A model for the altitude dependence of the hot plasma parameters responsible for the electrostatic charging of spacecraft was developed. Based upon plasma orbit theory, the directed velocity is a function of the ambient magnetic field flux density. A consequence of this approach is that while the thermal velocity distributions (assumed to be Maxwellian) of the plasma particles are independent of the magnetic field strength (and hence altitude), the particle densities increase with magnetic field strength. Thus, according to this model, while the equilibrium voltage is independent of altitude, the charging current density increases with decreasing altitude. However, the probability of such spacecraft charging decreases with decreasing altitude

Haffner, J. W.

English

NASA Technical Reports Server

/_6_t6
I, Intz'odUction 287
2. Altg.udt_Depefitlence 288
3. Model.ling 2gl
4. Char_Ing Parameters 293
References 2g_
4. An Altitude-Dependent Spacecraft
Charging Model
: J.W. Haffner
RockwellInternationalCorporation
SpaceDivision
Downey,Caiif_mie
Abstract
A model For thealtitudedependence of thehot plasma parameters responsible
for theelectrostatlcharging Ot_pacec_aR has been developed. Based upon plasma
plasma orbittheory,thedirectedcel_cltyisa functionof theambient magnetic
: fieldflukdensity. A consequettceof _ntsapproach isthatWhile thethern_alvelo-
citytl[stributtons(aSsumed tobe Maxweliian)of theplasma particlesare md_pend-
entof the magnetic tieidstrength(andhettcealtitttde)0theparticled" ,stilesin-
crease with magnetic fleldstrength. ThU_, accordingtothismbdel, While the
equilibriumvoltaireIsindependentOfaltitude,thecharging currentdensityincreases_ith decreasingaltitude.However, theprobabilityof such sp._,_e_raft
chargingdecreases withdecreasln_altitude.
i. INTRODUCTION
--}
Almost a',l og th_ pUblished dat/_ and analys_s ol spacecralt char_ing 1' 2 hage
_ b_en concerned _vlth spaeec_'viR in g_osyn6hronbtss orbit (i- = 6.6 RI_). it is
" theor_t4.eaiiy expected that the cimrging pheriomeii6n can occur at other aitiiudes
00000004
https://ntrs.nasa.gov/search.jsp?R=19780002204 2020-03-20T12:39:32+00:00Z
:i, 4 ! t . I '• " [ I ., I !
i •
r) /
_ t
,._ as well. Far spacecraft tn e_trth orbh at other altlt_ldes0 the characteristics of
_=_ such charging becomes of p_acttcal concern. Tll_ ptlrpose ot this study was to
: :_.:, develop an analytical model Which yielOed the significant parameter_ _£ the space-
cratt Charging phenomenon as tunctlons of altitude above the earth.
::!i!
.... 2. ALT|TIIDE DEPEndEnCE
!_.3' tI
_:;::_:: The major environment which has a strong altitude dependertce at geosynehro-
-_, nous orbit is the earth,s maAmetic field. If thi_ field is taken as approximately
=i'0 that Of a dipole, it_ magnetic flux density may be written
/
B + 3 sin 2 kM
.. where.
B = the magnetic flux density at the surfac@ of the earth at the magtletic
._ etltmtor = 0.3 gauss = 3 × 10 -5 webet's/m2_
i _' XM = the magvetic latittitle (degrees);
• r = dlstan_efrom themagnetic centerof the earth;
-- "v
!, It is necessary l_or r anti R E to be in the same units, and that r >.R E.
i:':* Itis Welt known that a plasma can exist in a mag_letie fieltionly ifthe plasma
! _i'._ energy tiensity exCeedS the magn_tic fielti energy den_tty. The energy density
I_ (E. D,) of thequasistaticmagnetic fieldisB2/2_, where _ isthe permeabilityot
_-°,-. the mediutn Which containsthemagnetic field.FOr freespace _ --/_o 4._X i0"7
2_.: H/m (MKS units). Thus tar the dipole-appt, oximated geomagnetic ftelti,
"_ Bo2 (1 + 3 sin _"_.M)
': E.D. =
2"o RE
,:_' 1 + 3 sln2
21;_ : a.58 X*O "4 . 1_1
J-
.2_-. !
6/
= -_a:!
_'_ Ahy plasma which isableto existinsuch a ma_letlc fieldmust p0_sess an enet'_y
.._ densityat leastthi_ large.
:_::_ The energy det_sltyof a two-component electricallyneutralfullyionizedrlon_
_ \ˆ relativisticplasma may be wHtteh
_ E.D. = KE (directed}+ KE (thermal} (31
--:o;: p .,
-[i where 1
....:_, KE (directed)_ I/2 (m+ + rn )v (dlr)2
ICE (!,hernial} = 1/2 m+ V+ (th) 2 + 1/2 m v (th) 2,N .... "
Itltheseequations,m+ and m_ are the restmasses of the posltivelychar_ed arid
.._,'," negati,telycharged plasma particles;respectively,while v(dir)and v(th)are the
_}.:i_; dlredted and the thermal velocities of those particles... N is the spatial density of
._:_: each type of partlcie. As Tong as th_ plasma moves as an entity, the + and - par-
_:_.:: ticles#villhave the same directedvelocities.Inaddition,iftheplasma isin
_. thermal equilibrium,the + and - particleswillhave the same aver'agethermal
energies,leadingtothe relatibnship
v.(th)
!2:!_. v+(th) (4}
This lastrelatlot_shipsonlyan approximation,as measurements in thehot plasmas
responsibleforspacecraftchsrg[ngseem toshow thatthe temperatures ot the
+ component (largelyprotonS)are abouttwice thetemperatures ofthe - component
(eleetrbns).
The characteristicsofthehot (spaceCraftcharging}plasmas atgeosynchronous
/' orbitshin#thatthedirectedvelocitygenerallyliesbetween thethermal velocities
:" otthe electronsdnd the pi'otons.Thus, the directedvelocityis supel-sonicforthe
protonsbtltsubsonicfor theelf.ctr0ns.Sin_e m+ _ 1836 m., theea_rgy density
forsuch plhsrnt_isessentia!iyalldue tothe dix'ectedmotion ofthe protons. To
illtlstratehis° 10ora pias._na _Olth a 5 keV temperature v+(th) _ 108 cm/sec while
V (th) = 4.3 X 10 9 cni/sec. Takitt_ vldl_} as 6 × i0 8 cni/sec (an lntei'mediate
_P.I:!' Value}yieldsdirectedenergiesof E+ = 180 keV and E. = 0,i ke_¢, Only t_vldlr}
_i__I_
_._: is not greati_" tltaxi v+(th} is the plasnia energy density not lai-_ly due to the
_ directed motion of the heaviei. {+) cotnponent.
_i _ With E. I).p = i/2 m+ v{dl_'} 2, it is possible to estlniate how low lri altitude a
• 6P_
_',t hot plasnivi moving radially toward the earth can get befoz-e its ehergy density is
.... _ 289
,o '!,
a
00000004-TSA04
not sufftcietlt to prevet_t the geoma_netiV field _rom tearing it apart. Equating
E. D. B and E. D. p yleid_
z'_ RE . _-- (5-) ::
! ao m+N i
The results of this calculation are showlt graphically ir_Figure 1 tot kM - 0°
(magn_.tic equator). Th_se results are an approximation because of many factors,
but due to the steep radial gradient of the energy density of the geomagnetic field,
0t
,_ 8 x IO8
_' I-_... _ Z_-HOUR
!
0 I I . .i. i .I I I i || I i |, I I | | i
|0-I I |0
PARti CLEDENSI ?Y (PROTDN'S/CH_I)
FigUre 1, CalcUlated Hot Plasma Aitltdde Lltnlt
29O
00000004-TSA05
o!,!
i'ii_ the approxirfiatlOns p_oduce only _elattvely sn_all perturbations in the _'esults. It
.....i;',i is seen that a modet-ately denge 1> 10 partiCles/era 3) plasma wlfh a Peasofiably
_i_?, large directed velocity (_ 3 × l0 8 cm/sec) can reach the 12 hr ciPcular 6rbit
'_!i (r _ 4.15 RE), while an increase in either" pat_ttcle density o_ directed velocity
:_ _,
Ii.... can resultInspacecraftchargifl_at eCen lower altRtidearthorbits
*_i There are vaelousal_pro_imateways of modeling a plasma to make plasma
_, problems mathetnatically tractable, Each model deals with that portion of plasma
:ii:i properties which are most pertinent to the problem at hand while st_ppr_ssing orignoring le_s relevant properties. Plasma orbit theory is among those approximate
_. models oftenused insituationsinwhich the motions of individualplasma partiele_
_ are important (Hydrodyna_dc theoryis oftenused for situationsinwhich large
Scale plasma oscillatiorls are more important than individual particle motion. )
The basis oforbittheoryisthe ConservatiCmofthe angularmomentum ot individual
t.. particlesabout an axis(totexample the directionof themagnetic fluxlines)
_ Motion ot theplasma particlesparalleltothe linesofmagnetic fluxisnot affected
(to a first approximation). Thus, it is possible to separate the thermal and the
i directedmotions of the plasma particlesby cons|de itlgthem tobe paralleland
i perpendiculartothemagnetic fleld respectively This simpllfl_dmodel results
i ina decrease inthe directedvelocltyas the distancefrom the earthdecreases I
(for example, as the magnetic field strength increases) while leavitlg the thermal I
velocityunchanged itisobviousthatthismodel neglectsthe compresslonai ?
;, lieating Of the plasma, which certainly is a major factor in the production of the hot ':
plasma in the firstplace However attemptsto incorporatecomp_ essionalheat I
_: ing resulted in a model in which the plasma energy density increases as rapidly
......i aS the geomagnetic fieldenergy density withthe consequetce thata plasma ableto
°! exist at any altitude could thet_retieally reaCl_ any other flower) altitude. This is
clearlyat variance_Ithobservationaldata (spacecraft charging anomalies have
"'. not been reported ior low-altitutte ea_-th orbtts}.
_,i Based upon the simplified application ot plasma orbit thet_ry, it is possible
t, to write
_ v{dir} _th cos a (6)
......::" whe_'e _ is the pitch angle (angle between the velocity vector at_d th_ dii'ectiofl of
-_; the gebmagnettc fleld). This is simi|ai" to the equation of motion fo_" Van Allen b_It
' particles. The second invai'lant for such particles leads to the relationship
..... _ ...... ., o .. ,, _ o _ ,_o
00000004-TSA06
According to thi_ model the average particle thermal Velocity (plasma tempera-
ture) does not change _ith altitUde while the directed vel0city gradually decreases,
reaching _ero when B -- Bma x. At that point, the plasma energy density has been
reduced to the energy density of the geomagnetic field.
The negative voltage to which a body immersed in a plasma of a given tempera-
ture will change is ~3.76 times the average electron kinetic energy (Eo) in electron
° :i
,_ Volts. The negative voltage is due tO the tact that the electrons have much higher
thermal velocities than the protons, and therefore impact the spacecraft surface
!_°I:
i ,_!i: much more often.
The factor Of 3.76 iS due to the fact that the negative current to an unillum{-
! __ flatedspacecraft _urfaCe varies exponentially with spacecraft voltage (to a f_rst
_"_i apprOxitnation) _vhile the positive current v_trtes linearly _/tthvoltage. Ttiis is a
_i:_i, consequetlce of the ta_t that the electron motiorti_ subsonic while the protoh motion
_. ts__upersonic. Mathematically,
"_' V
°iii" J+ = Jop + (9)
o
ii a.:joee"v/v°e _10)
_'_I ' v_herej+ an_J arethesurfacecurrenttiensltiesas a functlonor_pacec_aft
_- voltage(V),andJoe antlJop are thosecurrentdensities{includingtheeffectso_
o_ energte_ in electron Volts, reSpeCtively. Sinc_ m+ = t836 m., Joe = _1836 Jop
"'t__' = 42.8 Jop' The value o_ V will increase until J+ = J , assuming rio electrical
diScltaeges tare place. Eqtiatin_ J+ to J and solvir_g for V ytt_ltis
oo
oi_ ;
_,:_: V -_Vo 3.7_+ _n _ v°p+ _< 3,76 Voe . lit)
, .;. Since the secondary curi-_iit components Vary with spacecraR voltage differently
_ : _hari the prifiiary currents do, fli[s factor of _. 76 carl be appreciably diff_r_rR iti
_-_:_ ma_iy situatibfls. Howevei-o siiice tiie psi'ticies _esponsible for the cliarging flare
i-_0:i 292
°,,.!-
00000004-TSA07
an appP0xtrnatel_Maxwelliaflenergy dl._tributi0n,itisunderstafldabl0thata plasma
with an averaUe electron ternperatrre of Voe (volts) _10UI_ e _a _ge a spacecraft to
voltagesV > Voe.
4. CW,_RGiNG-PARA_IETERS
Since,accordingto thismodel, the particlethermal Velocitle._are unchanged _.
by the directedmotion ot theplasma tO#ard theearth,the equilibrlUmVoltage
__ which a spacecraft surface _#ill reach in the plasma will not depend upon altitude.
In the absende of electrical discharges, a spacecraft in a i2 hr clrcular orbit
(r _ 4.15 RE} wiU '.herefore theoreti_ally charge to the same potential as one in
a 24 hr geosynchronous orbit (r = 6.6 RE}. HoweVer, the am'face current densi-
ties (which determine how fa._t the spacecraR will charge} will be a function of
: altitude.The Initialprimary surfacecurrenttlensityas a functionof altitudemay
i be estimatedby cal_ulatingthe llmitin_plasma particledensityofthe plasma jtmt
as itsdirectedmotion has ceased. Sincethe average partlcleenergy (and the
particle energy distribution) remains UnChanged aCCording to this model, the par-
: ticle density mu_t increase linearly _ith the energy density Of the geomagnetic tield.
The dalculated n'umbers derived b_sed upon this model are sliown in TaBle 1.
_ At each altitude_" th_ average _nergy densityof the geotnagi_eticfi_Id(dipol_
approximation}was taken as the average thermal energy densityof a stationary
plasma at thataltitt_de.A_sumlng halfOf thisthermal energy densitywas due to
the ele_t_'ons,the product_ • N was obtained. For each value oflimitingspace-
craftpotentialV, theaverage electronenergy was obtainedby dividingby 3.76.
_ The electrondensity(era"3)was thequotientof _. • N dividedby Ee (E -E here}._; - - e
-_'" The initial pi'in_af.y electro_ trent density (J_) was obtained trom the equation
_ J. :N ' q. 9 . (i2)
_i The resultslistedin Table 1 are also shown _ravhlcallyinFigure 2, Itis
seen thatthe caiaulatetlinitialcurrentdensityihCreasesrapidlyas orbitaltltud_
decreases. This altitudedepefideticedecreases theimpoi'tanceof thephotoelectric
-_ currerit density (_vht_h has an altitude-independent value < 1 nA/cm 2) at lower
,i: altitudes. Another consequence of this altit._de dependence is that it the spacecraft
: surface _afinot withstand the equtltbrlt_m potential to _htch the plasma can charge
.?
it,the i-ateat _#hlcliel_ctricalbi-_akdowhs(discharges}occur willbe much greater
- at lower altitudes,
While the calculated surface current densities are larger at low altitudes thah
o at geosyiichronous altitude, the probability that a spacecraft will encounter the hot
,i,
293
00000004-TSA08
! • I ! ¢ ! ! I
I
_)-,i_ i'' " I " n T r T _ I[ ........... . "[ | _'_I ........ I '
! ,
' : _.99 key _= 5.32 key _e" 6.65 ke_o,: • N. _e" 1._i:_k_V e Z.6e k_v e
:_ .;_ kE _,..,'c= j) _ - 4.3x101 6.0_lxlO_ _ - 7.65x109 _ - 0.6x10 _ _ , 9.62x10_
_! 6.6 6.5 dl. 4.89 2.44 1.63 1.22 0.97
(24 hr) 3. - 3.36 2.38 1.94 1.68 1.50
i :(" 6 12.S S. - 9.40 6.70 3.13 2.35 1.88
i ,: J. - 6.47 4.57 3.74 3.23 2.8"_
2?
; i : 5.5 20 N. - 1._.0 7.52 5.00 3.76 3.01 _-
i;_- ,/. - 10.35 7.30 5.96 5.17 4.63
i: 5 36 N. - 21.J. 13.5 9.00 6.80 5.40
J. • 18.6 13.2 10.7 9.29 8._il
i _, 4.S 67.5 _. - 50.8 25.4 16.9 12.7 10.2
io;__' J_ - 34.9 24.1 20.1 17._; 15.6
il 4.15 110 N.- 8Z.7 41.4 27.6 20.7 16.6, 0,2 hz') ,,,i'_- $6 8 60.2 32.8 8.S 25..5
;_ 3.5 313 L__- 235.0 117.5 78.3 .58.8 47.0
J_- 161._ 114.3 93.3 80.8 72.3
i_:: v J.n,_mJe_.i Ill. J._p&rtJ._les/cms; J_ J._ nampeicm2.
fill
Table I. Calculated P_z-ttele Dettsttieg _nd inltlal Pt'Imary Current Densitie_ _s
_._ Functions of Altitude (XM = 0 °)
....)" ple.dma at these lower altitudes is appreciably lesS. I_ would be theoretically
_i_:' possible to ealculi_te an altitude-dependent probabillty it data Were available con-
o_
i °} cernin_ the p_'obability Ot en_otmterlng a given plasma energy density at _eosyn-
_ chron0us altitude. _uch data are becoming available. However, the measured
L-dependence o-_ the probability of eneomltetlng > I 5 volts on an attterma has been
me_sut'ed by IMP-63 (see Figure 31. This spaeeera[t was launched 31 March 1971
_° _ " into a 26. ?o elliptical orbit with an apogee or' 32.4 R E attd a perigee or 243 l_'n.
_; As the data shOWS, the _eObability Ot encOut_tering hot (Or at least warm) plasma
' _ at 4.15 R E is approximately an ot, der o£ ma_nitucle less thin1 at 6.6 R E. While the
i_ oi inclination ot the IMP-6 orbit makes ani_iysis di_tleult, the data suggest that the
[ i: spacecraft charging pheflomenum m_y be m0r_ comt_on nea_' geosynel_i-onousoi!"
_*i;o_, altitude th_n at any o_he_, i
'i"
°i;
o!.; I
i
• 1
S: ]
00000004-TSA09
295
,.t ; ; I I ! ._ [ |
t
_ _.0_
_, _= 2.5_ [S
"i, UJ
Z
o 2.0_;
(-
!!' --]._
I. O_
|
0
i:
°_.
N . . J i * i ,
d_ _
4: G£OMAGNETICPARAHETERL (AE)
_ Figure 3. P_obability of Measurirlg > 15 Volts on IMP-6 Antenna
References ....................L
:_2*L,
":_..' i. De _'orest:S.E. 11972) Sp_ceet,aftehar_In_ atsynchronous orbitj. Geophy_.
_, Re_i. 77.651-659.
"" 2. Rosen, J_. 119761 Sp.acecratt chargtn_ by magfl_tospherlc plasmas, Progress
_. in,At_roflanttt_sand Astf'o_auttts, 4_7, AIAA, New Yoi'k.
, , 3. Cauffman_ _. P. (i9741 A .Studyof rMP-6 Spaceci-aRCharglflg,ATI_-74 (74511-1,
The Aerospace Co_'por/it{on"."
_. 296
,i
.... _
00000004-TSA11


An altitude-dependent spacecraft charging model

Abstract

Similar works

Full text

Available Versions

NASA Technical Reports Server