Calculation ofthe Effective StoppingPower ofIons Generated by...
Transcript of Calculation ofthe Effective StoppingPower ofIons Generated by...
Pertanika 15(1), 55-59 (1992)
Calculation of the Effective Stopping Powerof Ions Generated by Neutrons in Tissue Constituents
ELIAS SAlONDepartment ofPhysics
Faculty ofScience and Environmental StudiesUniversiti Pertanian Malaysia
43400 UPM Serdang, Selangor Darul Ehsan, Malaysia
D.E. WAITDirector and Safety Advisor
Environmental Health and Safety ServicesUniversity ofSt. Andrews
St. Andrews, Fife, KY16 9TS, United Kingdom
Key words: stopping powers, heavy charged particles, Ziegler's universal screening length.
ABSTRAK
K.ertas ini rnelaporkan pengiraan kuasa penghenti zarah-zarah bercas berat yang tersentak oleh neutron dalam empatunsur kandungan tisu bagi tenaga zarah daripada 0.1 keY hingga 1.0 MeV. Pada tenaga rendah kurang daripada 30keVj amu yang mana proses penghenti nukleus lebih berperanan daripada proses penghenti elektron, nilai kuasa penghentiberkesan lebih tinggi daripada nilai pendekatan perlambatan selanjarnya (PPS). Sisihan di antara kedua-dua nilai inibergantung kepada jisim sasaran dan juga tenaga serta jisim zarah.
ABSTRACT
This paper reports the calculation of stopping powers of heavy charged particles generated by neutrons in four-elementtissue constituents for particle energies from 0.1 keY to 1.0 MeV. At low projectile energies of less than 30 keVjamu wherethe nuclear stopping phenomenon is more dominant than the electronic stopping phenomenon, the effective stoppingpowervalues are higher than the continuous slowing-down approximation (CSDA) values, from which the deviation is dependentupon the target mass and the energy and mass of the projectiles.
INTRODUCTION
Knowledge of stopping powers and projectedranges of low-energy secondary charged particlesis very important for accurate prediction of energy deposition by intermediate energy neutronsin tissue (AI-Affan et ai. 1984). Intermediate energy neutrons slow down in tissue matter to generate short-range heavy charged particle recoilswhich have ranges less than the cellular dimensionof most mammalian cells. The radiation quality ofthese neutrons, however, is not fully defined forradiation protection purposes although chargedparticles generated by these neutrons are knownto be capable of producing biological effects (lungand Zimmer 1966; AI-Kazwini et al. 1988). Somehave reported an increase in the radiobiological
effectiveness (RBE) of intermediate energy neutrons of energies less than 100 keY (Key 1971;Mill 1986).
The penetration of charged particles throughmatter is a complex phenomenon which can bemeasured in terms of stopping power and projected ranges. In the region where projectile velocities, v, are greater than the electronic orbitalvelocity, Vo (= 21te2j h = 25 keYjamul the pathlength of ions in matter is a straight line. However, in the low energy region, i.e. v < vo' thepathlength is no longer a straight line but a complex form (Cook et al. 1953) due to various interaction processes such as elastic collision with thetarget atom, inelastic collision with electrons,charge exchange and chemical binding effects. Ingeneral, there is competition between the loss of
PERTANlKA VOL. 15 NO.1, 1992 55
ELIAS SAlON & D.E. WATT
where Sn and Se are reduced nuclear and electronic stopping power respectively. The reducednuclear stopping power is given by Ziegler inequations (5) and (6) for low and high energyions respectively.
(4)
(2)f(x) = 0.021 [In (m/m)F-
, J
0.1434 [In (m/m)] + 0.3642• J
Ziegler et al. (1985) introduced a new universal screening length, a, = 0.8854a/ (ZiO.23 + zt23
) ,
Where Z and Z are the atomic number of recoil, J
ion type i and target atom type j respectively. Thecorresponding screening function produces a tightgrouping with a standard deviation of 18%, betterthan the one derived from a well-known Lindhard's screening length, aL = 0.8854a/ (Zi2/3 +Z.2/3) 1/2, which has standard deviation of 40%. They
Jfound that their fitting universal screening func-tion is in good agreement with the experimentaldata within 5% of the standard deviation. The re-
duced energy, cz
' for ions of energy E (keY), in
terms of Ziegler's screening length is given by
32.53rn j E£ = --------"--------- (3
z Z.Z.(rn.+rn.)(ZO.25+ Z?25) )I J ' J 1 J
The total stopping power is the sum of the nuclear and electronic stopping powers expressed interms of Ziegler's reduced energy by
. 8.462 x 10-15 ZjZjmj'S·(E)= x
J (m j + m j ) (Z~·25 + Zj25)
[Sn (Ez ) + Se (Ez )]
is given as
MATERIALS AND METHODS
energy of charged particles to electrons and torecoil particles (Lindhard and Scharff 1961). Theparticles undergo successive small angle scattering known as multiple scattering which may produce recoils deflected in the direction inside themedium, increasing the stopping cross section peratom. The scattering angle becomes larger as theparticle energy decreases. The particles travel in azig-zag path which partly explains the differencebetween the projected range and path length ofions at low energies. The difference is very significant at energies where quasi-elastic scattering becomes dominant (Watt 1972).
The projected range is an average thicknessof material traversed by a number of particles directed perpendicular to the material surface. Theeffective stopping power is the energy loss per unitlength along this projected range. For low energyions the effective stopping power value is greaterthan the continuous slowing down approximation(CSDA) value because of the significant importance of elastic scattering collisions with nuclei ofthe target materials and range of straggling. Inthe region where nuclear stopping becomes moredominant than electronic stopping, and experimental stopping-power data is lacking, the stopping process of charged particles in matter is notfully understood and here, -an attempt is made toinclude the effective nuclear stopping in the general stopping power formula. However, for ions athigh energies, the effective stopping power willbe the same as the CSDA stopping power becausethe loss of energy there is mainly due to collisionswith atomic electrons.
Calculation ofEffective Stopping Power
The effective stopping power, is/if (E), can be determined according to Watt and Sutcliffe (1972)in a manner similar to that adopted by Al-Mfan etal. (1984).
Sn(cJ_ In (1 + 1.1383 E z )
- 2[cz +0.01321E~·21226 + 0.19593°·5]
for Ez S; 30 keY/amu
(5)
Se(E,)
(1)
where E is the energy of the recoil particle, 'S/ (E)and ise (E) are the nuclear and electronic stopping powers of recoil particle type i in the atom
typej respectively. "(2 = 4 m; mj / (m; + m)2 with m;
and m being masses of particle i and target j respectiJely. f(x) is the function which converts theeffective stopping power of nuclear stopping and
In (E z )Sn (Ez)=-2-- for Cz > 30 keV/amu (6)
Cz
The corresponding reduced electronic stoppingpower can be expressed accordingly in terms ofZiegler's screening length by
)
3127.93 x10-2 Z2/3 z1I2 (m. + m. £112
I J 1 J z
(Note the occurrence of Z-<l·23 replacing Z·1/3 in the
56 PERTAN1KA. VOL. 15 NO. I, 1992
CALCUlATION OF THE EFFECTIVE STOPPING POWER OF IONS
10 '
o
N
10 '10 I
CARBON
-±--........--"t--=---c-=_"""""-; •• .. leW
10 '
x 0.01
10 'L'_~~~",,-~~~,",",,",,--~~~uL-~~~""""'"
10-1
PROJECT ILE ENERGY (kaV)
Fig. 1: The calculated effective and CSDA values of stoppingpowers for heavy ions (proton, C, Nand 0) in hydrogen
10 10
HYDROGEN
D10 '
>< 0.01 +- +
NNI
EUm'- ...>Ql
-"
C0: 10 7
ll.J::> ...0 + -0..
~~t.:JZ
>-'~ 10 •0..0..
~,eff0l-- csda([)
Rayno ld8 8' .1. () 9531•10 '
0 Fakuda 119821Vay I 11953)Oldenburg end 800z 119721
NX 0.1I
E - - - - - .-. • •u 10 7m ..
"- ••>• COJ
-t#_'f-~~-"
I I0: 10 ' :t---""'~ - - - - .J .. }-a=' ~ll.J
~M~::>00..
t.:J ....-Z a10'
~ .. ~ 0__Seff I - - - Scsda0..
0.. A Reyno ldo a' "l. 1195310 · Ph'llips 119531l--([) 0 \II) nS8arden & Duck.... orth 11962)
0 Sa, Arkhlpov and Gatt 119691
10 •SntSe, Arkhl pov Qnd Gatt (J969)Noorhoed (19651· Ormrod and Duck.....orth (19631· Hogb8rg 11971)· Fa8'rup 0' al. (19661
... Oldenburg and B002 11972110 J
10-110' 10 I 10' 10 J
the projectile energy increases. Also, the deviation for a given target decreases with the mass ofthe projectile. The deviation is largest for protons
PROJECTILE ENERGY (kaV)
Fig. 2: The calculated effective and CSDA values of stoppingpowers for heavy ions (proton, C, Nand 0) in carbon
RESULTS AND DISCUSSION
expression given by Watt and Sutcliffe (1972)).In the high energy region, however, the con
tribution from nuclear stopping is very small andcan be neglected. Therefore, one needs to consider only the electronic stopping power and thiscan be calculated according to the Bethe formulaor by Ziegler's code (1985). The latter has beenadopted in this work.
The effective stopping powers of heavy recoilions (i.e. protons, C, N, 0) in tissue constituents(i.e. hydrogen, carbon, nitrogen and oxygen) havebeen determined. Except for recoil protons, theCSDA nuclear stopping power for C, Nand 0ions was calculated according to equations (5),(6) and the first term of equation (4). The electronic stopping powers of energies of less than 30keY/amu were calculated according to equation(7) and the second term of equation (4). Thechoice of energy cut off corresponds to the ionvelocity of about 2.25 x 106 m s". The electronicstopping powers for ions in the high energy region were calculated according to Ziegler's code.Normalization was performed to connect smoothlythe stopping power values below 30 keY/amu toZiegler's stopping powers for every ion interacting on each target.
For protons in four-element tissue constituents, the CSDA stopping powers were obtained byfitting data of the International Committee onRadiation Units and Measurements (ICRU)(Berger 1986), for energies from 1 keY to 20 MeV.The fitting results produced deviation of less than1%. Consequently, the effective stopping powerof ions in four-element tissue constituen ts was calculated according to equation (1).
The effective and CSDA stopping power valuescalculated for recoil ions of energy from 0.1 keVto 1 MeV in hydrogen, carbon, nitrogen and oxygen are shown in Figs. 1, 2, 3 and 4 respectively.The effective and CSDA stopping power valuesare indicated by S If (solid lines) and S d (brokenlines) respectively~ For nitrogen and o~;gen ions,the values have been multiplied by factors of 10and 100 respectively for graphic purposes only.The results are compared with published experimental data as indicated on each figure. Thetheoretical calculations of Oldenburg and Booz(1972) are also shown.
The effective stopping power values, as expected, are higher than the CSDA stopping powervalues. As we can see from the figures, the deviation at the low energy region for a given recoilincreases with the target mass and decreases as
PERTANIKA VOL. 15 NO.1, 1992 57
ELIAS SAlON & D.E. WAIT
PROJECTILE ENERGY (keV)Fig. 3: The calculated effective and CSDA values of stoppingp01ll"rs for heavy ions (proton, C, Nand 0) in nitrogen
10' r-~~~.,.,.,...-~~~~~~~TTTT-~~~'"'1
The effective stopping power is higher than theCSDA stopping power for low energy ions due toin teraction of particles through nuclear elasticscattering. The deviation for a given particle increases with the target mass and decreases with anincrease in the projectile energy. For a given target, it decreases with the mass of the particle. Theresults can be used to predict the quality of intermediate energy neutrons which could show thepossibility that elastic nuclear collisions playa significant role in determining an increase in RBEfor these neutrons.
CONCLUSION
COIllponent.The experimental stopping power data for
recoil ions of low energies are generally lower thanthe present calculations due to the fact that themeasurements were performed for electronicstopping powers. In one case when the calculatednuclear components were added to the experimental data of Arkhipov and Gott (1969), the results were consistent with the present calculationas shown in Fig. 2, for proton in carbon. Nevertheless, experimental data for most heavy ions inthe low-energy region are scarce and are not sufficient to test the theoretical calculations. Thepresent calculations consider the contributionfrom the effective nuclear stopping power whichis otherwise not included in the experiments. Ourresults suggest the need to study the contributionof effective nuclear elastic scattering in the penetration of charged particles in hydrogen, carbon,nitrogen and oxygen, from which the effectivestopping powers and projected ranges can be calculated. Accordingly, the effective stopping powerand projected ranges in tissue and tissue equivalent (TE) materials can then be extracted in therecommended manner. Both quantities are important in the determination of microdose spectra and quality of intermediate energy neutronsin the simulated tissue volume of Tissue Equivalent Proportional Counter (TEPC).
o
o
OXYGEN
NITROGEN
x 0.01
10 •
NI
X O. IE0 10
7 - - - - - - -em
"-> CQJ
-'"
cr: 10 •w H::>0[l.
tel +-z10 ' -" -~ Seff
[l.Scsda[l.
0f- A Royno ld. ot .l. (1953)Ul . Phillips (19531
m F.kud. (1982)10 ' + Oldenburg end B002 119721
10 •
N
"ix 0.1 -pe ri:PE
0 107 00
m"-> Crn-'" +
cr: 10' - - - - - -IIIIt1BIlI
W.
H::>0 -+[l. l'-tel - +z
ID' .- Setf[l. -.- 5[l. csda0
Royno ld. 0' ol. 11953)f- AUl . Phillips (19531
0 Fakud. (1980110' 0 Fakud. 119811
+ Oldenburg end 8002 (1972)
10'
10-1 10 ' 10 I 10 7 10 '
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CALCULATION OF THE EFFECTIVE STOPPI:NG POWER OF IONS
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(Received 18January 1991)
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