragg-Peak SOBP (blue line) from (www.gsi.de/forschung/bio/).
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figure 2-3: Up: homogenous biological effective dose distribution (green line) and inhomogeneous physical dose distribution (blue line) obtain by superposition of different C-ion Bragg-peak curves. Down: C-ion RBE as function of the penetration depth in water. The flat biological effective dose distribution is obtained by multiplying the physical dose by the RBE; from (www.gsi.de/forschung/bio/).
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figure 2-4: Comparison of treatment plans for large tumour volumes in the base of the skull. Left: plan for carbon ions, two fields of irradiation. Right: plan for IMRT nine fields of irradiation. The irradiation with C-ions results in a substantial reduction of the integral dose to normal tissue and better spare of critical structures. Picture from (Durante & Loeffler 2009).
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Indication End point Results Photons
Results Ions NIRS
Results Ions GSI
Nasopharynx carcinoma
(advanced state) 5 year survival 40 - 50 % 63 %
Chordoma Local control rate 30 - 50 % 65 % 70 %
Chondrosarcoma Local control rate 33 % 88 % 89 %
Glioblastoma Average survival time 12 month 16 month
Choroid melanoma 5 year survival 95 % 96 %
preservation of eyesight
Paranasal sinuses Tumours Local control rate 21 % 63 %
Pancreatic carcinoma
Average survival time
6.5 month 7.8 month
Liver tumours 5 year survival 23 % 100 %
Salivary gland tumours Local control rate 24 - 28 % 61 % 77.5 %
Soft-tissue carcinoma 5 year survival 31 - 75 % 52 - 83 %
Table 2-1 Comparison of clinical results for conventional radiation therapy with photons and C-ion treatments performed at NIRS and GSI. C-ions are superior to photons for all the end points under consideration; from (www.gsi.de/forschung/bio/).
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15
0BA AABEED A EA E FBA BA EEACB CB @"F AB FABA B ABCDCBEA ABCD F FCABB (0 B AF BEA B DCAF CBEB EBAE A B BFBF AFAAF'EE*JBA>6AEAB,&.;AABAEAFFACBFBAFEFA AFCAEED @"F AA B EBAB AB CAF ADFECFFEDACBA B#AEE BEFC (0 CB ABCDEFDFAAE FFAFA A EE CAF CAE FCE BE BAEABD
2.3.2 Cost analysis A AA A F"AA B CBEA ABCD F FEE ;EA FAB F A AAB A FF AEABB AAEABD A1AF BA FA D EAB EE A *JBA >6AEAB,&. ABBAEABBAFAAAAFFCBEAABCDFFBA"CBEAEBAEDCABBABFBAEAED FFAFFA BAB *EEF"KAF A E ,%. ?AFAF ABBAFAABAAEF BFAE'AFE CBA AABA A BAEA C ABF F B F A BAAED ( BA ," CBA ABA FF B ABA ABBAAFBAF2ADFABACBBABCDBAFEEDBAACAFAAABAFABBAA=BAAABAEAFF ACAB BAEBED ACEDA AABCD BAAF4EB BAFEF A AA A B AA FD A F"AAAAFFBABCDBF'EEFAB*KF'AEAE,5.(FCBEBFAAEFFBABCDEBAACAFAF"EAFFFAAAFACABCDAAAB@"FABAFFEAAFBCAFFFCBABEBAEAFF FAABA FA AAF ( F AABAEAFF CFFEA AABE#A FEF EE B DCAF FA A AAA A F AAAAFF CBEA ABCD F FEE FBA ABABA A1A BABFAA FAAFFBDFCCBFADAFEDA1A*EEF"KAFAE,%.(FDFABAFAAAFEEFFBBACBEAABCD AAB *CCBAED $ EEF AB. EE ABAFA A BAED F BAFE A ABAF EBA ABE CAF 0BAABAFAFFAAAAFAEEACAFAFBABABCD ED =BA BBAFC $$ EEF AB CAB DAB *33 AFAFQDAB.ED53EEFABBAFCABBABCD*$CCAFQDAB.*AEAB.
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16
figure 2-5: Comparative average costs for different cancer treatments. Proton and carbon ion therapies are slightly more expensive than the average cost of cancer treatment in France but nevertheless cheaper than regularly employed chemotherapy treatments; adapted from (www.etoile.org).
2.4 Current and future ion therapy centers ABFCBCFEFCBFCAEEDAABFABCDBAB FCABB AC FA FB AF ' $&BC *2EF > ABF$&BC. AA EAB A BF CAF AF BAF ABF ABABAACBFBA$%B"FDBDEB6BAA?AB'AEAD6BBD 6?6 *I4. * F A E $&%. A A A $&F A BFAB BAAF 7BCA ABA CABBA CBF B AFDBDEB A <F2ABAB (FA ICCFE *4AA. *2 @ A E $&&3. EA A ABED $&CF A ABB @DEB 6BBD*I4. AA A BF EE"FA AAB FA CB B AB ABCD*4FABF ,. 6?6 B $&5 $&&, , CAF ABA BAAAA"FB$&5$&&,B3CAFABABEF@B4;AF*CACF. ($&&$A AFEEAFCBABCDEAF A BE A 6 6 IABFD0AE @AAB *[email protected] I4FA ABA $BCAFAAA BAA F FABA A BF FCE"FA AAB B CBEA ABCD ( AFADAB=BAA0ADDEBFFEEAA@ABAA6FFA ;A CBA C30A-CBF B EB B BAAEAAFADABEBFA)BFD,0A-CBFDB"DEBFABABAEFAEDAEFAA@ABAAEBPBCAD)BFD*@E).*2 @AE$&&3.0DAFBAABCDBAFEEFA EAB CDFF AEABB E'A A AAD (0AE AEABB*A(0@. @ *KC.ABA $&&B A BFCAF BAA@"FA<AFAEEFLB4ABABF*<4(.JBF*<ABD.ABF7BCACAFBAA@"F $&&5)AFA A
Comparative average cost for different cancer treat ments
2 500 € 6 400 €
24 000 € 25 000 €
30 000 €
40 000 €
50 000 €
0
10 000 €
20 000 €
30 000 €
40 000 €
50 000 €
Conventional RT
IMRT Average cost for cancer
treatment in France
One year chemotherapy
with Herceptin
Proton therapy
Carbon ion therapy
One year chemotherapy
with Nexavar
17
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18
3 Radiation therapy with ion beams
3.1 The physics of interaction of ions with matter
3.1.1 Inverse depth dose profile: stopping of ions in matter ABCDEF EA AB CB DDA ADEA AB EED DC F E FAAC CFEEF AE DC ACA AB D A C DB B ! D A " CDBA#EA$B%E%BABAAB$AED EA A# AD E%BEF F%%EE&E BA%FAAB B$AB A#%CADECB % BE$ BAED EDDB%%#FB%%%FAEFCCEC&A EDB E ACA EEDA 'D%% %E( A E A CA " E &BA %FAEFCCEC&AFB)&%%FAE)AE$%FE#E)#**%FAD%B '* +( '*%F +( ACA E DBE B AD%B )#',B+!(
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vm
vm
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3-1
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peff eZZ β 3-2
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figure 3-1: Electronic (full lines) and nuclear (dashed lines) energy-loss per unit path length dE/dx for ions of therapeutic interest in water. dE/dx values are calculated with SRIM code (Ziegler 2004).
B% A#% E B D %FAEF B DF%BA CCEC&AFB)EAF%#%E2C#EFB%EBBA#CE)# EE.EABEBE EBEB% ED,ABCBAB%%%)BE&EBCBAEF%%DFCEEBE%EFBB)A)ABAEB%&EBE#FB)FB%FD%B&EAD%BACAEDBE
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20
[ ] [ ]
××
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g
cmcmF
m
keV
dx
dEGyD
329 1
106.1ρµ
3-4
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,A B$# FBA E EAB% & E DBE 8 ACA B $A#F%BCCA1EBEBCA-FAB#BCBAEF%EFEBA $A# %E% FBA B AB$% B% E B ABE %E EDA && B FCBAE )& CA-F AB E &BA A E ABCDEFEAFB)BABE&EBCFEEFA#FB%&EB BFA$E '&A$ BD)ABE
BEFD)ACBAEF%(BAACABαCBAEF%&BCBE&BA&C%BBDFEEACFEEFA#
figure 3-2: Projected mean range for ions of therapeutic interest calculated in water with SRIM code (Ziegler 2004).
3.1.2 Range scattering 5 E FB ) E EDA ABE )& CCE C&A B *ABCB2 B B AE $AB% DAD FB AE BFA DA E E FE &E A#% $B%D &EF FB )FB%FD%B&EDBE)DEAB%E#BEEFB%%DFDBEA#
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21
% BAD E B$AB $B%D FFDA E %BA D)A F%%EE %&E& CAF E C E 2& B AB A A#AB%EB E E ACE)% A %BAA*ABCB2BDA AB E)B &E ACF FB%FD%BE )B B$AB A#% BE%CBAEF%BACAEEDAABAB%EEFAB&E CABE C E B E$BAEB% AD%E E *ABCB2 %BAA&E B B%%A E A EA EEEB% A# B E BACAEEDA8
A$AABAB%ECB%BCA-FE%CA *ABCB2 & E EDA E %BAA B FBA) *ABCB2B BAE B B C E &BA )FBD A EA E CFE ABAB%EBCCA1EB%#$BAEB E$A DBA A CBAEF%B'?FBAB%(BEEFB%%DFDBE$E%)EBA# EABFE )& EFE CBAEF% B %FA A ED BA BE ACE)% A AB AB%E B # BACACAEB%ABE)&%FABEB AABB CABE C B$EA E 1E)E B BAA&A *ABCB2 &E BCAEB%B%%E$B1BC%A%BE$ABAB%EEEDBDB)D@BABACAB%#@A E'ABAE ( F%EEFB% CABFEF &$A CAE% *ABCB2 E)ABABE%#DE#EEECABEDAE)DAE AB-FAE EE)B E. '?FBA B% ("DF%BAABBE B &E%% ) EFD E 1 CBABABC B% B BECAB E%DF *ABCB2 CAE% & CB2 ABF ABE)FABDB%%#B%%A&E EFABECBAEF%A#D EAEAABBE AB ,EB%%# E FB ) FF%D B F ABAB%EABC#BCC%EFBEEB%&B#B%%ABAFCBAB)%&E DB$EB)% D ECAE )B A BFF%ABA%E$A##'ABAE(A$A AFBE)B%E$A##DE%EF)#%EFEAABEBEBA$%DEFB)$B$BBD&EBAC*ABCB2ADFD)AA#C%BEEEEFB AA $AB%% EAABEBE E B B EA CBAEF% %DF CA%B#A'BC)A3:7AB+++(
ABCDEFA
22
figure 3-3: Comparison of measured Bragg curves of proton and C-ions having the same mean range. The measurements are performed in water with an ionization chamber and are normalized to the same peak height, from (Schardt et al. 2007)
3.1.3 Lateral scattering BACBAEF%CBE ADBED1CAEF%# EABFE&EBA%FA)DB%D%EC%%BEFF%%EE&EBADF%EBEEFB% ACEE D%EC% EABFE )& E B BADF%E AD% E B %BAB% CAB E )B F%# FB%% %BAB%FBAEBD%BAEAE)DEDFECBAEF%BABEF2B)A)A&EACFEFEEAFEFB)EACABAD%A $AB% E%# CA)B)% %FE )# B%% B% B E E &%%
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x
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dZ
pc
MeV10log
9
11
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&AFEDCBAEF% EF2B)A)AB%&' ABEBE % ED %%& B BD%BACAB EEFAB B CBAEF% A# FAB D F A B EBA DBE! EDA&CAB FCBAE %BAB%FBAEAEAECFEABCDEFEA*BFBA)BB$EAE&%E%%BAB%FBAE'E(&E%BD%BACABCA EB$AB A E %BAA B%% %BAB%%FEB$#E CABE AD B EF2 B)A)A E B CBAEFD%BA B$BB B$#E E FCBAE CA EF # B%%& B BA BCCABF EE$ADFDABBDAAECA$EEAE)DEEBABAB'?FBAB%(%BAB%)BFBAEEB%F%EEFB%A%$BFAAB DDA EF%$EFEE#ABBAE2'F5G( AEEE EAFEBCEE EAABEBECA %BAB%CABE)BAEEEDEBFB&EFBF5GFB)BCCABF
CAB
23
figure 3-4: Lateral scattering in water for ions of therapeutic interest calculated with SRIM code (Ziegler 2004). The small lateral deflection of carbon and heavier ions allow a closer approach to organs at risk (OAR) compared to proton beams.
3.1.4 Ion fragmentation: models and fragments 0EA#ECABEBEF2B)A)A%#EABF&EBADF%E('%FABEFEABFEBFAE)ECA$EDCBABABC)D # 1CAEF B &%% A DF%BA AF EABFE AD%E ECA-FE%BABADF%EABBEB%ABFEFAFEHGFAE)CA)B)E%E#ABEDAEDF%BAABBEBEEB%FB$AB&EA#AB&B)DD'71B% +ID( E EA# AEHG EBE%#E$)# AEFB%FA FE $A%BCCEDF%EF AB B %&AAE HGAE D FAE)DE A ABFEFBE %E2 CE%BEFF%%EEA DEABFE '?FBAB%(5$AB%DAD$E% CB%%BE ABFEB# AD% E FC% EEABE )CA-FE% B BA DF%E CA FB %# BA ABBE ECE)% ,A B2 FC% & E B DF%BA ABFEEDF)#%FABEFEABFEBAB%CE)%)DB%&B#%EE)%E A# AB E D E CBAEF% ABC# 5EEB%%# DF%EFABFE %BE CE CADFE BA B% CE)% B E EAE D E BAABC# )D #JA ABA D ) FC%%#EAA%$BACABFEFB%CDAC
0B$#E DF%BA ABFE B# ) F%BEE BFFAE $B%D ECBFCBABA)& AB-FAE &F%%EEDF%ECFBAAEEDEABEF%BKFAB%F%%EECAECAB%F%%EEB $BAED D%) AF EDF CAF B% B EB A )BAAEACAF' AC!(,AAEFB%ABCAECAB%F%%EE&A)BCBAEF%%A$AB%DF%BAADABFEB # FB)&%% FAE))# B)ABEB)%BE% B B & C
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24
CAF 'F%E$EAB B% +D+( EA C DF% BA B)AB E $A%BCCEABFE.'LEA)B%%M(CAABBACADF&EEN&E%DALCFBAMDF%BA%#%E%#BF'0OA+I8( B F C 'P ! ( 1FEBE A# E EA)B%% BAB E A%B )# $BCABE 'B)%BE( DF% EE CAC C A EB EC% ABF ':4G( BA B% CE)% E EF C )D # BA $AB% AA BED ABAA B 1FEBE AD DF% $BCABE 'Q/AAEB B% ( ABA& A# 1FE CADF B%% )%& DF% CBABEA%%#EECACRAB#EB%%&'%%BDA+!(
4EFB ABBE DE A BCC%EFBE E CBAEF% ABC# &ACAA$AB##BABS*S*A2%#AFBABFAEBE!DD)B"&EF&BDAAB'S%BFAB%++(?EE%BADE&ACAAB05 BFE%E# '?FB%% B% ++!(:5"S BFE%E#'*ABDB% (B??I #FAAB:? '?FBAB% ++!( A EBACFEABEFF%DEFB)AB&AFABBEA%$BABEABC#&EEA#E)B'?FBAB%(K
E "DF%BAABFEFBDB %CAEBA#)BCBAEF%BB)DE%DC %&AEC AB &EF )F A B A ECAB &EEFABE CABE C B F%BA%# CEF E EDA 8&E EFABE CABE C CB2 ABF ABE)F ABDB%%# B%%A BE%# )FBD EEEE %D1 CAEBA# E ,ABBE AB FB AE D@ A E B D B B$AB 8 @ CAEBA# E DE%E. E B #CEFB%DDAEAABEBEDADF%BAABBE'0BAB%!(5EEB%%#BB%AB#FAE)ECA$EDCBABABC*ABCB2 & E EDA 8 BA EFABE%# )AB )# A#AB%E
EE FBA# A EAAA CA-FE% %E2 AB $ &EB)DB$%FE#B CAEBA#E?EF#BA %EA BCAEBA#E#B$EAB%%AABBCADFBBE%)#*ABCB2F%BA%#$EE)%EEDA8
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CAB
25
figure 3-5: Measured Bragg-curves for C-ions of different energies stopping in water. The measurements are performed with an ionization chamber in water; from (Schardt et al. 2010).
AB% B$#E DF%BA ABBE BA ACE)% A AEABE EAE)DE) E %EDEB% B AB$AB%EE CFEB%%# E *ABCB2 AE "$A% A E ABBE E E%%&EE B BFFCB)% %EE CFEB%%#& DE BFE$)B %E$A# # B$E CA-FE% ABBE )A AE CBE'ABAE(,DAAACEAEEAB%E2 B FB ) DE%E. A ()C (* AB EAE &E CEA EEABC# 'A/( B E &E%% ) FAE) EA BE% E 1 FBCA BAABFBCEACBE'BE%#CAB0E(BAFDAA%# CAC A &'+,(C (),(* AB $AEEFBE&E EABFE$A1 EBE '( FED ' FBCA ( B &%% B CAC RAB#AEAB%%#)BEAFEB$)CA$)FAA%B&E CAEBA# ECB) ACA)B 'E B% !( B E)B'/BB%I(
,EB%%# DAE B CBAEF% EAABEBE B FEAB)% BD DA BACADF &E B $A# )AB BD%BA CFAD '/ B B% +( BB%D#FB)1C%EACAEBA#AB$AEEFBEEF#BADFAA%B&EECB'BB%(EFDEB$)ABE B)D A% DA A AE2 %B F BEDF FBA# FBFA 'ABBE B% !( /$ D E &BCE D B DA C )B %E$A# #':FB%2 !(&E FBCA )B B %EE)% DA ?$CAAB:#&BBDABA??&E.A%B'?FEAB%(BBE%%%EE)%I:#DACAAB:#&BEBA EEAABEBEB:?:AB#':D.ABA1B%I(
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26
3.2 The physics of interaction of photons with matter 5%DB%BAD)ACE)%ABFEFBEBA2&ARAB#E BA %# A B-A #C C%B# B ECAB A% E ABEBEBDAK C%FAEF B)ACE C FBAE B CBEACADFE '7%% +I+( 5%% CAF %B CBAEB% A FC%ABARAB#CA#%FAA#)B$EDACEBAEABBEFB%%#EAABFBACBAEF%FAE)ECA$ED CBABABC CBAEFD%BA CJ %BF2 FBA B2ECE)% B# E%BEF F%%EE&EBEF%FAFBABFAEEFABDB%%#%&&FBACBAEF%E2EABFE1C%BE&BEDB%EBE$ BDA RAB# B BA (BACABE EBAB FBA CBAEF% D DF B%%A FA FE ACAF E B)$ A%BE$ E%BEF %FA F%%EE FAFEB((BB)BCEABEA#BECBADB EF2 BA )D %# BDB E EE# )FBD C EAEBCCBAEA%#ABAFBAADBEEEFBB%D)B'S++(
3.2.1 Photoelectric effect, Compton scattering, Pai r production A BB E$%$ B)ACE B C )# B BEF%FA&ED)D-FE%FAABA#DE%FAEE$)#%%&E1CAE
be EhE −= ν 3-7
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
CAB
27
FE $BAE &E C A# BCCA1EB%# B ./B0 &E% CFBEFD)AUAB$AEDBAEBU B8C&A B EC%E B EAUBAEB%BA B$DA A C%FAEF B)ACE B%% FB $ A B$#%%E2DC%FAEFFFB)%FBAEAEA
figure 3-6: Total, photoelectric, Compton and pair production cross section for photons interacting with tungsten (left) and water (right). Data from XCOM photon cross section (Berger et al. 1998)
CDE FAE B% FB%% EFA FBAE E CAEBEABFEFBEARAB#AE$AB%E ECAB EABFE FBE E ED%E2 BAEB% E A#ABA2'0/ =3 DEB+I(B EFB)EEDA!&AEFB&BA CFAFE'A%E(ACAB-AFAE)DEB%CFAFE
figure 3-7: Kinematics of Compton scattering
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28
5CEF E EDA D C FBAEFFDA A %FA E BAFE%EABAABDF%DBAFDA%FABA)D)DECA#EE&EACF)EEA#E%BA FB ) EA B %FA FB ) FEA B EB%%# A5CC%#E A# B D FA$BE # A )# EFECB%FABA&FB)BE%%&EA%BEFAE)E DEA#BFBAEB% A) %FABCBE #)%E E 2F EDAD&)BE 'S++(K
( )θγνν
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h 3-8
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−+−=−= hhhT 3-9
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( )2
tan1cotθγφ += 3-11
&A 1./C BC E BA# %FA '8 ( AB% CFBAEFAFECD)A%FAB$BE%B)% E B)A)A B AA EFAB %EBA%# &E U &E% E
FAB &E EFAB E C A# 'BCCA1EB%# %E2 .ν( BFF%%EE A# E FBA B E ABAA B %FABFFAEDBEIB+A%BE$BDAECB%EEFBAC'DBE(BFB)AEDAIBA#CE%FB$ABABFEA#ABAAE2EEFA#%FAEFAB&EEFABEC A# B &%% B A F# A A&BA FBAE B E$B%DRAB#A#'7%%+I+(
figure 3-8: Differential Compton cross-section per unit angle for the number of photons scattered in the direction . Figure from (Davisson & R. D. Evans 1952)
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CAB
29
1BC%F$AEA#EBBE$%$ABABEBC EB%FACEACBEA ECAF%FAEFFBA EFABEF%FABCEAFBAA#CCEFBACBB A# B 1F E 1F A# E BA )& 2EEFA#%FABCEA*FBDCEA&E%%D)D%#BEE%B BA %&E & E B)A)E ED & BEE%BEC BA AB%%# CADF B FBA# CADF CBEA CADFEFAFE')%D%EEEDA!(EFABABCE%#&EEFABEA#B)$A%BEFEFFDAEE%DF%DFAFECADEBBA%EBA%#CB&EBEFD)A EABFE ED C%% B)$ A% CBEA FABE FAFEE%%EFAB&EA#%E2%'/(
,A B2 FC%&&E%%E B AACAF1EA C EABFE &E BAK FBAE GB#%E FBAEB AEC% CADFE EA FA FE BA B%&B# %EE)% &FCBAC%FAEFB)ACE CFBAEBCBEACADFEFBAEEFBAEC)#A%FAEF%BEFB%%EE&E%GB#%EFBAEB%FB%%FAFBAEEFBAE C )# B B B &% ) CAF FBAE EFBABFAE.)#BFBA#EABAAEDBBA EA 1FE A EE. B %# EAFE C E FB'S ++( AEC% CADFE E B CBEA CADFE 1FC B EABFEFFDAEE%%FAEBDF%DDAAEF CBAEF% BCCBAK CEA FAB %FA B AEEB%%FAAFE%EA%AAEC%CADFEB#)&FFDAB &EF A% A CBEA CADFE D '0 / = 3 DEB+I( 5CBEAFAFEFB%BDBAFBABACBAEF%&%%B)$A%B%CBEACADFEFAFEFB%BU'UV(ABBFBAUFABFFDAAEC%CADFE
,EB%%# & B E% C EABF &E BA B# A BEEABFE CAF 'C%FAEF B)ACE C FBAE B CBEACADFE(B#FFDAB#EABFE%#CAFFBB2C%BF)DEB#EABFEB%%B#FFDAA%BE$CA)B)E%E#BF#C EABFE E CACAEB% FA FE A B CAF CA)B)E%E# B EABFE E CACAEB% D FA FE1CA)# B% BDBE FA FE ')%BF2 %E E EDA !( BACAEDBE
pairComptonicphotoelctrtot κστµ ++= 3-12
FB%FD%B B% C FA FE A FCD DF B&BA B)ACE FEFE FB ) AE )# EC%# BE EE$EDB%FEFE A BE$%$BFFAE&EBF% EFCD
ABCDEFA
30
3.3 The physics of interaction of neutrons with matter "DA B$ FBA B AA FB DA %FABEFEABFE&E%FABDF%E AB$ABA&EFEBA#%FBEAFBACBAEF%BEACAEFECB%BEABFEEADAAF&EDF%EABFEBADFABAA E FCBAE )FBD A AB E AF "DA DF &EE N F DF%D )A B# EABFE CAF FBBCCBEFAB%BAEBE%#C#CBFDABA)A$ ) $A# CABE CBAEF% 'S ++( A%BE$ CA)B)E%EE $BAED#CDAEABFEFBABBEFB%%#&EDAA#BEDF%BACAFBDAB#DAFB)%EE%%&EK
E /%BEFFBAEADF%E5'(5KEECAEFECB%FBEA#%ADAEAEEABFEFBA#ABEBEEFED)#AFE%DF%E&EFB$CEF2DCFB)%BD A# A DA F%%EE 5 BF FBAE E DA%A#BEA)#ABA%&&%&AA# &E% E EAFE E FB EFE ABA E#A )FBD DA FB % DC B%% E A# E B E%F%%EE,AB$EADF%E%#BCBAEB%A#ABAECE)%B B1ED CE)% AFE% A# !#'" A B DF%D &E BEFD)A5 2F2 )# B DA&E A#!) E E$ )# DBE'7%%+I+(
( ) nR EA
AE
2max1
4
+= 3-13
/CFEB%%# B %& DA A# %BEF FBAE ) $A#CA)B)% B A$ )AE %& DA AB%DE%E)AED '8 B A CABDA(&E B)A)AED)ABEA#CABFEB2C%BF
EE %BEF FBAE5'J(5W5'J(*K E A# DA EDEFE%# E DF%D FB ) % E B 1FE B&EFB#%BA FB# )# RAB# A A A ABEBE$ EEEF%DE$BCABEBADA%BEEEFBDAD%EC%EFBEAAAE%BEFABFEFFDADADB$ DEFE A# 1FE DF%D DDB%%# AA A A ,EB%%# E A# BA &A FB B2 C%BF A$A#EDAAE'/X(
EEE GBEBE$ DA FBCDA V'U5(YRV'U5V(K E E ABFE BDA E FBCDA )# B B)A)E DF%D B A%B DA1F A# AD ABEBE$ EE AB% FA FEADAFBCDABCCA1EB%#B&AE$%FE# DA AA DA B)ACE E A CA)B)% B %&AE B CE % A B# B% ) ABCB2DCAECDCCF#
CAB
31
E$ FA DF%BA ABFE DF B 'C( '( '( 'Z( 'C( '('Z('EE(KE2EABFEBDAEFBCDA)#BB)A)EDF%DBFBACBAEF%BAE5AABEBE$FBCDA ABFE FA FE B%% B $ AA )FBD EFE DA A# E DDB%%# $A# %& B%% DF ABFE DB$BCEE$[$B%D'EAF)&EAB%A#ABFBBCADF()AEFB%%#CE)%'7%%+I+(
B%CA)B)E%E#ABDAEABFEBAEEB%%#E$)#DEE$EDB%FAFEBACAEDBE
captureradiativeinhelasticelastictot σσσσσ +++= 3-14
&AH%BEFHE%BEFHABEBE$BHFBCDAE FAFE A DADAEABFECAFFAE)B)$
ABACCDECFEFAEFFCACFCFDEAEACDAE
32
4 Current and proposed methods for dose verificatio n and monitoring in particle therapy
ABCDEAFCCA ACCAEC CACAFCABAFAAECCC CD CD CC ACB A BAC D CADDCAACDCCCFAC D A F A DCA CA A A A CD DCD ACDCE DC F C C C A FAD CABCA FACBCFABCCADABDCACAACCDCE C ACDCE D AC CAAA!""#CCCACBDCFABAC$% &'(&)FCCDDCDCFAACDCEC"*)CD"") DBCACACCFCACCEDABCFACCDC C C CA A ADA FCBDACABCA DACC +CBCCC,**- &CACEFCDADC..AACDCCEAFAAFACCFAC,*/DBAA "0/C DAA ACCDCAA ACB C )CA1 C "02" C AC CFDC'(&)AAA"*)CD"")ADEAFACBCACFC",)DACC,**3 'EACFCECCDDCD4CCB5DFF$%C
4.1 PET and TOF-PET $ABAC$% AACDFA CD AB CABDCA AC %BCAD C "00, ABAACDCAA"!6CD"")CAFADCAACCDDFACACDCEEC$%CDECA()CACCDAADCCCDCCECEECDCDF AC CB CD DEA C $CAD C ,**2 DFFACCCACD
7A 5C $% C AC8D C 9: CACD C 8D D CBDADCCC4A8DCDEADACD AC A CD $% C4 AFAD ;ACCCDFACA;C3*DCFACAACDCFAC%BCADC,**3
&AC FF5 $% C ED A CFA AACDCCAC$%CA A;ACDDFA;CCDABBA
EA
33
ACC(9' $CADC ,**2 CD CDD FA)5DEAFCC'(&)FCCBDCA:CADC,*"* 5CCACEADCDBFFA CC F AB DEDC FD AC BBFCCEAFAA5ED"!6A6FF5 F5AB BACCAACCECCCD CFFAACBB AFAC A 5C D CB DA CDACC CAC A5B C C F BCFAA5EDACDCABAFFCA CD AACDC CD CBB (AEA 5ACCBB D BAC C DEA C F ACBFACCFACFD$CADC,**2
ACDFFACCF$%CBBACDCACFBA35"7A)5AACDCACAF FBA35" CC<=5CE FADA;F ACBB5CCCDCD DAFAA"*)CD"")CECCACBCACA",)56ACAACAD5DAECD<=5CEAFCAFFBA35" AADCF A1 FACBC C C; F AACDCE FAD C D F ACA A ACB $CAD C,**, 7AAAADDCECFCABEC C FA F ACA CA C C F CABAAAB ADFCA AC/EA CFCAACEAFCDACCCA)5CCD;DABACDDCEA9 FAA $CAD C ,**, D C 3* BAAFACAD)5CADEACFFED9+ACF,*** CCCDACCF$%CBBCDCA AC <=CE DDFACBC>C,**495"5?FA",)CDC-**495"5?FAA%BCADC,**3 FC ECCA,5?ADAFCBDACACDCEACACEDEC$%CBB
ABACCDECFEFAEFFCACFCFDEAEACDAE
34
figure 4-1: Measured autoactivation of thick PMMA targets by means of 260 MeV/u carbon ions (top) and 140 MeV protons (bottom). The solid lines show the depth profiles of the measured + activity. For comparison the depth-dose profile of the primary beam is shown as dotted line. Figure from (Parodi 2004).
& 5C $% FA )5 C C D A FAABCC33*CACCDAD"00@C9:CD C AE C ECC FA 4C CAC :CAD C,*"* A CE AACD DA AAC CC CA F DEAD D ' AC A CED EC CAB CAD <=5CE DA C()CAAD CD AC C CD F A F AACDCCDDFBA35,CFAEDDACCADCD;D$%CBACD5BAEDDC4CCE C F DEC CD CD CCCD C D $CAD ,**3 FA ; AACDC FAC ACDAC C AFA ; C C A5AC) FA FAAEBC F CCC CB CD C F BFCDEC CD CD CD D C AC C C CACD CA8 $% AB 4 DED C 9:AD ABC;ACB EAFBFDCD DBDEC CBA C CBF CCCAFAC:CADC,*"*
EA
35
figure 4-2: Dose distribution (top) versus + activity distribution predicted from the treatment plan (middle) and measured (bottom) after a skull base tumour irradiation at GSI. The planned dose distribution is superimposed onto the CT image where the brain stem as organ at risk is highlighted. By comparison with the prediction it is shown that the C-ions stop before the brain stem. Adapted from (P. Crespo et al. 2006).
&;ACCDCD CF ADACDCADECB5CDDBAB CAFAD$)AC,**@ ADACFCFC5F5FB 67 $% CA CB ABCDEA DFABE 4CCEEAFCFCDD)5ACCACCFABC,** FD C CFC; 7D'( B A DFABE 675$% CB D CECC E DAB A F ACAACDC C D DAC DCC AB CDF67CDACFBCACADB E F AB AED (AEA 67 FACDCCDACADFCBCAFCCCAFAD5CB BAC /EA CB ABA DA CDAFDCAACDCAEDCCDED AA D C C EA &DDC A BC DD $% AC DCD A FACBCACBCDAB AACDCCD;ADD<=CEAACFAACBFAABCDEA$%CBB
ABACCDECFEFAEFFCACFCFDEAEACDAE
36
4.1.1 Ion range verification with PET AE CACBAC C D C ACB EAFC CFAC4CDDDFA$%AB(A DC C DEC AED CAD CDACCD$%CBCAACC9:CACD"002DCDCCFCACCAACBCFAB $CAD ,**3 DEC A D CCACFAACAE)'FDACDCA54ECC B (+AEAC,*** CC AFAEAAD %BCAD C ,*** )4 BA AC F AACBCD;DBACCAAC AACDC FD AC5CAC AC CC D A A FA F AC C CAAABCCA$CAD,**3
CCF$%CBFA,*!CACDC9:CACD,**?D A5AC ) A5;A FA - F $CAD ,**3 ! C EBC FAD C C CCC CB CD FA C C ACCCCACD7ACF1ECDC AC AA CF CAB CD CAF F CACCACCCCCEDDCAACDCFDCDAFA C AED C F ACB DEC A C4AAD$CAD,**3
(AA7DACAFADCFA4CCEDCACF5C$%DDACBDECCDCDCD AC C AEC C B C CD CDCCCD2"C ACDC9:CACD 7DAC,*"* 7A C C C ACB DFFA F F- CA C EACCDADCD$%CBCEECCAD;;ADECCA $% CBCCB ADCCEACDAACBCEAB8DECCAC 0*G F C /EA A AB ED C FFFDEFACBDECCCCBABBCABAACDCECCDC ;C FBA 35? CA AAD AF F AAD <=CE DA C C C DA AB A FD FE F $% CAC FBA 35?C AAD C C F C C EA CD A ACB $% CB CE AAAB8DFBA35?C1AFECCAFCDDB ACB DFFA & C CACD CD $% DACD CECCFABAACBEAFC
EA
37
figure 4-3: Profiles of reconstructed +-activity distribution taken in a beam direction crossing the isocenter field of view of the PET camera. The different activity distributions are drawn for range variations of ±6 energy steps (ES) corresponding to projected range variation in water of ±6 mm. The ±0 ES curve differs from the reference distribution only by statistical fluctuations during the simulation. The region where the range difference is expected is marked as an ellipse. In (a) it is shown a case of a patient in which the over and lower ranges have been correctly recognized while in (b) it is shown an example of patient in which the majority of the evaluators failed to detect the differences in ranges ; figure adapted from (Fiedler et al. 2010).
4.2 Prompt photon radiation $A H5AC FA ;D FACB ADD A DAB CFCCCAB"020 AFACAFAD/FAC"0@, CC;DFA EACA7A;CDAECCD C ACA F A H5AC FACA FCE AD C CC DA C F F CAC FD F CACFBCAD CA #C ,**" (AEA C EAC ACCA ABCC5ACCECCC $9&& DC5DAEDFADABACDCFC C C CA AACDCD CC F A CC C "002 F C CA F A CD A H5AC CACADB5AH5ACAA)AC,*** $9&&CDFCCABFH5ACDFA5CAB F C AEC AAC
DCFDABCCACADCC5EE ECE 4 DA AC A ACDA /A )CA AC /) ID C ,**" 4 CD CA F H5AC A D "*J @. CD "'H , AC C F A H5AC AACDAACAADAECCDCCCAFCADDDACAACACDDAB+CCC,***
ABACCDECFEFAEFFCACFCFDEAEACDAE
38
figure 4-4: Example of the time course of the coincidence rate acquired by the in-beam PET camera during the application of an entire treatment field to a patient at GSI. The rectangular pulses, better visible in the enlarged view on the right-hand side, indicate the beam extractions from the synchrotron. The coincidence rate during beam extraction is about one order of magnitude higher than during the beam pauses due to the high amount of prompt -rays emitted within the spill time course; figure from (Parodi et al. 2005).
DCFCABDCA ACCCACDDDCE 5ABFDDEAAAAFAD$%'AAH5AC AA E C C CACD C A FA C DC F B5ED <=5A BAC ECD BCDDABAC$CADC,**! DDCCA FBA353 DACC4AD ACACDAB C ;AC C ADA F CBD BA C DAB CC D B C F B H5AC A DDAB C ;AC DF AD FCDBC7AACC9:CACDCAFF FCDEADAAFC,DACFD?C$CADC,**! CAADDADACDCADFCDBCABADDABCA;AC%BCADC,**3 DAACDCADFBA353A1F5DCCC ABCD AD BC 3*GCDCAC;DFAAADDCD5AC D AC CD C DAC ACD ADEACAC$CADC,**!
EA
39
figure 4-5: Comparison of the depth-dose distribution at proton energies of 100, 150 and 200 MeV, measured by ionization chamber (IC) and right-angled prompt- -rays with the prompt gamma scanner (PGS). The correlation between the prompt gamma distribution and the Bragg-peak is within 1-2 mm for the first curves with proton energy of 100 MeV; figure from (Min et al. 2006).
(A AC AF ;ADACD C CAFAH5ACDDAAACDACBA(C,**- CD)5AC%CC,**2 &CF$% CDC CA FACBCFACACCDCABAACDCAACBDDFACBCACCCBC,5?FAACBB5CACAACACADABCECCABA15CAB A F C CAC ) CAAA C A CA F D A ACD FAACA CD DCA CA AC D AB ECCFACDDACDACBB5CCACEAFDAC(CCCACF"5,FAAC"**(#CAADFBA35!
;FA(C)5CCAFADABAC 9&/. FC )C7AC ,**@@?(#K "?)-= BBC$((&CABDCF;ACDFBDD;CACCACDCDCC FBA 35- AAC A CD ACBB5CCCDEFA)5CABCCDACADAB CA FACBC % C C ,**2 (AEA DACACDCBADACDCCDFFB67 AACCACAFA;AC5CDCEDFADBCFAAD ( C & DD ; CACBAC FCA F CACA AC A BFC AD 8 F DB CAC % C C ,**0 CB C CD 5DA5CACDCFAABCDEADACBAB
ABACCDECFEFAEFFCACFCFDEAEACDAE
40
figure 4-6: Upper part: detection rates as a function of the longitudinal position of target, obtained for two different time of flight (TOF) selections: prompt -rays (square symbols) and neutrons (round symbols). Bottom image: scaled photograph of the irradiated PMMA sample; figure from (E. Testa et al. 2008)
)B C AAC D C C FAH5ACCCDEAFCACCDFFCFDDEADABA AACDCC A ACD$F C C FAA CD ( )CA C AD A F CACADDCAAH5ACADDDAB A AACDC $F $A )CBCA C ,**0 C DAAFADCAFAH5ACACBCDADD A CD A C ) A $F $A()C,**0 &BDCCCFD CACA H5AC AC DDABA AACDC C ABAAC C FD DEAD ACD5 ACBB5C :6$ DDACDCACAFAC1ACCCAH5AC CA ACCABCD ACAC A FC ;AC A D :8 C CAC AACDCB C.CCD C CDCDDACAACBDABCC:8C,**0 DCAFCACAABCDDC FC F A BCC C C C F CACA8B ACACB5
EA
41
4.2.1 Collimated Prompt Gamma Camera
figure 4-7: Artistic scheme of the multi-collimated multi-detector prompt gamma camera. The hodoscope tags the ions in time and space coordinates. The collimator allows selecting only the photons emerging orthogonally to the beam. A series of stacked thin detectors are aligned to each collimator slit and provide snapshots of the longitudinal photon profile.
&CACDD * ACBEAFC$% CAFAD DAB C AC C C F CA C4A AC DCD A CC BC /EAACBFDCEFCAFECACDDEA7DAC,*"* CDC D CADFACCC;D1C,**! BDACCECCDACBDEC DAB C AC CD ABCDEA 7A CA A BA AD DE C DE CD CD ABCC CAC DD ;B D F A H5AC CAD CCCDCFACAFACBCABCDEA FAC C D DEAD CD ACBB5C A(AEACCACDD*AAC A BCC CD ACA C C DACDFAA(C,**- CD)5%CC,**2
(AFCFACCA5CCD4 ACBB5C AEDD CDD 5 C C B A ABBABC CDA C D FBA 35@ F 674 DAC A FA C CABCBAD ACDC C D A C C FAA DBCAD DA CA C C C A F DAC F CBD C AADB CA C CD CDDFBA35@:C5CCBCCDAEA A BDC ACBF DC F CC A CC CED 5CA CD 5DA 5 DD
ABACCDECFEFAEFFCACFCFDEAEACDAE
42
DCCA!CCACDCDCBDCAFFADCED
AB F CDAAC E A4A A DC ? D CABAC AFA BDC ACB C AFAC ACEA F C A4AD CD C AEDDCEDCDDFBA35@&BC CDAAEDDD 4 1ACCA ACE ACB FADA A C ACC C FA )5 A4A FAA AC ECC FA A CE CABA CACCAB&AC1A C F CD AED BCFA67CACF5DCDCFCFC5AA67CADDDC;CA/EACCCCFAA EC D FA CA AC C DDEDCCBFAC$CAFF"*2)5KCD "*"*AKCA CD AC $AC ,**2 CD C ;D CAD CB BCCBDCDFCBFA&CC,**2 A DCD 8 C ,**- D F D CAAA B DED A CACA CD CACA FA)%&5.:CC7ACAB8C,**"
.FACACBB4C1ADFFCC EA A BCC CAC CC F BB C C ACB AF CC A F ADAF A ; CADCD DAC C CCCCDDABCCAACDCACDDCCAC
EA
43
4.2.1 Compton Camera
figure 4-8: Artistic scheme of a TOF-Compton camera setup. The hodoscope tags the ions in time and space coordinates. The Compton camera constituted by 2 scatter detectors and 1 absorber detector detects the prompt -rays emitted subsequently to the nuclear fragmentation processes induced in the patient body; figure from (M.-H. Richard et al. 2010).
) CAC CADEAD A BA FA CD ABCDEA AAEABC ? ABF ACBB5CDABCCDAACAC&B 1FAC CACA AD C CDECCB F) CAC EA C CD BCC5CAC C AD * C ACD FF F CA ADA FCBD D AC F AFAC5B CABCACAC5ACBCACEABC,**0
ACDC ) CAC F CA DA CD CAA DA CD CA AA DA DEADD FACC C BCC CA A C ,**? CD DCCBB(AC,**, 4CDC5A7AC H5AC DAB C ) CAB FA CA DA CDD CAD CAD D CAA DA$AEDD A CA C CAD D DA A ADABFACAFDDAB CD AC DA AA CB D AC1AF BH5ACCC CAFAAADABC
7A CA AC CC A A BCC AB AC EA ACD CD A AB F EAC (# D DFF ECB C CA D DA B FACAFACFADCDABAC
ABACCDECFEFAEFFCACFCFDEAEACDAE
44
CADAC EBCD5CCBCDACCAAFDAFBH5AC(5'CADC,*"* FBAC F D AAD FBA 352 ABCF 5 A F CCD BA ) CAC D F C D C CACDDD * CD CBBB F CD CADC7ACECH5ACDABC)CABABCAADC ABCADA C CADA CDC AC CAA 4C35"35!CA
( )
−−=
01
21
111cos
EEcmeθ 4-1
( )
−−=
12
22
111cos
EEcmeθ 4-2
110 EEE +∆= 4-3
221 EEE +∆= 4-4
( ) ( ) ( )3221
3221
rrrr
rrrr
−⋅−−⋅−=2cosθ 4-5
CD CA CAB CB FA CD D CADACDCA ABECFA AC FACADA DCDCAAAECDCA AC EA A DA L CD L CA AB DD CA DA D F4C 35" 35! CCC EC F FE 4C CDFECAC4CLL CDC4C35"CD35,DCCAACDB D CDA F A CAAADCAAAAA
6 DAD AA C AC1AFDABCCCA BE A F AAD CD AC1AAEDDD/EAAADABCCCCFFDEACACCBEDCCAFDCACCABFCD AC F DCA CA DA :F AB DDECAAFACA CABAADH5AC(AEAAACBAEAFCFACCDDACCADAC5
EBCFFECACACACABCD A5DA DC CEC CC A CD
EA
45
DFFCACECDCAAABA(5'CAD,**0 CAFDCDEC()CACCAEDCBDFADBFC)CACCDABACCDAB5A A4A (5' CAD C ,*"* D CABFBACADABABFCFABCEAAB C AC /EA D BC D CD C C F :. DA DCC C ,**! CCAAF)CACAAABDEDACACACDDCECFFACDA ADA F CBD CAD D CAB CACADCE
4.3 Interaction Vertex Imaging (IVI)
figure 4-9: Artistic scheme of the interaction vertex imaging (IVI) system. The hodoscope tags the ions in time and space coordinates. In single-track vertexing, the vertex is reconstructed as the intersection of the particle trajectory and the beam direction provided by the hodoscope. In multi-track vertexing, the vertex is reconstructed by the intersection of 2 or more particle trajectories arising from the same fragmentation point.
& DADFCA FACDAACABCDACBEAFC CA CD DF CA A FAACCAACDDABCFACBC$% AFAA BCC D5;C F CA FACB CD CD )ABCCCAC &CACE 4CD DFABCABDCAABB FACCABACD CA AC B CD CAB AADAEBCCCACABACD%&FDC'A4,*"*
ABACCDECFEFAEFFCACFCFDEAEACDAE
46
4 CD AC EA; CBB # ACA EA; DFC A F;D CAB CA ;AF#FBA350CDCD AA F AC1A F ABBCA CA ;ACCDCAAD(Dauvergne et al. 2009)DDCFA$%CDABCCCBB4FFACBC CA ;D AACD ACB CD C FABBCABDCAD AAACD D CCDECCBF#CADCDADBCCCECDDFA;CCFADC"*MACDACCADC-;"*5!5"A5"FA",)C0!(#KACC,*"* CD!;"*535"A5"FA",)C,**(#K98A5(CA;C,**2 ECCAC ,5? ADA F CBD BA C N!;"*5@ A5H 5" A5"CAD ABC C DA ( C C ,*"* CDAFAC#CCCACE4
EA;AACDDFFA4CDCACABFACFACBCEA;FA C CD B5ACEA;B CA AC1A CD CA F F AC ;CD DA CD EA; AADC AF CDAAEDD D AFA C C E ABBCA A FACBC EA; O " C C AAD /EA AA 4 ACD ACA FACBC CB ACA C DAAEDDDAAAC FADD CC AF DCD CAC CABF ACA :D ABB CB F CA CFF FCAF CDCB FACADDCA CA CDCDCCAAADDDBACACAADEA;ACDACBCBACDFACAACCDCDA(AEAFACADDCACAC AB CD AFA E CAB AA CA C F D> C FD A CBCA CAC C CAB AEC CB CD CBCA ACBBB AFAC BA AB CA C FACADCB (AEACBCAFCADAC C ACD FF B C CD CC A F AAD EA; 7A C A ( )CA C CAAABAFAD'A4,*"*
&DCACFAEA;AACCD5ACEA;BCDAAFEFACFACBCEA; A A CA CA D P" AC C 4CDADCACCACEA; D DFD A F CA AC1A
EA
47
ACD CA FF AC ;CDDACFBA350D5ACEA;BCDAAEDDDACACBDCCFAACBACDD FA BDA CFCAFACBCACCDBCABACC A F ;A CA AA B AFAD A BA C 9&/.FC'A4,*"*
ABCDBABEFDAFDFEDAEDABEFFE
48
5 Physical measurements of the prompt radiation originated from ion fragmentation
ABCAD EFBBE F EDBD EABDE FB D EB C AD F AD FBEEB D BA D BECB F BCBD F EDBBECD D EB C F DDB BBE BD F FBADDCDBDFDEDEDEBDDFDBFEDBCDFADFBEEBD A ABCAD F DCD CE FB DA BCB FC FBEADBD !"#$%CEDB"#$BDDFEFD&CFBDBBD F EADB F A FD A F B DCDBECDFBCECDDBADBD
5.1 Properties of scintillation detectors #EDBD E F BE FB A ABB FD CE DDBBD ABBFF BEDBD FEFB BCADEDE 'BCADEDE EEC FD BD DEAD BBDBEEFBDBAAEC EDBDBED(BDED A F BDE BD F B FF D )FEDFDCDCDDADFBDBB FD F *FD EC BD BAD E CEF B BFAC FEDBDFDEBDEDDEEBCFEF EBD FD EDEB BDB ECD DABDEDEDDFDEDBBD)FABD&CADBEDBABBFB B B FF EDE EDD ED D CED BBD BDBDE D CED BBD B BBDAD FF FADDBEBBDEDDF F EB D D FAC B F EBEDBD !+% #EDB ABB B CCB EB B BDE BDDBDE
,BDEEDBBBABEFEBDEACDEDBDDDEDD DDD CEC )F A DCF BC B BEBAFBDBDEDBDFBABDC EFB BE ED D EDB F EDE BAABEDDABEBCFDBDFFEF F -./ FD01 D !# " 2..3% #EDBDF D F EACD B A BDD AB F BDEED F BDE AEC )F EB ED B DBEB F BD BECB BA D F AEC BD EEC FB BDD B 4AECB B 5EBC F AECB DBC CADEDE D F ABB BDE EDB EBD C D ABDFEB A FC D F EDBD E F
FBD
49
BCDACEBBDBACDAEACDD&CBDCD
DBDE EDB EBD ACBEB BB FB EB 6B!)% !)% 7B58!% F B BF AD 79#,!7C9#,:;% BEB DD BB ABB 5B<2 5=, (Van Eijk
2001))FBBDBDBDEEBBDEEDBDFBDCFFFDBDFFBAEDCAADBFEDBFBFBAFFFFCC!)B:-% FEFCDDCD)FABFACBEDBAABBBDDFBBFFBDBDB F AD B A CADC BD D EDBABB !> * >?A B 2..@% )F CADEDE E EECD DDBDEEDBBBEEDFAEBDFEFFADBBE;CEDE FAEDBDFFBD-.A BDFFEDE B F AD A B FBD -.A BD AABBBBBBFC!#"2..3%
Scintillator Density [g/cm 3] Decay time [ns]
Light yield [Nph/keV]
E/E(662 keV) (% FWHM)
NaI(Tl) 3.67 230 41 5.6
BaF2 4.89 0.7 fast
620 slow
2 fast
8.2 slow 10
LYSO (Lu1.8Y0.2SiO5:Ce)
7.1 41 33 7-9
LaBr3:Ce 5.3 35 61 2.9
BC501 0.87 3.2 14 -
Table 5-1: Comparison of scintillator properties. Values adapted from (P. Crespo et al. 2007).
DD FBFBDEBDDBDEEDB FBACDCEDE FA DEDB FD F DD BE D F D F EDB B EACDEDDDDC FBEBDEE DBDBADB B CD FB DB F BACD EDBD FCE BE F BA D EB FB BE )F AAEBA ECEFBFBB5!5-C:-%5DFBFFCCCDDF!%FEE D !A% BEED &CBD :- BCA FB FDDDB DA F BD D C &CDEFDDBEDD FEAECBD FBF DEDBE)F &CDEFD DBED BD D FB C F DCADEDE ABD FCF FDD BD FB CED #DE B FFDD CE B FF D E AEC A
ABCDBABEFDAFDFEDAEDABEFFE
50
&CDEFDBBEFBEBDFFFCED
dx
dEkB
dx
dEA
dx
dL
+=
1 5-1
D&CBD:- B FBCEDBDEDEBDCD BBBABD F DBD D A D BEE CD BD D5DACBFADBBBBDBCBBCCDEBDCDDFBCBCDEDFEDBABB BEBDD!7-CC/%
D)B:- FDCAEDBDFDEFAFDBD BACD DA B D B EDB D &CBD :2!7AEB-CC8%
SQE
ESQNN
gapheph β
== − 5-2
E D FDCA FABEDFBCE D FDBED E AF F BDB D D BDE BDEDCE BD BD B BBA FEF DEB F BB D&CCEDFABEDFB;AAF E28!1BDBF2..-%#FBD0BDEDEFFBCADEDEED !7%BDG F&CBDCAEDE F7 FEDE FDADDEB7E
5.1.1 Characteristics of BaF 2 – NaI(Tl) – LYSO – BC501 scintillators D F C E FB D C; 5B<2 6B!)% 79#, 5:.- )F ABD EFBBEE B D )B :- BD F EEADDBD)B:2 6B!)% 5B<2BD79#,!7C-A9.2#,:;%B EAAD A HE AB FF I AD F 5:.-J#BD=BD B B &C BDE EDB BECB C DCDED
Scintillator Dimensions
NaI(Tl) 2 inches Cylindrical Ø 5 cm thickness: 5 cm
NaI(Tl) 3 inches Cylindrical Ø 7.5 cm thickness: 7.5 cm
BaF2 Hexagonal Ø 9 cm thickness: 14 cm
BC501 ®Saint-Gobain Crystal Cylindrical Ø 5 cm thickness: 15 cm
LYSO pixel 4x48x22 mm
LYSO medium 3x50x40 mm
LYSO large 5x50x40 mm
Table 5-2: Dimensions of the detectors used in this work for and neutron measurements.
D C :- B F EBBD D EB F C EEBBDF -83BD @.BBECE6B!)%FB
FBD
51
FDCDBDFCFBFBABACA!<*K%F@@21HBAF-83CEDEABADFFBCFEFEBDCDDFBCBDFBBD)B:-BD EABBCBC)B:- BFDCDCD F 5B<2 E F C 79#, E D DCD)FABDCFACAFEDBBDBDDAB ECD F FAC C !")% < B ED EBD ADD FB <*K -:L B @@2 1 EBD CD FD F 79#,E EBB F -83 BD BD F D AD [email protected]@@21HB)FBAEAD BDE 6B!)%BD5B<2F FABF FFD AF CE CD B BD C F EDB CA BB ADD 5:.- B &C D I BDE EDBDD DCD ED BD F EDE HED DBBFD D C:-FADDCECBFFBD FEE BD B B F -83 BD @.CE
figure 5-1: Calibration energy spectra for NaI(Tl) 3 inches, BaF2, LYSO medium and BC501 detectors with 137Cs and 60Co radioactive sources at the same time.
,D F ABD EFBBEE F 5B<2 BD 79#, EDB FDDB BBE E C 22@'B BD -3@7C ACDD 5B<2 F 22@'B BBE DBD EFBD !*FB M>?-CA/% BD FEFBBEE D F CN
ABCDBABEFDAFDFEDAEDABEFFE
52
DBDBEBDFDEBDFBC:8
PbPoRnRa MeVMeVMeV 21411.6:21859.5:22287.4:226 → → → ααα
PbPoBiPb MeV 21083.7:214214214 →→→−− αββ
79#,BCCABEDBFEFEDBDFBBE-3@7CFEFBDBCBEECDBA-3@7CBEBD-3@KCC@@LFAF:C31EB!<DB-CC@%)FBEBFB8HBEBEB8.31 2.21BDAA1BEDC:2
figure 5-2: Decay scheme of 176Lu from (Firestone et al. 1996).
)CEC EDDEF:C31EBBDF2C.1B!2.2OAA1%EBDDDFBECDDECADFFBC:8
figure 5-3: Background spectra due to the internal radioactivity of BaF2 and LYSO scintillators. For the BaF2
detector the 226Ra measured activity is about 350 Bq. For LYSO, 176Lu measured activity is about 40 Bq/g.
)F ED EDE 5B<2 BD 5:.- EDB FB D ACBF=BD/DBE!DB2..8%ADDEDE
FBD
53
BAFDBDDC:/ABEDF ACBD E D D F D EFB )F E A BEECBCE FEDBFBBDADDBBEFDEBAED:P-./FDBBDFEBBDFD F ED F D F EDB E F FDEDEDEFF5B<2 FBD5:.-E 5B<2EDEBFEDBDDFFDDBDA.--.1BDBFDEBDFEDEBQ@1CFDEBBCEDEED,DFFFBD 1DFD 5:.-EDEEBDDBFFDEBFFDDDE CEF IABB F EB D F AD DBED [email protected]
figure 5-4: Intrinsic efficiency of BaF2 (left) and BC501 (right) detectors to monoenergetic pencil beams of photons obtained by Geant4 simulations. The measured detection efficiency of BaF2 (left) for a 24 kBq 60Co radioactive source placed at 10 cm (60Co Meas.) has been compared to the source detection efficiency (60Co Sim.) obtained by simulation.
) BB F =BD/ ACBD F ED EDE B 2/ 5& @.BBE CEBABCF F5B<2EBDEAB FEDE BD ACBD )F CE B BE B -. EA A FD 5B<2 EDB B FD C D F E BD F@. B A D F ACBD B BD E CE FD FD-2:1DDEDDFDDAFBD-..1 D F EDB B BD F DDE D F EDEDEDFEDEFF)F BBAEEDFABC ED EDE /L B EAB F F EACBDEDE83LBDCDDBADBDC:/
ABCDBABEFDAFDFEDAEDABEFFE
54
5.1.2 Pulse shape discrimination (PSD) for BaF 2 and BC501 scintillators )F BE B C FB EADBD !"#$% D F BE FBDABDBCFBEDBEDFBEDBEBDF C FB F DB FEF DB F E KEB"#$ BEBFEDBDE !*DBB-C3-%BFCF FB B D B AEDCED E BE DEBD!AABBD B -C@8% BD AAD D D CD !RD M*BA-C3:%6F DFDBF"#$BBDEBDDBDEEDB
DDE BFEDBFEFFBBBDBBDDFEB EADD !+% B BA !)% <8 5B<2 BD B BDE&CEDB B"#$D BBDEADDBAFEBDBFEFBCBDBEEDFEEDA F DBEDBBDEFDF B C:: FF DDBBD !DCD%EA EDB B FEF FB D EBD A BD F DCBD DB EAB DD BBD ! FD% DFD DCE DB B BDD B E B F F A F FF 7B) BE CE ACEBD FEFECBABBB
)AFBCCBA"#$;FEDBDFEFBEABD!*B-CC:%DFEDAFFBDDBFEDBDBFDDBBDFABFEFFDBDBEFBD!ED%DBFDBEDBEDFFEDB!5BDBSB-CCA%)FABDBBE F AF FB &C EB EDE ACEEBD CCBDBDEBEDBD BEFBECBEDBD ABB )F D C B F A B BFCF CDBEFD B D !T 8.. 1% EFB EABDAF!6ABDB2..2%EDDBDFBDDBFEDBBDCBDFBEFBDBDBDBB ED !G$% AC )F DE F AF EBD BCD AEB EDBD F DB EFBCD FEDBDBBBADD FA DDF BE F D F DB B C F D F ABBDB)F EDD BA FEB5B<2 DD FCB C:: F DBDBF !:.D%BDB D!:.. D% B !=CDB 2../% B H DB B BA F BABACDEFBFB DF HB EB FEFB DB F F B BD F EFB DB FDB FB !)FDFEBBDCDDB DFEF DFBADBD " "#)FDE DFBFDBEFBEBDCBDF2$"#$EBDFFBC::D BEFDB FBACDEFBDBFF$ DB BDCDDBED BBDBDFD" "BDFEFDEBFH
FBD
55
DBED D F BD F BE EBD CD EDD FB FBABACDEFB DB F DB FEFBDBFFBDEBFFBHFBD DCD DB DBC EDBD EBD D F DBDBEFDA"#$FF5:.-EDB!5BDBSB-CCA%DF EB C B F BA CBD !8.. D% C F DE F F !8: D% DBA B BD B B E)F D F 2$ "#$ ECA D F BA DBD DCEB "%"& ' %& BD FC F DCDD B B F HDBEDD)FEFEBDDBDBDB 5B<2 BD 5:.- E B D BEED F C CD D FBCBDFEF CDC B F"#$ ABDE BEFEDB
figure 5-5: Scheme of Pulse Shape Discrimination (PSD) principle. Left: (black) and neutron (red) signals integrated over different gates. Right: scheme of two dimensional PSD spectra showing the relative position of (black) and neutron (red) lines according to the specific choice of integration gates. Q-S represents the charge (Q) of the signal integrated over the short gate (S), the other notations follow accordingly.
DFCBBBF5B<2EBFBBEC22@'BACFEFEBFCFBEFBDNBDUDBD)FA DDB BBEEBDDCF FCF"#$BDBEBDBDF2$"#$ECADDFBC:@ F D !% EDD U BD H $ NDBED B DB 5 DD FD BD EDDBEDEBDDDCFDE FEB BFDDBED
ABCDBABEFDAFDFEDAEDABEFFE
56
DADEDBDDAEBDEBBAFE)FDDEECEAAFDBEDDDBBCAE;FFD DBE D B BDA EBD F E FB BD EDDBEEDDCCBDBFE BDAFDBDEBEFE)FFEFBEEDAABFAEBBD<CFA BBBBDB DB2$"#$EBFFDBEFBF$DB FFFFDBDDFBE FFB !F BDDFEFB DB F F BD D B E% )F FDBCN DBEDCEBDFEF BDF U BD H D F F B C :@ FD BD DECA5B<2DDBBBEDFEFABDBDD F BE FEF EDC F ECA )F C N B BB FD D C :8 EC FC DCF A F EDCEDFUEBBDBCFBECDBDBCF-/@1HBA/.>AC!*FBM>?-CA/%
figure 5-6: PSD applied to the internal radioactivity of BaF2 scintillator. Left: 2D PSD spectrum in which signals arising by photon and alpha are clearly distinguishable as two separate sets of points. Right: internal background radioactivity energy spectra (black curve) in which a selection is operated on signals arising from - decay and interactions (blue curve) and from decay interaction (red curve).
5.1.2.1 PSD test measurements with a 241Am-Be source DBF"#$DCDBAABEADBD5B<2BD 5:.- EDB A ABCAD FB D A F B-@. 5& 2/-A5 CE )F 2/-A5 B BBE CE D FEFDCDFDC-.1!7EF-C38%BCEFCF!N D%BD!H D%DCEBBED2/-ADBDBCBNABDCA F B ABB CDD F D BED FEF B FCEDDCDBDHBADCEBEBD;
FBD
57
( )
nBeBe
n
nBe
MeVCCnC
CBe
NpAm
+→+
+++
+→+→→+
+→
89
8
12*12*12
*139
237241
3
4.44 ;
γ
αα
γα
α
)F BED E ED BED B D D B EAB D F N D != M 1BD IBD -C3:% F D BABD F BDEFD BED *F 2/-A B NCE BDCDBC3.DCD-.@NBEDBBD!7-CC/%
figure 5-7: Energy spectra of a “low activity” (160 MBq) Am-Be source obtained with BaF2 detector. As reported in the inset, the measurements have been performed with three different configurations: no shielding (red curve), 10 cm lead shielding (dark blue curve), 10 cm lead and 40 cm paraffin shielding (light blue curve).
D C:3 FDBDDEB F 2/-A5ABCF5B<2
EEBDDEFECAEAFAFU
CEC BD F C NB C F DDB BBE 5B<2
DDC:@D F2/[email protected]&BBDCDE-./DCD0A D/4FEF BD DBEECDFEDEDEBDBD FBAABDCBFE8:. 5& DDB BE F 5B<2 E )F D EDCD A F2/-A5FECADFHBB///1EDDF -2V E B BD F D .:-- 1 HEB B B 8C8 1!B M >F<BF 2../% D D F D C :3 D F F DCD EDCD F D ECA BDBABCADFBDAFB-.EABFDBD/.EABBDFDDDFCEBDF5B<2E)F BBD B C C F DCD FB EC F
ABCDBABEFDAFDFEDAEDABEFFE
58
CB EB CBED F F ABCAD A F BFD D 6F D DE B EDB 2/-A5 DCDECAB D F BC !"B2..8% ECBEFF DEDB F BFDADB E DCD FHBAFECA
figure 5-8: 2D PSD spectrum of Am-Be source obtained with BC501 detector. Two different aligned sets of points corresponding to neutron and interactions are clearly distinguishable.
)F ABD B C F F 2/-A5 CE B D DCDDBED D F 2$ "#$ EB )F CD C CDBEFB F5B<2 ABD EBC F BB ADD FAD DB ADDB BBE 6F EB AD D C FBBDB DB A 5B<2 B C DCD DB F BDCDBABDAC5! D%C5BED!BDB2..@%DDCDD:1 DBE EBD B FABDBED D F CD BD BCA BA FEF DB A &CDEFCFFDAD
,D F EDB DCD DEBD C BFB F5:.- E B D D C :A 5:.- D D DDBBBE BD F F BECD DB D BEE DD F ED EDE DCD -. 1 FF 5:.-EDBFBD5B<2!=CDBB2..:%D DF2$"#$ECA C :3 BD F 5:.- BD DEDD DCD !C% BD H !D% B EB DCFB BDDF"#$ABDE5:.-
5.1.2.2 PSD test measurements with 14 MeV neutrons DCFBF"#$DCDBAABEADBD 5B<2 BD 5:.- EDB B ABCAD FB DAF-/1DCDB#,$B'6W=B6B2@XB
FBD
59
DCDCDB!'BDMD2..A%BBBBF7BB"F&CCECB!7"% AD<BD!<BDE%
DDEDCD-/1DEDCEFCFFDCEBCDBED
nHH 32 +→+ α
)F ABACA DCD C FEF EC DB B E2-.A D0EB A D /4 F F NBE CE D F BEDFB B DE D 8: 1 FEF EBDD DB F EB A FCDB5F5B<2BD5:.-EBEFFDBBC-.EAAFDCDCEDD
figure 5-9: 2D PSD spectra for 14 MeV neutrons obtained with BaF2 detector. Left: background measurement performed with the neutron beam switched off and corresponding to the internal radioactivity of BaF2 scintillator (analogous to figure 5-6 left). Right: neutron measurement with beam turned on. Two different aligned sets of points corresponding to and massive particle interactions are distinguishable.
D F B C :C FD F BECD 2$ "#$ ECA 5B<2BE&CFFDCDBAEF)FHBDNDBEDBCFDDBBBE5B<2 DFFECAAFDDDC:@EBCFFFBBF")BBCBBBBDDFEFBDBDDFBE&C DB D F F B C :C FD F 2$ "#$ EBBE&CCDDCDBBDEBDDEFBBBDEBDHDBED EAB BECD EB A F H BDD D FDCDCE F CDBCDBFCBACDEBDBEDDFBFABCA!T-A8% BBD EB F B ED&CD CED FD FCF !D DH%BED
ABCDBABEFDAFDFEDAEDABEFFE
60
figure 5-10: neutron interaction cross sections on 19F atoms. In the inset ‘Inelastic’ stays for inelastic scattering mainly leading to (n,n) reactions. Figure obtained from http://wwwndc.jaea.go.jp/
)F BDB DCD DBED A EB D B B DDE BEBDBBDDCDCDDBEDC E D D F H BD N DE D BB DCDFBBDDD DDHBDNBE)F D FEBF2$"#$ECADFFC:CDFEF DCDABF CE B D BD F NBE 6F BECB EB FB BD D BDBD F D BED DCDCDD5B<2,DBB DCDDBEDEEDDCDBABDCFFFBDDBCA!RB% BDCDEBBCDBDBBCAD5B<2EDB FEBDFCEDCD E ED D C BDB EBD DE D C :-. DCD -/ 1 F CA -C< E ED BD N CED DBA !D N% BD !D DN% D ABDC FF FBD F CA BEDEEDBDDCED DBA!D % !D % !D % !D D%)F DBDFDFBFABDDCDYDBCDCCBBNDDF2$"#$ECA)C DC:C BEFBDD2...D F DBB F FNEFBDF )F EC F DBC B BED BD DCED C FFFFCCF DB#ABAFBDDDCDDDBDBF5B<2DB DBAFBABBDBDBDBB5:.- CFDBBDBEFADD"#$&CB<DBEBDEDECFBDHEADBD F 5B<2 &C B B FD EAB "#$ABDE FB EBD BEF F 5:.- D F BA ADBEDDBDDC:--
FBD
61
FBDCFBDCDDBEDF5:.-EDBABDEEC FCF BE BD DBE EBD DCD FDDCE F &C EDB )F AB DH EADBD BECBED B FD D C :-- F DCD BD FD DB EBD EBEADBDDFCD1
figure 5-11: 2D PSD spectra for 14 MeV neutrons obtained with BC501 detector. Two different aligned sets of points corresponding to and neutron interactions are clearly distinguishable.
5.2 Measurements of prompt -rays produced from C-ion fragmentation )F AD A C C BC A BABCAD CE A D BADBD FB D A B=67 EED F 3810C -8@O D !B )B B 2..A% BBADD D ED /2 F ABD C F AD B FADBD F EBD D F DCDB A FDBDF5BBD!C/@%)FBECFBAD B EAB EDB ED F A B AFDBFBAED FBDBDADFBDDDFDEDDBECB BEFDEDB FB D A ),< ABCAD BD EE DCDEFBDC DBBADCDEBDFFDBDDCABCADFFDD BD DEFD BEEB <DB A B ADBADFBACECDFABDEDBDDFD B CC ACEAB BD ACE ABAAB EBAB FEF C DB B EDEB BD FEF BDDCDCC
5.2.1 GANIL and GSI single-detector experimental s et-up ) D AD F ABCAD A FDCE CD -2D BADBD FB D A B =67 BD=#BE
ABCDBABEFDAFDFEDAEDABEFFE
62
D F AD A F C: 10C -2D B =67 DBE A F BECCA BA D E F B ECE AFAFBEB!:KA,2%D!" Z[-20EA8%B!:.:.:.AA8%=# FFDD 2C210CBD8.:10C ABBBB!-2\2:\2.EA8%DC:-2BFDFEFAFADBCDFADFBBEDBBFEFECAABD FBAB ) EC; F5B<2 BDF 5:.- EDB FEF FB BB D D D )B :2 )F5B<2 EDB B EFD ED A D BD FFEDEFDED FF5:.-BCFFDCDED EDE F BECB CB DB B A DCD EADD EB F F D BD BE D F C BBBF 5:.- D ED &CB DCDFDDEBDFCFCFBEADBD
=67 D EABD ABB ! B BD BBD% E A F 5B<2 BD 5:.- E )F B D AFEABDFFDEADDF5B<2E BDF DCD EADD 5:.- EDB DB FE F BDD FFD BCED DD D F" B B 2AA FE B D &CBD ABB !")<BZ[280EA8% BD B @AA FE B CD &CBD ABB !# C']// Z[.20EA8% * DB B F DCDE F BCA D F FD CD BD BDCBD BBD B ABEDEB"B!2EABA(:EADF%BDBECEBB!8.\8.\8.EA8%
=# BDBEABBCFF5B<2BD5:.-E FEFBEBEBDDDC:-86FBDBDBBBD EAB B B FD F B EAB D F ADF 8.: 10C D D F ABD DE D F ADAB=# BFBEABBCFEFB E -.AABD/AAF2C210CBD8.:10CAD)F BDB BBD EAB B F C FFF FA FD DB F DCD DCE BECD B BD D A B CF D F EFB ED AD DED F =# AD F BDE D F B BD FE FB B DEB A - A -8 A D F AD F 8.:10CD
FBD
63
figure 5-12: Diagram of the GANIL (left) and GSI (right) experimental set-up. At GSI an additional paraffin collimator was added when the lead collimator slit was reduced to 4 mm in the experiment with 305 MeV/u C-ions. The distance between target and detectors was 1m for the experiment with 292 MeV/u C-ions (Pb-collimator slit: 10mm) and 1.3 m in the experiment with 305 MeV/u C-ions.
)F ABD DE D =67 BD =# AD B AECABCADFFBACECBBABFBDFEFECADBDED.DBE CDBDEBDEFD&CCDFABCADFADBDFABEFDDFBBDFFDEDFEDB)FDABDB)A ACDAC !)%=67 FFBAC!BACE-DA.D% FEEDFF&CDE!K<%DB!CBB%ECCBDB)FBDB B F F 5B<2 5:.- ED B FD DCD D BD DD BE&CD A )F EFE BD F BDB A F E FD F ECD B B ADA F DCA D FEF B B DB D FB BEDDDB)FBADDBADF6B!)%Y8DEFD E D D )B :2 !D FD D C :-2% BE B BBBDEAFB DBDBECDDBDBF BA DD C DB DDD B D BD EABD)F 6B!)% E B EBB F B <BBB EC B FF DD!D%)FBADDBBC-D!-.CD0% D A F E ECDD B F BD C BD BA
ABCDBABEFDAFDFEDAEDABEFFE
64
E D EDB B F ##=# DEFD F B EDDCCA BEDABC!EABEDE-.% F),<DBB FD BE EDB DED F BA $CD F EBD DBED F DD B B &C B BC !B -.: D0% BBD DD DFBEEDB !FEDEBEFE EABD D BD EDEDE ED A% )FEDBBCABCFDBDCADFDFB < F AD F E BC !A BD DCD% B A F EDDDB 6 EDE BD B 1BBBBE&CDA)FDBEDEFABEBDDFD
figure 5-13: Picture of GSI experimental set-up. From left to right are visible: the beam line exit window in front of the water filled flasks (target), the lead collimator (gray) with additional lead-bricks shielding (blue and yellow), the superimposed BaF2 and BC501 detectors. Two thin plastic trigger-scintillators (not present in this picture) were place between the vacuum window and the water target. The additional paraffin shielding between the detectors and the collimator is not showed in this picture.
5.2.1.1 Calculation of detection solid angle and f ield of view )F ADBD F BD BD F E DBFB D C C F FF D B ABD EBC FDE BD D BEECD F EBD FD F EABBD BD BDCBD EED BD F E EDE < FBDFEDBDBDFFBDBCBABD D B ACBD FEF F D BEECD FFBD E BCD F F EAB )F BEDF=BD/ACBDABCDD!7<CF2.-.%
)F ADB C B CE D B ACBD D FEF B DBCE EB A FD !F F BA D ECA AFDEBCDBADEBD%BEF"BB
FBD
65
)FED FEF DCEB EDFDBDADAFEFFDECE DB
)( ∞
∞−
≈= FWHMdzzPL
() BD ACBD BD D F B ED BFDFEFFBDABBDBBDBDC:-/D BEE () BD DABBD F ECA F EFDADD ABACABC)F EBDBCA&CBDF<*K()BDBCBD)B:8FDADBC
figure 5-14: Simulated detection probability for GANIL and GSI experimental set-up (20 cm long Pb collimator, geometry shown in Fig. 1-12). The origin of the axial position corresponds to the center of the collimator slit. Figure adapted from (Le Foulher 2010).
)FEDBD*DB
πγ
γ 4
Ldz
dN
N
Emit
Detd
−
−=Ω
E%+FBDCAEFD EA+)FDBDAFDBD FED )FBC* FDADBEDCBDBD)B:8
ABCDBABEFDAFDFEDAEDABEFFE
66
Collimator slit aperture [mm]
Field of view L [mm] d [sr]
GANIL 95 MeV/u 2 4.1 4.33 x 10-4 GSI 292 MeV/u 10 22 1.07 x 10-3 GSI 305 MeV/u 4 6.4 4.54 x 10-4
Table 5-3: Values of field of view and detection solid angle obtained by Geant4 simulation. Table adapted from (Le Foulher 2010).
5.2.2 GANIL multi-detector experimental set-up ADBADFBACEABBDACECFBDEDAB=67F3:10C-8DCDDBECE " B !:. :. :. AA8% EBD D A C :-: FDBCFADABFDDDFCBBBFEFBEFBFA C79#,E!DD)B :2; $ADD F E C D F H BD DCDABCAD% FB D BE BD BEF FA B BD FD BEB F CDD B !$DAJ Z[-3 0EA8% ACEABDFDBFBAED,DF F B BB FDB F BA ED B D YDED79#, E B BD FD B B EAB #DE D DE FEABBFBFFDADFDBFBAED BEF79#,EDBCEDFFDAD F D BD EAB 6F FEABBDEFDWEBX!EBDADE F DFCD D% EBD B BE BD BB FD EDD D A F A D )F FDADD ECDABDFDEFB
#DEFDBDEBAAA!FDEBDEBFA AA B % BD F D BF B E-: AA D 79#, E BAD B F D BF B F BA A )F B BEF 79#,E BEAEBDFFDDCEFCDBF FB B BBD BE D B A ED B AD BD F BAED )F B FF D E BDE B DFBEF BD A D F E BBDAD B FD DC :-@ D F B FAC C !")% BA !^ 2 EA% EA F C AAE BD BAAE F C EDDE F79#, EB F ") D BEF F A EABE E BBDAD F EFE CD 79#, EB FD ADD !B D D )B:2% FB D AB DBFEFBFACBEDBCABCCD BBBADD FBECBACE C ADBBDABECDBCCCAADDDED.
FBD
67
figure 5-15: Diagram of GANIL multi-detector experiment.
7 F DE AD B =67 F BA DD BAD B 6B!)% E F ECDD B B DB FBA DD BD DDD B D )F BA DD BBBDBC-D!-.CD0% DFDEDFAD E B C B F BA A BA EED D BBED EA DEB D F AD F DE F DB ),< ABCAD B F EED FF&CDE!K<%DB!CBB%)FBDBBFED B FD DCD BD F 79#, EDB D BDDD BE&CD A D F DD BD D BB BDB BBDCDACBCDFEF79#,EDBFBE&CDD
figure 5-16: Technical drawing of LYSO detectors arrangement. In the GANIL multi-detector experiment only two LYSO detectors were constituted by pixilated crystals.
ABCDBABEFDAFDFEDAEDABEFFE
68
5.3 Results and discussion
5.3.1 GANIL and GSI single-detector experimental r esults
5.3.1.1 Time of flight spectra analysis DC:-3BDC:-ABFDFAFEBF5B<2EBDB=67BD=#E)FADEDBBFB FD FAEBEDFAFDFDFFBDDEDDFDDDFEAFBD21BD/1ABDF),<EBDFBDCECE
figure 5-17: Time of flight spectra for BaF2 detector for the GANIL experiment with 12C ions of 95 MeV/u. The origin of the time scale corresponds to the time when the C-ions hit the target. Red and blue spectra are obtained by selecting the events which deposit in the detector more than 2MeVpe and 4MeVpe respectively. Spectra are obtained with the collimated detector looking at a target penetration depth of 16 mm. The bin width is 0.1 ns.
D C :-3 B FB A FD B EB DB B 2 D )FCEC FB F A FD B B C DCDDCE
FBD
69
BBDFEFFEBFAFD)FDCDDCE CEC BAD D A B D F D BBBF6FEBDBBBFBFBABDCDCDDCEBBD CE D F EAB BD D F ADB EB BFFBBDDBBDBEFDEDADF),<EB)FFDFF FFFFDCAEFDFEFFBEBBFBFEB)FBDF FDDEC FEADDB-.2.DFFFBDFDB:-.D
figure 5-18: Time of flight spectra for BaF2 detector for the GSI experiment with 12C ions of 305 MeV/u. The origin of the time scale corresponds to the time when the C-ions hit the target. Red and blue spectra are obtained by selecting the events which deposit in the detector more than 2 MeVpe and 4 MeVpe respectively. Spectra are obtained with the collimated detector looking at a target penetration depth of 170 mm. The bin width is 0.1 ns.
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F A BA A BD F BA DD &C D DD F F BE EDB BD D ED D FDDBB21DFEDEBEBFAFDBDFDCDDCECECBDFCBFAFDBCFBDCDCEDBDFDDBF)FD=#EB FEDCECFFEBCFDBD B 8.:10C E-A. AA EAB E2- AA B C:10C BD FBBBADBDB E:.LDB8.:10CBDDE-.LDBC:10C
BBADDDED. BDBDBBBDEABBBD D F B EAB F AD B =# F D B 8.:10C)FDCDEFBDBBBDFDDF),<EBFD D C :-C EBD D F F BDB BBD FDCDDCECECBD FCB FAFDBFEF F EBDBDFCBBD6F FABFBFADBDBFCDDFDFBDAFFBDBBBDFDABDEBC DFDDBDB ACDFAD FE FBBDFDD DEBD F B A FD DB DCDDCEBECDCFFFBDFBECFBDAABDBDDC:-C
figure 5-19: Time of flight spectra for BaF2 detector for the GSI experiment with 12C ions of 305 MeV/u with (red curve) and without (black curve) additional paraffin shielding. Both spectra are obtained by selecting the events which deposit more than 2MeVpe in the detector. The origin of the time scale corresponds to the time when the C-ions hit the target. Spectra are obtained with the collimated detector looking at a target penetration depth of 150 mm. The bin width is 0.1 ns.
D F B C :2. FD B ADDB ECA FD D F 5B<2 E B B CDED F ),< FD FE B DB B D E F 5BB D F AD B=67 F C: 10C -2D BB FD D C :-3 B FB
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figure 5-20: Left: Two-dimensional spectrum of the energy deposited in the BaF2 detector as function of TOF. The spectrum was obtained at GANIL with 95 MeV/u 12C-ions with the collimated detector looking at a target penetration depth of 16 mm. The origin of the time scale corresponds to the time when the C-ions hit the target. The energy axis is calibrated for photons. Right: Two-dimensional spectrum of the energy deposited in a NaI(Tl) detector as function of TOF obtained at GANIL with 75 MeV/u 13C-ions. Spectrum adapted from (E. Testa et al. 2009).
DC:2-FDBADDBD),<ECABDFF 5:.- E D B B D E F 5BB D F =67ADFC:10C -2D)FAFDBBDB: DADB F D),< ECA EBC F B EABDFBBDEABDDF5:.-EDF@. EA FE BBD EAB FB BD BD DF EDD E:EABFEFEADCEDFABFD B 1 CE CD F BAD EBD BD DECA C :2- )F EBD BCA FB F BACD AFD E F 5:.- EDB ED F DAFDCEDBDFDDBFBDADF F 5:.- E BB ADD F BBD EABB A DB B A DCD EADD D ),<ECABDF BEEBEDBD F5:.-EEC ED CDEAB B 6F D A DCDEADDECEDCFBDFECAC:2-BDABBDBCD F"#$EFD&C D D FDBBBF
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figure 5-21: Two-dimensional spectrum of the energy deposited in the BC501 detector as function of TOF. The spectrum was obtained at GANIL with 95 MeV/u 12C-ions and the paraffin-collimated detector looking at a target penetration depth of 16 mm. The origin of the time scale is arbitrarily set. The energy axis is calibrated for photons.
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figure 5-22: Two-dimensional spectrum of the energy deposited in the BaF2 detector as function of TOF. The spectrum was obtained at GSI with 292 MeV/u 12C-ions and the collimated detector looking at a target penetration depth of 150 mm. The origin of the time scale is arbitrarily set. The energy axis is calibrated for photons.
5.3.1.2 Time of flight (TOF) spectra analysis cond itioned by pulse shape discrimination (PSD) BB ADD D F C BBBF B A B BDB F A FEBEBDA DCED F DABDBCF BE FEF EDC BEF D F ),< EB *F"#$ DCDBDFDEF5:.-EDBECEBDCF D F F AD A B =67 BD =# C._F E F BA ED F F E BE FDBD DCD FA B F EFB BE CE CD DBADBD
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figure 5-23: 2D PSD obtained with BC501 detector for the experiment performed at GANIL with 95 MeV/u 12C-ions (left) and at GSI with 305 MeV/u 12C-ions (right). For both spectra the collimated BC501 detector was looking inside the ion path. The energy axes are calibrated for photons. Two different aligned sets of points corresponding to and neutron interactions are clearly distinguishable.
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FFABACAFDEADDBEBECD)FCABDFB B F DBED EECD D F D A FD BBDFABACAFCEC!ECD%CCEEDCD F C D FB B E ' ,--. EDD BDE D FF FBD --. 1 5C B D D C :2: FBACD DCD F DE D FF FBD -.. 1 D BADBDEC.FBADBDDCDDD C BC E F D F FE DCED B CDADB!=CDBB2..A%)FEBDEDECFBD F EB =# ),<EB F CEC D D : BD -: D DC:2/EABDCFDEBFCF!DH%BEDDFBEAB
figure 5-24: Left: TOF-spectra for the GANIL (95 MeV/u 12C ion beam) experiment. Right: TOF-spectra for the GSI experiment (305 MeV/u 12C ion beam). The spectra were obtained for detector focussing on a given target penetration depths (Pos=0 corresponds to the target entrance, and the origin of the time scale corresponds to the time of ion impact on the target). The energy selection is performed on the photon equivalent energy of the detected count.
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figure 5-25: Simulated neutron energy spectra at their emission points. Neutrons are produced by the fragmentation of 310 MeV/u 12C-ions stopping in a water target. A selection is performed over the quasi-orthogonal neutrons emerging at angles between 85 and 95 degree with respect to the ion direction (red curve) and over the neutrons emitted at forward angle (blue curve). Figure adapted from (Le Foulher 2010).
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figure 5-26: Sum up of all the TOF spectra obtained with the collimated BC501 detector looking inside the ion path (GSI experiment with 12C ions of 305 MeV/u) at eight different axial positions from 25 mm to 180 mm. The sum-up of the spectra allows the identification of the prompt photon peak. The origin of the time scale corresponds to the time when the C-ions hit the target. The bin width is 0.1 ns and the energy selection is performed on the photon equivalent energy of the detected count.
5.3.1.3 Photon and neutron scan profiles )F CAB C F ),<EB BDB D D F CBBBFBFEBDFDDFED)FAFDEBD D D C :23 ! D% B BD DBD FECDEF5B<2EDBDFAFDBF),<EB ! C :-3% B BC DCDB D; D .EDFBDBDE BDF5BBDABBBF D )F A DBD DB B -: D ED D F AFDB)FEBDDFBEDC:23 BD DBD F ECD E F 5B<2 EDB FD),<ECAADDB BFDDFF21BEFDAFBEBDFDBBECDBDFEB FEBDBD DBDFAFDEADD F),<ECA!D%BEBEBDDFDBFBDFFDCED)F DEB FHBB FDFDBFEBDBCBDDEBFBADBDEEDBD FD AD ACE FD F D D EB ,D FEDB F EBD BD DBD F D ),<ECA!BED%EABBDFCDEBDBD)FADB FBCD AFED FAHBEADDF),<ECABDFDEBDEBFFDBDFDCDFD5B<2E Indeed it has to be nFBF DBBECD B ABC D F D EB B D A; A FBD C.L F - CA 5B<2 E D
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figure 5-27: Longitudinal scan profile obtained for GANIL experiment with 95 MeV/u 12C-ions. The origin of the longitudinal axis corresponds to the target entrance position. The prompt gamma yield obtained by TOF selection (red points) is strongly correlated to the ion path in the target, whereas the counting rate profile without TOF selection (black points) is almost flat. The calculated Bragg-peak position is given by the dashed vertical line.The error bars corresponding to statistical errors are hidden in the dot symbols and the energy selection is performed on the photon equivalent energy of the detected count.
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figure 5-28: Longitudinal prompt photon scan profile obtained for GSI experiment with 292 MeV/u 12C-ions (left) and 305 MeV/u 12C-ions (right). The calculated Bragg-peak position is given by the dashed vertical line. The error bars correspond to the statistical errors only and the energy selection is performed on the photon equivalent energy of the detected count.
figure 5-29: GANIL and GSI prompt photon profiles normalized over the detection solid angle and field of view presented in Table 5-3. The energy selection is performed on the photon equivalent energy of the detected count.
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figure 5-30: Prompt photon profiles for PMMA target with different inserts: the rectangles indicate the longitudinal position of the bone equivalent (green) and lung equivalent (red) inserts. It is observed a variation of counting rates vs the material density and the differences on the ion range induced by the inhomogeneities can be detected. The calculated Bragg-peak position is given by the dashed vertical lines. The inset on the right shows an illustration of the target with the different material inserts. The energy selection is performed on the photon equivalent energy of the detected count.
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FBDADBECB FEBDBDBBDBECEBB !8.\8.\8.EA8%FFB FBDFFD D FAFDBDBDBFBECD!EDBBE%CE-2/ EAB E F-/:BD-:/ F CB ECE "B BD F AB EDEB " B !2 EA BA ( : EA DF%)F BC B BD A C :8- F D D ED D FAFDBBDBDCDBD-.AADBEEEBDBCAFB BBDBDBA FEDBDAFDED D F D BD B F 5BB C EABBFFEDBBECDFFECE"B!:.:.:.AA8%DFABACACEDFEDBBEDFABED!2EABA%BDFECEBB!8.EA%BC2.L
figure 5-31: Prompt photon profiles for different target volumes. The signal to background ratio decreases when the target volume increases due to the higher probability of photon scattering. The inset on the right shows an illustration of the different targets.
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Contrast factors
No E Selection Counts ×10 -7
E > 2 MeVpe Counts ×10 -7
E > 4 MeVpe Counts ×10 -7
IN 6.11 3.78 1.35 OUT 3.96 1.70 0.64
Cylinder 2 cm
Contrast factor 1.54 2.22 2.11 IN 5.86 3.13 1.21
OUT 4.03 1.68 0.63 Cube 5 cm Contrast factor 1.45 1.86 1.92
IN 4.61 2.43 1.00 OUT 3.71 1.58 0.59 Cube 30 cm
Contrast factor 1.24 1.54 1.69
Table 5-4: Achievable contrast factors on the photon scan profiles for different target size as function of the energy selection applied on the photon counts. Photons counts have detected at a longitudinal position of 10 mm (IN) and at the background level (OUT).
5.3.1.4 TOF-spectra and prompt photon scan profile comparisons between measurements and Geant4 Monte Carlo simulations DBBFFADBABCADDB =BD/DBACBDFBDADFCDCEFABCADBDABDEFAB=BD/EFABCBBAHBEBCDDCEBBADEBD)FBBFACBDEBDCDD(Le Foulher 2010)
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figure 5-32: Comparison between TOF spectra obtained from GSI measurements with 305 MeV/u 12C-ions (as in figure 5-18) and Geant4 v9.1 simulation. In the hadronic physics list the Binary Cascade model (BC) was used. The origin of the time scale corresponds to the time when the C-ions hit the target. In the simulated TOF spectrum a normalisation factor (~12) has been applied to all the detected photons. Figure adapted from (Le Foulher 2010).
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figure 5-33: Comparison between Geant4 (v.9.3) simulated and measured (as in figure 5-27 and figure 5-28) photon scan profiles obtained for GANIL and GSI experiments. In the hadronic physics list the Quantum Molecular Dynamic model (QMD) and the Fermi break-up de-excitation model were used. The calculated Bragg-peak position is given by the dashed vertical line. In the inset of the figure (left) are reported the simulated and measured profiles normalised to the maximum photon yield. The error bars correspond to the statistical errors only. Figure adapted from (Le Foulher 2010).
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5.3.2 GANIL multi-detector preliminary experimenta l results
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figure 5-34: Time of flight spectra for one of the LYSO (medium) detectors employed in the GANIL experiment with 13C ions of 75 MeV/u. Red and blue spectra are obtained by selecting the events which deposit in the detector more than 2MeVpe and 4MeVpe respectively. Spectra are obtained with the collimated detector looking at a target penetration depth of 10 mm. The origin of the time scale is arbitrarily set. The bin width is 0.2 ns.
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figure 5-35: Two-dimensional spectrum of the energy deposited in one of the LYSO (medium) detectors as function of TOF. The spectrum was obtained at GANIL with 75 MeV/u 13C-ions and the collimated detector looking at a target penetration depth of 10 mm. The origin of the time scale is arbitrarily set. The energy axis is calibrated for photons.
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figure 5-36: Prompt photon scan profiles for the multi-detector experiment performed at GANIL with 75 MeV/u 13C-ions. Position 0 corresponds to the target entrance. The calculated Bragg-peak position is given by the dashed vertical line.
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figure 5-37: Scan profile for the multi-detector experiment performed at GANIL with 75 MeV/u 13C-ions obtained with no selection on the TOF spectra. The calculated Bragg-peak position is given by the dashed vertical line.
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FBD
89
EBD D E EED F BADD BC CBD B D )B :: F F D 5B<2 E B C D FDADBEDCBDBDBFDFF21 BC3HECDFDBD8HECDCFDBFF=67EBDFDDC :23 F C BD BC 2. HECD FD BD 3 HECDCFDBFF=#EBDF8.:1DFDDC:2ACAD B CDA CD D D F CAC CA D B CDBABDABFDCAFDDBEB CAC E D A EDEB B BE EFD&C BC C.L F FB B F ` -.L FABACA F D BD DCB !7AB B 2../% D BEE FC ABD FB F B EAB BAAB EBAB C B ABDEBDFABDEFEFFB FF FBD B F CEE AB D E * AD FBFDBBECDBABCDFDEBBDA;AFBDC:LF-CA5B<2EDBECD FEF&CBB&CBDBFDC FEFDCDEBBFFDCDBDBAABBECD
Measured counting rates [counts/ion]
Estimated photon Counts/Slice
Inside ion path 4×10-7 7.2 GANIL 95 MeV/u 12C-ions Outside ion path 1.5×10-7 2.7
Inside ion path 1.1×10-6 19.7 GSI 305 MeV/u 12C-ions Outside ion path 4×10-7 7.2
Table 5-5: Estimated photon counts per tumour slice based on measured counting rates with a single BaF2 detector and a 2MeV energy threshold applied over detected photons. The estimation is performed for a typical clinical case in which 1 GyE dose is delivered to a 120 cm3 tumour volume (M. Krämer et al. 2000).
)F EADBD D A FD BD BECD BBD ABFAFDFABDEFBBEECADBCBD B F C C DCD FD )F BC BECBABDE DE A DEBD CE F F FDABB!B)BB2..C%BDBADBADBCFBEACEBBDBDFEFB<CFA ),< EFD&C B ADBD F EBD F A FDCEDBDFABDBFFBDFCDBDFFDBDDCDEDCD D),<EBBCF F"#$EFD&CBDCDEDB5:.-
FCF C FF DCD ED EDE 5:.- EDB F BEE BBD EABD DB B A DCDEADD EB F F D BD D CEF EBD B CD)F BDCDEBC._EBDDEDCCDABD D BD EBD K F D A FB
ABCDBABEFDAFDFEDAEDABEFFE
90
DCDECDA DABDBBA BBD CFABDDBDBDFC
)FDBDFEBDDFADADBB ABB EBD F A FD CED F F BD F B D CD BD BD DCEE F FF BD D D D F " B EDBDFFDEBD)FADBFDBBBCDFEFEBDBEFFBEABCBDFBEBDABBCE-2AA)FDBDFDCDEFBCA D F A FD B FB FD CD BDBDCBDDFBBEDB FFBDACABDF B B DEBD D F ABC DB BECD B DBECB FEBDBDBBDBECEBB!8.\8.\8.EA8% F FB EAB F BBD F CB ECE "B !: \ : \ : EA8% F B D F A FD BDBECD FD !EDB BE% CE BC 2. L F BDD ED D FD F A FBD 2 1 )F EDECFB BBDBDBA FEDBDAFDEDDF D BD B F 5BB B&CB D BDEBD
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91
BBDEBBDF DB FFBECBADBC F EDB BE BEF F BE 79#, E !E2% ABD FBAFDBBDFFD5B<2EDB
6FB FDABDADFB DDB EAB D EDEB BD EDD F BAAB EBAB FC AB FEFABCDBEABEFD FBD F ),< EFD&C 6F F C B EAB EECD D D D D F BD C D DE BED FBD FAB DBDFCAD FBD)FBDFEBFADBADAFF ACE C F AEB BD C F B B E FED !DE BDE A AA% BD ABDBF!E-:AA%D79#,EBADB F DBFBFBAA)FB BEF79#,E BEAEBDFFDDCEFCDBF FBBBBDBEDBA ED B AD BD F BA B 6F F DBDBEABABAABEBABFBEABEDCFBEFBBCDBCE-2AABDEDBFBAA F D FD DCE F C D BF D F D EFBB AEB EDCBD F EAB BD BE EB ABEB C BD F EDBD D F ABD DEDBDB
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92
6 Geant4 Monte Carlo simulations for the design of a multi-detector multi-collimator Prompt Gamma Camera
AAAABCDEFDBCACABDDCC ACE AEFC BCE CB FEC FECEEC D ACFEC AF CB EECFFACECDCAFCBCBECAFDBAEB AFD!CC A F C B ACFECA AE CEDCFCA D B EECA A" D A B AACEECACBDBBBACCABCACACA
6.1 Application of Monte Carlo simulation codes in medical physics
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93
6.1.1 A short overview of the code architecture and physical models used in Geant4
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94
6.2 Simulations of a simplified multi-collimated and multi-detector Prompt Gamma Camera
6.2.1 Basic principles of collimator design FECE CC. ACEEC BCACDDFAC D $#BA. A. EA EE ACCEEC A A(Anger 1964). CA FA C A C DCCAA CCB BFCEA & D CBFCEA'ACEEDAFADFEAACBCAC!ABB!AAFCECCAD$#A>FACDCAE C C CAC BCFFA EE ACCB ACEBFCAACB%$#2BECCAABCEF"DCFECABCBFBC>C.CBECCACBCEBC CCCAF!EA& A' C 31 CA C B A D ACCB 81CA C B A D %$# #B A CAA FA C CEFECC988/& AG9"H'.I:& AB89GE844"H'.938& A 9EB "H' 9G+ & A E99 "H' BCFF E B BA CB BC C D CC CA BFA FFC C C AACECDCFBCAACCAD A#BDBA CE B CA E EEC C B CCAF> B A DCF I9 CA CEEFA AEC D BC ADEECABCBE CAEAACDCBD BC DFAC&%B344I'CBEEECACCEAB CB ACE BE FA C CC AEE A AFB A BBCEACCDCCACEECACBBEACFACCECCDC CA B B D CA CA AEE B B AC; D B 1CC EECA AFCB BEABCB C D B D FA CA AFB A EFABFAFEEEBBAC;DB#BD.ACD B CA D DCF I9. CA CDC CEECACCDCCCEECAEEEBEEECA CB BEA B EEE B B CFE B D1C B EECAC B AB D B BEA BDB!E.CFEAFFBCEBCFFAFEEA 444 4444 #BA EECA B A E FA CFECCFADFCAB>C2FACBECEECACDCCEECACCDBCDB>.BAACAEAECEECCACACAFCCACCBBAEECABCB BD E. D !E. %$# AFCBA B FBECBCBADEEEBEAEECA
95
figure 6-1: Diagram of different types of collimators used for gamma camera in nuclear medicine. Figure from (Bushberg et al. 2003).
6.2.2 Description of the simulation set-up + F FECEEC FEC BA EEEAECEECACACCACEEFACDCFI3BCFADBCABECFCEACCDB2"BCB CA DCCC. CEC" C B A D ACE CE EEE C ECFCE ACC C B A AC AEC DFF CA CA #BD. C B AA. EEEAECEECA. EEEBE EECA CEE AFDDCC ! BECFCEACCDB2"(BEAA.CFA.BB C AAFCA B AC C A CEACECCECA!ECEC"FEDB A CACA D B DFA C B !CE E D BECFCEAFAECCEC"CEDCE(U. Weber & G. Kraft 1999)CBCCAECDFFCB CA CA C FFCE D "A CCFEBAECFCEACCCBEDECD B !CE CBCCA F B CA D BC ACCAECCE*BCACAAECCBDCEEFFCEDCBED#BCAEACBA CAC C B F AFF CC B B C DDA. A E CF C AC 39. BA FEC B CDC B AA ACC D B BCB BD C CCE E CB B AACE !CE CBCCAFBCA
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96
figure 6-2: Diagram of the multi-collimator and multi-detector simulation set-up. FS and FD represent respectively the source and detection field of view including the source and detection penumbra marked as gray and pink shadowed area.
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97
ACCEECAEFABCCACBCBBCDDCC C AEFC A )J%* A B BA +CEE. AC BFCE C A EA B AC; D ACFE AF. FAED34EBEBCBBAACFE
figure 6-3: Screenshot of the graphical representation of the simulation detection set-up. From left to right are shown the isotropic linear source of photons (green), the multi-collimator (purple) and the stack of LYSO detectors (red).
#B C CDD FA C CCE FECC CC F AA B D BCC CC . BCE D CCE B B CA CAE " &DC! B CCA C C BBFCE ' CE !A E99 "H. C F A B AAFCA!ECACFCABCBB94HAADBAFACDCFI0 C CABACFEAFD AFCQACAD!CCFCBCCD894HPF 93CA DFEE A C (Le Foulher 2010) #B BCACACAAC"AHD93I98HD9I*(Polf, Peterson, McCleskey et al. 2009) EE CACE #BCA AFBA DCCB B!CE DC C B CAD DCFIBCB BA BD FA C F ACFEC A D B CACFCDB ACBECBAFACCAABCCEA C (Le Foulher 2010). C B B AFD AFCD!CCCABCDBCBDBBCDFACCFACFEC BAFDBF ACEC&894HPF'AA>FACDC
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98
CDCFI3'CADACCEEE"AFACDFECC#BCAEEAFACDFECECCADACBBECBCCDAEAEA
figure 6-4: Energy spectrum (black line) obtained by Geant4 simulations of prompt -rays emitted in 4 steradians and produced from the fragmentation of 310 MeV/u 12C-ions fully stopped in a water target (Geant4 9.2 with the binary cascade model). The red line represents the exponential fit of the simulated data. Figure adapted from (Le Foulher 2010).
#B)J%*CDDCCBAACCB844"HCBA BA CDE CAC D CDD AE BC"AAA ACFECB CCDCEDBACEEE BBC" CAC D B AE &$' BCC B D B D CBAFAACDCFI3#BAFEADBAACFECACDCFIECBBDDCCAACBB D 4E H &CE F B A DBEC AA ACA' C AECBE CAA D $ RGHF B CADCFCAA ACA%CEE C DCFIE.B AEA A B DDCCCA EFE CB BCBABCEBAAEAABBDDCCDBACBBAFACDCFIBCBBACD3EHEEBACFECABCBDEEAEAAA8BCBCBAADC! E A ! B BC" B AE B BCB CA CA CDDCC BD C FE D A CA BA B BC"AAACE A (BEAA A CCAC ECCC F B CECCC D )J%* AEA &BCB CA " C F C BAACFECA'FA AC BD DD BA CDDCC"FCAF)FAEA C AC E99 A EE B ACFECA A C BDEECCCBAEBC"AADEEDACCA &EBFB ACEE A C BCA "' D B !CE
99
AFEA C CB B FEC !C AB C B CFABBACFECAAB
figure 6-5: Simulated detection efficiency for a single LYSO detector with different thicknesses (E). Circle points represent the efficiency for monochromatic photons and star symbols the efficiency for the photon with the energy spectrum presented in figure 6-4 with a median energy of 2.5 MeV. In all the simulation the width of the LYSO crystal was fixed to 3 mm (D) and a pencil beam of photons hit the center of the face oriented toward the source as represented in figure 6-2. The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2.
6.2.3 Basic description of collimator imaging prope rties # ACA D ACFECA B D CB B ACDC C DCACC B CDEF D B EEC CEA B DDCC ACE AEFC C CAE AAF B B EEC E EA > E CCCBACEAEFCDB.FCAAEAB>ECCCBFDFA
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100
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#BCA DD F . C D B A D CEEEC. CA EE F D E EECA (BEAA. D ACFECEDCFCABCBCEEACCEACB ! B E! ECABC B DDCC ACEAEFCBAABCFFC.FA."CFEBAFDCEDC+%FEABDCEDC(BEAACBACBEEBFFCAAADFDBAACCECDBACACBEECDFBCCCBB*EBAACBFBBEECCBFCCF
DCAACADACFECBADCBE"D)J%*EEC CE CDCC ACE AEFC B B CC CACBBACCEE#BDFEE"CFBCEDDEECECDECACACFECACBCB B )J%* BA A C AE ?CEAB@ AEEA A" AC AC A A C DCF I3 #BCA EADCFC EE A EE "C C F B B AAE"&AC D B CBFC A' B )J%*AEAEBFBBAAFEAACBCA"
101
6.3 Simulations results and discussion EBFB AB C BCFAB BC DDCCACEAEFCDCCACEEECEEA ECC C D F ACFEC AFEA AC BEACABCDEFDBCCEADBEECAA"DAAEBDDCCACEAEFC
6.3.1 Influence of the collimator design on the det ection efficiency
6.3.1.1 Influence of the collimator thickness and p osition on the visibility of the collimator slit-pattern
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102
figure 6-6: Photons detection (black lines) and emission (red lines) positions obtained with a 25 cm thick collimator placed toward the linear photon source (top), at the central point between the linear photon source and the LYSO detection block (center) and toward the LYSO detection block (bottom). On the left part of the figure a selection is made over the photons detected between -0.5 mm and + 0.5 mm (black line) and their corresponding emission position is given by the red curve. On the right part of the figure a selection is made over the photons emitted between -0.5 mm and +
103
0.5 mm (red line) and their corresponding detection position is given by the black curve. The notation used to indicate the geometrical dimensions follow the one introduced in figure 6-2. For all the simulation S=T=1 mm. The origin of the zaxis corresponds to the central longitudinal position of the camera.
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figure 6-7: Diagram showing the purely geometrical source field of view (FS) and detector field of view (FD) as function of the collimator position (a: Source, H0; b: Center, H=B=(X-L)/2; c: Detector, B0). The symbols used to indicate the geometrical dimensions follow the notation introduced in figure 6-2. For all the simulations X=100 cm.
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104
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figure 6-8: Photons emission (black lines) and detection (red lines) positions obtained with a 50 cm thick collimator placed at the central point between the linear photon source and the LYSO detection block (FD=FS=2 mm). On the left part of the figure a selection is made over the photons detected between -0.5 mm and + 0.5 mm (black line) and their corresponding emission position is given by the red curve. On the right part of the figure a selection is made over the photons emitted between -0.5 mm and + 0.5 mm (red line) and their corresponding detection position is given by the black curve. The notation used to indicate the geometrical dimensions follow the one introduced in figure 6-2. The same number of photons is emitted as in the simulations of figure 6-6.
6.3.1.2 Influence of the collimator thickness and p osition on the detection efficiency
B CCE D B AAAA D B DA CA A B EEC BC"AA BCB. C. BA ECDEFBEDDCCDB
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105
B. C. F AA B DDCC $ BCEADCACDCFI3$FFCICACFCC CECA B CA CEC B DDCC B BEEC BC"AA B CECB #BCA ECBACDC BACFECA AFEA C DCF IB. B B C DDCC CAEADFCDBEECBC"AADBAB!#BFADBCADCFCBFFCDBDDCCAACECEB CA D B EEC BC"AA F%&' B AFEA D BACFECA DEE BCA !AAC A A D B DC D B ACBE
figure 6-9: Detection efficiency as function of the collimator thickness (L). Three series of simulations are plotted according to the position of the collimator with respect to the linear source of photons. The blue dots represent a collimator position next to the photon source (H=0), the red dots represent a collimator position next to the LYSO detectors (B=0) and the black dots represent a collimator position in between the photon source and the LYSO detectors (H=B=(X-L)/2). The dash line represents the fit of the data presented in the plot according to the fit equation reported in the inset. The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2. For all the simulations X=100 cm, S=T=1 mm.
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106
figure 6-10: Histogram of detection efficiency as function of the collimator position for different collimator depths. Collimator position Source, Center and Detector follows the same notation introduced in figure 6-9. For all the simulations X=100 cm, S=1mm, T=1mm.
*AACE !EC C BA D DDCC D EECACCAEBBAFBEAD ACECDC CEE DBCB. C ECB B EC;CEFEC A C AC E399. B C DDCC ACCEBFDBCAECE(BAF DCE D C #BD B !AAC D B CDDCCCADEE
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107
figure 6-11: Diagram showing the purely field of view for source toward detector plane (FD) and detector toward source plane (FS) as function of the collimator position (a: Source, H0; b: Center, H=B=(X-L)/2; c: Detector, B0). FS and FD arise respectively from the angles DS and SD. The symbols used to indicate the geometrical dimensions follow the notation introduced in figure 6-2.
D.ACCAABBABFAACDCFI93.BFD B C AEC E( B AF DCE D C CCACEEA B EEC ACC B FFECC AB D BCA DFCFABCCCBCACFCDBACFEDDCCA DFC D B EECE0. BCA ACECDC CEDDCC&FNV1!'ACABACBACFEDDCCA C A D BFABD B DFCBCB CAFBBCACFCDBACFECEFABAECBACBCBACFEDDCCDBACCABAF B FE F B CDDCC#BD.EBFBBDFCFNV1!FFECCEAC!ECBBDBCCCABDDCCDEEEEC.CAEFCDBBCAECE AF DCE D C CA AA EE D B FFCCFCDBACFEAFEA
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108
figure 6-12: Estimation of the detection efficiency as product of the detection solid angle D and the source field of view FS. Dashed lines: geometrical calculation of the detection efficiency <$> = D x FS. The collimator position reported on the x-axis is calculated as H+L/2. Dot symbols represent the simulated values of detection efficiency as reported in figure 6-10 and normalized to the geometrical value of D x FS. The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2. For all the simulations and calculations X=100 cm, S=1mm, T=1mm.
6.3.1.3 Influence of collimator tiles and slits dim ensions on the detection efficiency
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109
#BFA.AECEECBACDEFBDDCCC CABC"FBEEABA0.BAAEC.BECDEFBACEAEFCACEEACCECB!B
figure 6-13: Detection efficiency as function of the collimator slit and tile width (S,T). For all the simulations S=T. Three series of simulations are reported for different collimator depths (L). The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2. For all the simulations X=100 cm, H=0.
6.3.2 Influence of the collimator design on the spa tial resolution A EC. DFEE " C F B CE DD EEC EC B BCE ACE AEFC D ECAC ACFECA C BCB B )J%* BA A C AE ?CEAB@ AEE A A" AC AC AACDCFI3BECAFEB&,.ADCFI3'BA C D 4 I4 AA D 3 %C BAF CA AC CB A B D B . B EBCC C >FA EA B AEC D B D BAF94CBAAD9
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110
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111
6.3.2.1 Influence of the collimator position on the spatial resolution DCFI9ABBCDCEADBCDDAFEBA&.E4EI'CCBEECBAAECACEA3C$BCDBBDCEAABFAACE)J%*A.BCCBAABCBDB)J%* AE !'EE B C ACC CA B ECFCEACC D B CE AB #B B FA B CBDCFCFFCE CD944EECA+A"DACECCBDCBADEBCBDBC DCE * B ED D B AF. B EC A D BB DCEA. BCB ABFE A 8 . AECACFCABE. D BBAA. BACCD B DC CDECCAACABEAFACCACB!CFDK94<
figure 6-14: Detection profiles for three different linear source lengths (Q) 44 mm (red line), 50 mm (black line) and 56 mm (blue line). The fit curves are performed with the function y=a+b·erf(c(x-d)). In the inset are respectively reported the position of the source edge (Q/2) and the value of the fit parameter d with its absolute error. For all the simulations S=T=2 mm, D=2 mm, H=5 cm, L=20 cm, B=35 cm. The reported photon counts have been detected with a configuration equivalent to a ring of 100 collimated detectors. The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2.
DCFI9ICAEBFADBDCCDECCAECAB E AFACC D B EC AF EB ,C D4I4AAD3&BCBABBAFAEA94AAD9CBABDB'.CACBCDEFDBEECACCBACEAEFC.BCDDDCFCACBBEEC!'AD+EEACE
ABCDEACBFBCFDDDD
112
B AF. C E ACC AF A. BABAACEEACFE
figure 6-15: Detection profiles for linear source length (Q) varying from 40 mm to 60 mm by steps of 2 mm. The fit curves on the right edge are performed with the function y=a+b·erf(c(x-d)). In the inset are respectively reported the position of the source edge (Q/2) and the value of the fit parameter d with its absolute error. For all the simulations S=T=3 mm, D=1 mm, H=5 cm, L=20 cm, B=35 cm. The reported photon counts have been detected with a configuration equivalent to a ring of 100 collimated detectors. The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2.
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113
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114
figure 6-16: Curves of fit inflection point vs. source edge position for three collimator positions: toward the source side (top), central position (middle) and toward the detector side (bottom). The fit inflection point corresponds to the parameter d of the error function fit presented, for example, in figure 6-15. The reported fit points have been performed on photon detection profiles which have been acquired with a configuration equivalent to a ring of 100 collimated detectors. In the inset is reported the equation of the linear fit (red line) weighted on the error bars of the simulation results. There are also reported all the geometrical parameters of each configuration according to the notation introduced in figure 6-2. For all the simulations D=3 mm, X=60 cm.
*B.DBDCFCCBCBBEECCAEEABA&DCFI9I'.EBFBBEECAECCAEECACEBBCDCEA&AAD!ECDCFI9:'B
115
ACCAD B CDECCAC B DFC DC EE BA EE ECB B E AF ACCA . A EC. B DCFC A C DCF I9I . CB BEECEACECBEACCBA.B EA B A ACE AEFC 2F B B B. A AB CDCFI94.BDCFCCBBEECBAEA CA D B C DDCC D F K9< &D!D 'AD +E' BDCFCBBEECCAEEE#BD.BFEA C EC B EEC B A EBFB BCAAFEFAECDFBCACCA
figure 6-17: Detection profiles for linear source length (Q) varying from 40 mm to 60 mm by steps of 2 mm. The fit curves on the right edge are performed with the function y=a+b·erf(c(x-d)). In the inset are respectively reported the position of the source edge (Q/2) and the value of the fit parameter d with its absolute error. For all the simulations S=T=3 mm, D=1 mm, H=35 cm, L=20 cm, B=5 cm. The reported photon counts have been detected with a configuration equivalent to a ring of 100 collimated detectors. The notation used to indicate the geometrical dimensions follows the one introduced in figure 6-2.
6.3.2.2 Influence of crystal detector width on the spatial resolution ACFFCI3.BEACEAEFCDBECADFC D B B EECD B AEFC AEC.A DCA!CC.AAFFFE B CB D ACE )J%* AE BD BCA ACA D ACFECA D ECC CACC B CDEF D B CB B E ACE AEFC D B #BD. B ADCFC A C DCF I9I !!!9D EE:D !'AD +E BA F EC EE B EEC A FB F FC BACE)J%*CB 9#B AFEAD BA ACFECACDCFI9GBCCBECECCA
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116
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figure 6-18: Curve of fit inflection point vs. source edge position for the collimator placed in central position. The reported fit points have been performed on a photon detection profile which has been acquired with a configuration equivalent to a ring of 100 collimated detectors. In the inset is reported the equation of the linear fit (red line) weighted on the error bars of the simulation results. They are also reported all the geometrical parameter of each configuration according to the notation introduced in figure 6-2. For all the simulations X=60 cm.
6.3.2.3 Influence of the detection statistics on th e spatial resolution A EC B F D C BA D B EC AFAFF.BFDBFA.CACCEBCBBAECDEFBBDCBAEFADBDCAEEBACFECADCACBCDEFDBEECACBACEAEFCBCBBAADBCCBECAFCCDE4EW94E P&'BCBCA944CACABBECACDBACCEECDCB&E4EW948 P&''DCEADCACACEE&3I$'
117
A E C CAC B EC AF CC D BFCAFFCEACCD944EECACCEEACB BA C D B CCE AF CC (BEAA BCAAA E BBC DCFC. AC C C B !CFFDA.BEBCB .BCBBACEEECCBCFADI4 CAFK:E. DDFFECCEECC D B . C FE AECCE CAEE DFEE CDA F BC#BDDACADACFECACACBCDEFDBFDA. AFF B F D ACACA. BBCE ACE AEFC#BA AFEAA C DCFI9BBBADCFCDBACFECAACDCFI9I&EECE B AC !!!D 9EE' BA E;ACC BCA C E B FC ACACA FFC 94. 34 E4AA!.BBAEDBECDCBCAACDBCA F B DC 'ACB B CCCABC FFCE F DA B C (BEAA ACEE E EC D B DCCDECCBEAFACCCAACBE94FFCEAACEAEFCEDFKECAACEEBEBCBACBDAFBFACACA B D B DFC DC B B CDCEAEEABCCCEC;CEFADDADBDCDFC
6.3.3 Conclusions and perspectives ECCACADACFECABAD CAAAA BCDEFD BCCEADFECEECFEC CA C DDCC ACE AEFCEBFBBBACACCACEEECFEF EACA C CAC B B CCA D B CCCFECECACDBEECAA"DAFEDD.ACE.BDDCCACEAEFCDB
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118
figure 6-19: Curves of fit inflection point vs. source edge position for three different linear activities of the photon source. The reported fit points have been performed on photon detection profiles which have been acquired with a configuration equivalent to 10 (top), 20 (middle) and 50 (bottom) collimated detectors. In the inset is reported the equation of the linear fit (red line) weighted on the error bars of the simulation results. They geometrical parameters of the simulated camera are the same as in figure 6-16
%E CA D B CDEF D EEC AC B CDDCCBCBDFCBECFBCDCFACFECAACDCEE. CBAABB BCDDCC.A !. AA !CEE CB B CA D B EECBC"AAFCEAA.E.BEECACCCBABBAFECDDCCCA.CD
119
FK34<DEECBC"AA!CD+EKE<D!DCAD+E.BDF D B DCFC C BCB B EEC CA EE E C B AF B A #BCA BCF FE FFECCE!ECACCBCDDCCFDABFD BCECAECE(BAFDCEDC(BEAA CA EFCDB( . EAF . CA AA EE D B FFCC FC D BACFE AFEA BA EA AB B C B A B B C B AEC F B CECB CA A. B CDDCC ECE A &CC B EEC BC"AA CAFB'BCCDBDDCCBAECDCAEC EE B EECCACA $D$D.BCB CAFAFEECBECF&F344'.BACDC
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EACACBCDEFDBCACACABBCEACE AEFC "C B FFCE F D EECA E CE C F B EC AF D BA A!BACEAEFCACBBCCCABCFFCEFDAEBC(BEAAACEEEECDBDC CDECC B E AF ACC CA A D BDCFCACB 94 34 FFCE ABCBFE ACEE4G8 9I: D B3Q D B DFEE ;CFB%CBBABCBDE.AFBDCFCFEA!CFCFE !AC D EECA AD 9BCB FEBDAEECCCEB.AACEDCFCACEECABCDDCC.BFAAFF EA B ACE AEFC. FE AC CEEC &A DCF I9' DFAC B2" C BCA A BFE C B C CB F E B CD BCAED C (BEAA. A B FE AFE.CB CEEC C FE FAE ! BCC D DFAC!CDCAFB2"ACEAEFCDFK38CEAAFACECCEB
B C B C DDCC FE CA B BC"AA EBFB A CCAC ECCC F B CECCC D )J%* AEA &BCB CA " C F C BACFECAAAD'FAACBDDDBA C DDCC "F CA F )F(BEAA.EBFBEEBACFECABDCBAE BC"AA D EE D AC CA &ACEE A C BCA "' D B !CE AFEA C CB B FEC!CABCBCFAB.BCAACEEACCABAEBC"AA
EA. BA ECC ACFECA CEE B FAF ACFECACBCBBCDEFDEEBCEAAB FE CAC CB E AAC AF BCDEFD BEC!CE DCEC DBCCCBCABA"CFACFA!EFB BCE ACE AEFC +FB. ECAC EC BDCEABFACADBFEECAFDBCBBBCAACFEA;FACBAFAFCEC CCCA AE BA C D A CEA B 2" B A D B F DBACDB2"BA E CDEFBCCDBCE
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121
7 Summary and outlook
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D CD CD BCA CD A BBC BCACCD D D BDDBE EA EE E DDCD CC C BBEDCD CCC BE D C DE CDADCDDCEDEAEEDCBCDCDADCDDBADCADC C C BEA A CE D DCEA
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ABCAAD
122
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123
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124
8 Appendix
8.1 NaI(Tl) calibration for beam intensity monitoring ABCDE ABFBD FCC D CEC EDCBECCBCECCDBABCEFBDBCBBC CBABABC D CEC B CAF B AECC CDC!CEBECBC"B A#"$$CCEABF EB D DCB EED F $ ABCD % C BD CEB B FBD D C! E DA C &'( B BAB FB E F D C'BABCD BE FB ECCB BFBD BB % E AB%C "B A #"$$!) BDC FB#*+'CED BBF(BBEAE(!,$-(,.CE/E!
NaI Monitor [Hz] CF44 [nA] Ions/s
20 0,0 ± 0,5 0,00E+00 ± 5,2E+08
330 0,3 ± 0,5 3,13E+08 ± 5,2E+08
910 1,0 ± 0,5 1,04E+09 ± 5,2E+08
650 0,8 ± 0,5 8,33E+08 ± 5,2E+08
1600 2,0 ± 0,5 2,08E+09 ± 5,2E+08
2400 3,0 ± 0,5 3,13E+09 ± 5,2E+08
2900 3,8 ± 0,5 3,96E+09 ± 5,2E+08
3600 4,2 ± 0,5 4,38E+09 ± 5,2E+08
1430 1,9 ± 0,5 1,98E+09 ± 5,2E+08
2200 2,7 ± 0,5 2,81E+09 ± 5,2E+08
Table 8-1: Detected count rates for the NaI(Tl) detector used to monitor the beam intensity. Reference beam current values are given by the Faraday cup (CF44) (for C6+ 1 nA 109 ions/s).
ECFC B&'(FCFABEC&'(EECBCDCEC BEECCB A D BBE F 0! 1 BC ABCDE D BBEE (CBBACDC2B CBEC%CCAC' AFFEDCCDC2C'CD!
125
figure 8-1: Beam intensity as function of the count rates detected by NaI(Tl) monitor detector. A good linearity is observed up to beam intensities of ~5 nA. The error bars are due to the sensitivity of the Faraday cup (0.5 nA).
8.2 Electronics and acquisition set-up "BABCDE BEB CDBCEBC CEEABFBD C %C 3 BCE 435 6 CECCEED! FC B ABE 7 CBDE F ECABEECEDCE!
8.2.1 GANIL single-detector experiment EC'B ABCD B ECCBE 8"9 8#0,( BCB6 CECCABFBDB A7EEC CC %BB 1# B CBC CC%BB :1#! 7 CBD F ECE ABEEC EDC CEABE C FC B &'9! E EBC C AB%C E ABBA ECCB E E DCB D CEC C 7B %E C C B ABABC D BB! C F EC ECCB E F BCBC BE E BB B B 435 EBD E BEAB D F 7B %E! CE AB%C B DECACFBDCCAC%CBDCECABDECF BE F CEBCDCB 1CEBC EC %BCE BC ABCD!%BEE DCCDC2 6 CECC 'CD DA C%CEBD 1C%CEBCEC2CFBCBECE!BCB E B% EBABEDA C&'(B C%C% ECDE CBC FBD BBF(.(%E/EBBB6 CECCC!
126
figure 8-2: Block diagram of the signals processing schematic for GANIL single -detector experiment.
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88"98#0,(ECEBEAC>?ABEEFBDAC BC!EEBCCBDE BDE ECDA ABFBD CB DACFCC DAC F BEECE E EEC% F C 1#! EC ABEEC FB B CE DB DAC! >C FB ?>1 ED EC E CB %B CFFB E C E F 8#0,( 5 1 F ,, E ECF 0 E E FC B 0'0 % BCB BEC!;BCEF8"9BEB 0,E 0,,E5>ECEFCBEDACFCCFEDACFCBDAC"ECCFFA EEAB'EAC!ECCB%BE C F BBABEEEABFBDEC CB %B EB ! CE ABC B EC ABEEC EAC%B?>1ABFBDE!
127
8.2.2 GSI single-detector experiment 7CBDF ECEABEECEDC FB> EC'BABCD ABE C FC B &' CE DE CC E ABE % A FB ;" EA EC C C CE E EAB%C AEC ECCBE ? (9 CBAC D! EECCBEBE EDE BCB DBFCECCB BFB CB B E CB 435 EBD ! AEC ECCBE FFCC E 7 DABC ECCCCDEF =(,,@ AF(,0CE/E!
figure 8-3: Block diagram of the signals processing schematic for GSI single-detector experiment.
8.2.3 GANIL multi-detector experiment D C'B ABCD FC% A>; ECCBE A>; ('0 B E BCB 6 CECC ABFBDB A7EECCC%BB1#!7CBDF ECE ABEEC EDC CE ABE C FC B &'$!E FB EC'BABCDE EDCBDCECCEECABEECECCABECEC,!
128
figure 8-4: Block diagram of the signals processing schematic for GANIL multi-detector experiment.
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129
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