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Space Science Reviews 21(1977) 355-376. All Rights Reserved. Copyright
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COSMIC RAY INVESTIGATION FOR THE VOYAGER MISSIONS; ENERGETIC PARTICLE
STUDIES IN THE OUTER HELIOSPHERE--AND BEYOND

E. C. STONE and R E. VOGT*
California Institute of Technology, Pasadena, Calf. 91125, USA.

F. B. McDONALD, B. J. TEEGARDEN and J. H. TRAINOR
Goddard Space Flight Center, Greenbelt, Md. 20771, U.S.A.

J. R. JOKIPII
University of Arizona, Tucson, Ariz. 85721, U.S.A.

and

W. R. WEBBER
University of New Hampshire, Durham, N.H. 03824, U.S.A.

(Received 24 May, 1977)

* Principal investigator of the Voyager Cosmic Ray Experiment

Abstract. A Cosmic ray detector system (CRS) has been developed for
the Voyager mission which will measure the energy spectrum of
electrons from ~=3-110 MeV and the energy spectra and elemental
composition of all cosmic-ray nuclei from hydrogen through iron over
an energy range from ~=1-500 MeV/nuc. Isotopes of hydrogen through
sulfur will be resolved from ~=2-75 MeV/nuc. Studies with CRS data
will provide information on the energy content, origin and
acceleration process, life history, and dynamics of cosmic rays in the
galaxy, and contribute to an understanding of the nucleosynthesis of
elements in the cosmic-ray sources. Particular emphasis will be placed
on low-energy phenomena that are expected to exist in interstellar
space and are known to be present in the outer Solar System. This
investigation will also add to our understanding of the transport of
cosmic rays, Jovian electrons, and low energy interplanetary particles
over an extended region of interplanetary space. A major contribution
to these areas of study will be the measurement of three-dimensional.
streaming patterns of nuclei from H through Fe and electrons over an
extended energy range, with a precision that will allow determination
of anisotropies down to 1%. The required combination of charge
resolution, reliability and redundance has been achieved with systems
consisting entirely of solid-state charged-particle detectors.

1. Introduction

Within the outer heliosphere and in nearby interstellar space exists a
complex hierarchy of energetic particle populations Above energies of
~=100 MeV/nuc, the galactic cosmic rays are the dominant component.
Between 1 and 100 MeV/nuc occur striking changes in the quiet-time
particle composition and spectra that signal a different population
which originates either from a nearby interstellar source or perhaps
somewhere in the yet unexplored distant regions of the solar system.
The particle fluxes in this energy region are frequently augmented by
flare-associated, impulsive solar particle events. At the lower
energies, the turbulence generated by high-speed solar wind streams
interacting with slower moving ones accelerates large numbers of
protons and helium nuclei and is a major source of ions in the MeV
region. Below about 30 MeV, the electron component in the explored
regions of the heliosphere appears to originate mainly from the Jovian
magnetosphere. With most of our heliosphere as well as interstellar
space still unexplored it is expected that even more new components of
the energetic particle population will be identified in the future. It
is becoming well established that dynamic, magnetized plasmas of all
astrophysical scales are frequently the source of large fluxes of
energetic ions and electrons. The composition, energy spectra,
temporal and spatial variation and arrival directions of these
different components contain information on the location of these
plasmas and their dynamics as well as the nature of the medium
traversed by the particles. The separation of the different
populations and the study of their properties require excellent
charge, mass and energy resolution over an extended range of all three
parameters. To meet these objectives, an instrument consisting of
three basic particle detector systems has been developed for the
Voyager mission.

2. Science Objectives

In this section we present a brief overview of what is presently known
about the major energetic-particle components, and we discuss the
expected impact of the Voyager cosmic ray investigation. In this
spirit many of the references are conveniently directed to review
papers.

A. GALACTIC COSMIC RAYS

Of basic importance is the energy density of this component in the
galaxy ( ~=1 eV/cm^3), which is of the same order as the energy
density of starlight, of interstellar magnetic fields, of the 3 [deg.]
blackbody radiation and of the turbulent motion of interstellar
matter. Galactic cosmic rays thus contribute a major element to
galactic dynamics.

The cosmic-ray composition and energy spectra are the result of the
physical processes connected with their synthesis, their acceleration
and their propagation through the interstellar medium. Their
composition includes all elements present in the periodic table. For
Z<=26, the more abundant elements in cosmic rays are also the more
abundant in Solar System matter (Meyer et al. 1974). However, detailed
comparisons (Figure 1) show that cosmic rays (referenced to C), are
depleted in H, He, and O, and enriched in Mg, Si, Fe and Co.
Comparison of the derived cosmic-ray source abundance with the
calculations of explosive nucleosynthesis suggests that the particle
sources are highly evolved stars with masses greater than 5 solar
masses (Meyer et al. 1974).

Another group of elements, d, Li, Be, B, F, K, Sc, Ti, and V, show a
relative cosmic ray abundance which is orders of magnitude larger than
their solar-system abundance. These elements are produced almost
exclusively by spallation of higher-Z primaries in the interstellar
medium and thus provide information on interstellar propagation. The
remaining nuclei for Z <=26 have significant contributions from both
cosmic-ray sources and the interstellar spallation of heavier nuclei.

Measurement techniques for low-energy galactic cosmic rays make it
possible to obtain information on particle acceleration and
interstellar propagation which cannot be achieved at higher energies.
For example, isotopes can presently be resolved in the energy range of
~=1-200 MeV/nuc., and the isotopic composition will provide much more
detailed information on the nature of the nucleosynthesis processes in
the source region than elemental data alone. Several radio-active
isotopes, such as ^(10)B and ^(26)Al, which are mainly interstellar
secondaries, make possible a determination of the average lifetime of
the cosmic rays in the interstellar medium. Furthermore, ionization
energy losses during interstellar propagation should produce
systematic changes in the low energy spectra of various nuclear
species. In addition this low energy component contains a so far
unknown fraction of the total cosmic ray energy.

This energy region which can provide such a wealth of astrophysical
information is also the region that is most severely affected by solar
modulation. As the cosmic rays penetrate into the heliosphere they
encounter magnetic irregularities moving outward in the solar wind.
The resulting processes of particle diffusion, convection and
adiabatic energy loss in the expanding solar wind result in
significant intensity modulation of cosmic rays with energies below
500 MeV/nuc (e.g. Jokipii, 1971, Fisk, 1974). The calculated
interplanetary energy losses are so large that it has even been
suggested that primary nuclei with energies up to several hundred
MeV/nuc outside the heliosphere were unlikely to be observed at 1 AU
(Urch and Gleeson, 1972). This general. conclusion holds even if one
includes gradient and curvature drifts Jokipii and Levy, 1977) which
reduce the energy loss calculated under the Urch and Gleeson model.

With most of the medium and low energy phenomena almost completely
obscured by solar modulation, it is of great importance that precise
measurements be made in the distant heliosphere near and beyond the
outer boundary of the modulation region. The combined mass, charge and
energy resolution of the Voyager cosmic ray experiment is generally
superior to those instruments which up to this time have been used for
measurements at 1 AU. In addition, these measurements cover a far
greater range in mass, charge and energy than their precursors on
Pioneer 10 and 11, and will extend to greater heliocentric distances
at much higher data rates. These new measurements should provide a
much more detailed understanding of the interstellar cosmic ray
component including its energy content, the effects of energy loss by
ionization in the interstellar medium, and its lifetime.

B. COSMIC RAY ELECTRONS

The cosmic ray electron component consists of both directly
accelerated primaries and interstellar secondaries produced by the
decay of charged pions which were created in nuclear collisions (e.g.
Meyer 1969, Ramaty, 1974). While their intensity at most energies is
only a few percent of the corresponding proton intensity, they are of
great astrophysical. importance. The electrons produce the non-
thermal. radio emission observed throughout our galaxy and play a yet
to be determined role in producing the diffuse X- and [gamma]-ray
background emission. Below ~=1 GeV the electron spectrum observed at 1
AU is severely distorted by solar modulation. Estimates of the
interstellar electron spectrum can be made using the spectral data of
the galactic non-thermal radio emission (Webber, 1968; Cummings et al.
1973). However, these radio measurements are primarily useful above ~=
1 MHz, which correspond to a few hundred MeV electron energy in the
assumed galactic magnetic fields. Below 1 MHz, the low-energy galactic
radio spectrum is observed to turn over and decrease (Alexander et al.
1970). It is usually assumed that this depletion is due to free-free
absorption by interstellar hydrogen. However, it is also possible that
the electron spectrum itself begins to decrease as well at the
equivalent energies. Obviously, the correct interpretation of this
feature is of major importance in understanding the conditions in the
interstellar medium (e.g., the presence of cold gas clouds and the
temperature of the intercloud medium) and the origin of these
electrons. Depending on their flux levels, these low-energy electrons
could play an important role in producing the diffuse X- and [gamma]-
ray background in the galactic disk, they could be important to the
dynamics of the galactic disk-halo magnetic-field relationship, and
they could provide information on the escape of these electrons from
known source regions in the galaxy such as the Crab Nebula.

The key objective of the electron investigation is to make precise
measurements over an energy range from 3-110 MeV at large radial
distances. Because galactic electrons are only a few percent of the
nucleon flux, special efforts must be made to suppress background. For
this important objective a new and simple electron telescope has been
developed. Detailed calibrations at both electron and high energy ion
accelerators verify that the energy response and background
suppression meet the requirements of the study.

C. THE ANOMALOUS COSMIC RAY COMPONENT

During the present solar minimum, very large variations as functions
of energy have been observed in the respective composition and spectra
of quiet-time He, N, and O relative to C. (Hovestadt et al. 1973;
McDonald et al., 1974). At 1 AU these appear in the form of a flat
helium energy spectrum below ~=100 MeV/nuc and a sharp increase in the
N and O spectra below ~=15 MeV/nuc (Figure 2). At about 10 MeV/nuc,
oxygen and nitrogen are about 10 times more abundant than carbon
whereas the O/C and N/C ratios are of order one in the solar and the
higher energy galactic cosmic rays. Recent studies of the radial
gradient of low energy helium and oxygen (McDonald et al., 1977;
Webber et al., 1977) show that this component is not of solar origin.

The presence of this anomalous component poses significant
difficulties for the conventional cosmic ray modulation theory. Two
possible solutions have been proposed. Fisk et al.(1974) have
suggested that the low energy portions of the helium and oxygen
spectra could result from the flow of neutral, interstellar atoms into
the heliosphere. These particles are ionized by both solar ultraviolet
and by solar wind particles through charge exchange, and it is
postulated that a certain fraction is accelerated by the
interplanetary medium. The resulting singly ionized nuclei have much
higher rigidities at a given kinetic energy/nucleon and hence, can
more effectively penetrate back into the inner heliosphere. An
alternate approach is to decrease the commonly assumed residual
modulation (by a factor of ~=2) of galactic cosmic rays, as, e.g.
would be produced by including drift phenomena in modulation theory
(Jokipii and Levy, 1977). The average adiabetic energy loss for
protons would be lowered from ~=300 MeV to ~=150 MeV. With this lower
value, direct entry of low energy alphas and heavier nuclei into the
inner heliosphere becomes possible. In this view the anomalous
component is a local interstellar one. Measurements of the isotopic
composition by Mewaldt et al. (1976a) have established that the
enhanced oxygen and nitrogen fluxes are predominantly ^(16)O and
^(14)N. These values restrict possible nova source models for which
the observed nitrogen and oxygen should display enhanced abundances of
the ^(15)N and ^(17)O isotopes (Hoyle and Clayton, 1974). The presence
of a local interstellar source would not be surprising. Already within
the heliosphere there are many different known sources of MeV
particles. The inherently larger and more dynamic plasmas outside the
heliosphere could be expected to provide a great variety of low and
medium energy cosmic ray sources.

It is important that the measurements of anomalous components be
extended over a wider charge interval and to lower energies. The
effects of possible solar-particle contamination at low energies will
be reduced by making these measurements at larger radial distances.
Reduced also will be the effects of solar modulation. The ability to
resolve isotopes is also of special importance for identifying the
origin of this component.

D. INTERPLANETARY ACCELERATION PROCESSES

Co-rotating streams of protons, helium nuclei and possible heavier
ions are the dominant type of low-energy events observed at 1 AU. They
occur in association with high-speed streams in the solar wind and
show little correlation with solar flares or radio emission. They
typically last for 4-10 days, suggesting widths of 60 [deg.]-150
[deg.] at 1 AU. It was originally expected that these co-rotating
streams would diminish rapidly with radial distance due both to
adiabatic energy loss and spatial. effects (Gleeson et al. 1971).
However Pioneer 10 and 11 studies (McDonald et al., 1976) have
indicated that the intensity of these events frequently increases by a
factor of 10-20 out to ~=3-4 AU (Figure 3). Helios studies have shown
a factor ~=10 decrease in intensity between 1 and 0.3 AU. Marshall and
Stone (1977) studied the streaming anisotropies of several-MeV protons
in these events at 1 AU and found that they were generally streaming
in toward the Sun. The energy spectra of the protons are of the form
exp(-P/P[0]), where P is the proton momentum and P[0] is generally on
the order of ~=10-15 MV. The ratio of He/H at a given energy per
nucleon usually varies between 0.03 and 0.05. Maximum particle
intensities are observed between 2 and 4 AU.

These co-rotating proton events are associated with high speed solar
wind streams. Beyond 1 AU the forward regions of these streams steepen
into co-rotating shocks (Hundhausen and Gosling, 1977, Smith and
Wolfe, 1976). At this time it is not clear whether the particles are
energized by the shock or by the associated turbulence. This
acceleration mechanism presumably should be one of the simplest ones
to study.

It is essential that detailed studies of the charge spectra be carried
out at low energies. While it was not known that interplanetary
acceleration was an important process when the Voyager proposal was
prepared, the characteristics of the cosmic ray experiment are well
suited for investigating this new phenomenon. Not only will it be
possible to study the charge and energy spectra, but the low-energy
detector system also provides an excellent measurement of the three-
dimensional. streaming patterns of these particles.

E. JOVIAN ELECTRONS

Below ~=40 MeV the electron spectrum observed at 1 AU exhibits a sharp
turn-up of the form ~T^-2 (where T = kinetic energy). Prior to 1973 it
had been observed that this spectral region underwent very unusual
time variations, including intensity increases of the order of 200-
500%, with durations from 5-12 days, and an anti-correlation with low-
energy co-rotating proton events. The intensity variations could not
be associated with solar activity, and so it was generally assumed
they were galactic. However as Pioneer 10 approached Jupiter both the
University of Chicago (Chenette et al. 1974) and Goddard/University of
New Hampshire instruments (Teegarden et al., 1974) detected low-
energy (~=0.2-8 MeV) electrons from the planet. These electrons
occurred in discrete bursts or increases, typically several hundred
times the normal quiet-time flux, and becoming much more frequent as
one approached Jupiter. Close to Jupiter, but well outside of its
magnetosphere, a quasi-continuous presence of large fluxes of these
electrons was observed.

Subsequent re-examination of the earlier quiet-time electron data over
an 8-year period revealed a striking 13-month periodicity with the
maximum increases generally centered about the period when the nominal
interplanetary magnetic field connected Earth and Jupiter.
Simultaneous observations by Pioneer 11 at 3 AU, IMP 7 at 1 AU and
Pioneer 10 at the edge of the Jovian magnetosphere have further
confirmed the Jovian magnetosphere as the source of these electrons
(McDonald and Trainor, 1976). Further studies over the solar minimum
period 1972-1976 (Mewaldt et al. 1976b) have shown that the increases
can be detected over an entire year (Figure 4). It now appears most
probable that most electrons in the low energy spectral turn-up are of
Jovian origin. The electron increases have been observed inside 0.4 AU
and out to 10 AU. How these ubiquitous particles are transported
throughout much of the heliosphere from essentially a point source at
S AU remains a major problem, the solution of which is bound to
provide significant new insight into cosmic ray transport processes.

In the 3-10 MeV electron range the sensitivity of the cosmic ray
instrument is significantly greater than that of instruments which
have flown at 1 AU so far. It should thus easily be possible to study
the properties of Jovian electrons out in the distant heliosphere. In
addition, during its passage from Jupiter to Saturn, the Voyager
spacecraft will be near the extended Jovian magnetotail, making it
possible to determine what role this region plays in the transport of
these particles.

F. ARRIVAL DIRECTION OF LOW ENERGY COSMIC RAYS

This key observable in cosmic ray physics has yet to be fully
exploited, and studies of low-energy flow patterns are a major
objective of the Voyager cosmic ray experiment. The complete
determination of both the isotropic component and the streaming vector
(anisotropy) of the cosmic ray flux over a wide range of energies and
elements will greatly aid the analysis of interstellar-particle
propagation phenomena. One of the most exciting products of the
measurements of cosmic ray anisotropies would be the identification of
a specific astrophysical object, e.g., a pulsar or supernova remnant,
as the source of an identified component of the observed cosmic ray
flux.

Source identification can be attempted from the measurements of the
interstellar streaming patterns and the energy spectra of low-energy
cosmic rays over an elemental. domain ranging from hydrogen through
iron, provided the Voyager spacecraft penetrates the modulation
boundary. The anisotropies are expected to be most pronounced (in the
order of tens of percent) in the low-energy range where pathlength
limitations due to heavy ionization losses are most significant, and
where the sources therefore must be close. For example, a 1 MeV proton
has an integral. pathlength L ~<= 200pc in interstellar gas of n = 1
cm^-3, and diffusive propagation with a mean freepath [lambda] ~= 30pc
restricts the distance of their source to less than ~=100pc.

It must be noted that the structure of the interstellar diffusive
medium will impose its signature on the propagation vector, which thus
will tell us something about the features of the galactic magnetic
fields, but not necessarily the source direction. Source
identification has to be derived from the analysis of a combination of
observed parameters. Identification of a source will be aided by the
fact that potential sources are extremely rare within the volumes
under discussion; e.g. statistically, one expects only a few
supernovae remnants in a 10 MeV pathlength source volume, with
additional restrictions being imposed by source age. Since ionization
losses are governed by the square of the particle's charge (Z^2),
consistency checks between anisotropies and energy spectra of elements
differing widely in charge (1 ~<=Z~<=26) can be used to separate
local. origin elements from those at large distances which may have
been decelerated to lower energies in their propagation through the
galaxy.

G. OTHER OBJECTIVES

There are several other study areas where this investigation should
make important contributions. The large geometric factors of the
detector system will permit detailed study of the dynamics of solar
cosmic ray events even to very large radial distances. This study of
the interplanetary propagation of particles impulsively injected from
the Sun will complement the measurements of the radial variations of
galactic cosmic rays. In addition this investigation will yield
important information about the magnetospheres of Jupiter and Saturn.
On Pioneer 10 and 11 conventional cosmic ray instruments functioned
over most of the Jovian outer magnetosphere (> 25 R[J]). Pioneer 10 also
demonstrated that in this region, the proton anisotropies are a
complex mixture of co-rotation, intensity gradients and field aligned
flow (McDonald and Trainor, 1976). The Voyager multi-element cosmic
ray system is well suited to study these distributions, and in
addition, it will be making charge composition measurements at much
lower energies than the Pioneer 10 and 11 experiments. These Jovian
studies complement those of the Low-Energy Charged-Particle Experiment
on the Voyager spacecraft.

3. The Detector Systems

To study the energetic particle phenomena discussed in the previous
section a set of three basic detector systems has been developed. The
charge, mass and energy intervals covered by these detectors are
summarized as follows:

(a) Nuclei charge and energy spectra: Z = 1-30, energy range 1-500 MeV
for H to 2.5-500 MeV/nuc for Fe.
(b) Isotopes: Z = 1-8 ([DELTA]M= 1), energy range 2-75 MeV/nuc
(c) Electrons: 3-110 Me
(d) Anisotropies: All components ranging from H (1-150 MeV) to Fe
(2.7-500 MeV/nuc) as well as 3-10 MeV electrons.

This combination of charge, energy, and mass resolution, reliability
and redundancy has been realized with particle telescopes consisting
entirely of solid-state charged-particle detectors. These devices have
proven to be highly reliable in their space application.

The Voyager cosmic ray detector systems are: the High Energy Telescope
System (HETS), the Low Energy Telescope System (LETS), and the
Electron Telescope (TET). By using three independent systems, the
charge and energy response and the background rejection can be
optimized over a given energy interval while providing the redundancy
that is vital for an extended mission. By using three-parameter
analysis over almost the complete energy range, through the use of
curved dE/dx devices to reduce the pathlength variations, through
choosing the thickest dE/dx device appropriate to a given energy
interval to minimize Landau effects, we feel that the ideal solid-
state-detector resolution will be approached. The use of two double-
ended High Energy Telescopes and the use of multiple (4) Low Energy
Telescopes provides the necessary geometric factor to do isotope and
charge studies as well as measure low-level anisotropies. These
systems have evolved from the GSFC-UNH Pioneer 10 experiment and the
CIT IMP-7 and OGO-VI experiments. The flight instrument is shown in
Figure 5. In the following section the characteristics of the three
different systems are discussed.

A. THE HIGH ENERGY TELESCOPE SYSTEM (HETS)

The system possesses two complete HET telescopes which have nearly
orthogonal viewing directions. They have the following
characteristics:

(a) The spectra of electrons and all elements from hydrogen to iron
will be measured over a broad range of energies. (b) Individual.
isotopes can be resolved up through the isotopes of oxygen ( [DELTA]M
= 1 for Z= 1-8); individual charges will be resolved up through Z= 30.

Each High Energy Telescope (HET) is double-ended (Figure 6) and has
its own associated electronics (Figure 7). A portion of the
electronics is also shared with the LET system. The HET telescope is a
unique combination of solid-state detectors: A[1] and A[2] are thin
surface barrier detectors, B[1] and B[2] are curved Li-drifted
detectors, and C[1] through C[4] are the central. areas of double-
grooved Li-drifted detectors. The combination of a double-ended
telescope and the inclusion of a solid-state guard element permits up
to a twenty-fold increase in geometry factor over earlier designs. The
double grooves create annular detectors around each central area. The
annular detectors taken together constitute an anti-coincidence or
guard detector (denoted G) surrounding C[1] through C[4]. A double-
grooved detector is shown in Figure 8. Accelerator tests indicate that
cross talk between the central and annular areas is less than one part
in 2000. The B detectors are curved to minimize variations in particle
path length in these detectors due to the finite telescope opening
angle.

Three classes of events are recognized by the electronics, two
stopping (S[1] and S[2]) and one penetrating (P), as described in
Table I.

Event type S[1] represents particles which enter through A[1]A[2] and
stop in the active volume of the telescope. S[2] events are stopping
particles which enter from the B side, and type P events penetrate
B[1] and B[2] and the complete C stack.

In the S[2] mode precise measurements of the electron spectrum in the
3-10 MeV interval will also be made. Below 3 MeV, background due to
Compton electrons from the spacecraft radio-isotope power supplies
will prohibit quiet-time electron measurements. However,
interplanetary electron increases due to solar flares and large events
associated with Jupiter will be observable below 3 MeV. Above 3 MeV
the 3-10 MeV electron sensitivity should be greater than that of any
particle telescopes flown so far at 1 AU.

In order to accommodate the very large ranges in particle charge and
energy, effective electronic dynamic ranges of up to 40 000 are
required. This requirement is met by using 4096 channel pulse-height
analyzers (pha) and preamplifiers with two gain modes differing in
gain by factors of 5 or 10. Nuclei with charge Z>2 are analyzed in
both gain modes. In the low-gain mode, however, protons and alphas do
not contribute to S[1] events, electrons and protons are excluded from
the S[2] events and protons are excluded from the P events. For
particles entering a HET telescope from either the A or B end, the
experiment electronics forms a pulse sum (such as B[1] + 0.5B[2] +
0.142[C2 + C3 + C4]), which when applied to a fixed threshold
determines whether the event is due to a particle with Z< or >=2. We
refer to such a system as a slant threshold. For particles entering
from the B end, there is a slant threshold for both high and low gain
modes. For particles entering from the A end, there is a slant
threshold operating at low-gain mode only and it defines nuclei with
Z>=3 and < 3. This slant threshold logic is an integral part of many
of the rate equations and also forms the basis for the categorization
and storing of pha events for readout.

As shown in the HET block diagram, three 12-bit pulse height analyzers
are shared by one HET telescope and two LET telescopes. The instrument
has two of these shared pha blocks. They are essentially identical and
incorporate considerable cross strapping between the blocks to provide
redundancy by command. Each pha block incorporates 8 storage
registers, a polling system and block select/readout control.

Each block polling system independently scans sequentially through
eight event register positions (e.g., LET-S[1], LET-S[2], TET, HET-
S[1], LET-S[1], LET-S[2], HET-S[2], HET-P) until it finds a register
with data. It then holds at that position until the event has been
read out and then advances to the next position, etc. The block select
system sends the read envelope and shift signals to the appropriate
block if only one block has data, or it alternates between blocks if
both have data. Such a polling system optimizes the efficiency of the
experiment data system as well as emphasizes rare events in the data
in a predictable way.

Typical examples of the expected charge and mass resolution are
presented in Table II. It is shown that isotopes are resolved up
through oxygen and that individual charges are easily resolved through
iron. Isotopes will not be resolved in the P mode.

Schematic curves illustrating the response of a HET for stopping
particles in the dE/dx by E mode are shown in Figure 9.

B. THE LOW ENERGY TELESCOPE SYSTEM (LETS)

The Low Energy Telescope System (LETS) is designed to determine the
three-dimensional. flow patterns of interstellar and interplanetary
cosmic ray fluxes and to extend high resolution elemental measurements
(1<=Z<=30) down to very low energies. It consists of four Low Energy
Telescopes (LET). The LETs have been optimized for the interstellar
anisotropy measurements by incorporating large area, thin detectors.
The LET (Figure 6) provides multi-parameter analysis capability at low
energies with the relatively large geometrical factor (0.5 cm^2 sr
each) needed for measuring the expected anisotropies. The four LETs
are required in order to completely characterize the three-dimensional
anisotropy. This arrangement also provides a large total geometrical
factor (~=2 cm^2 sr), and sensor redundancy.

As shown in the schematic drawing (Figure 6), a 3 [micro]m Al window
serves for thermal control and protection from sunlight. All detectors
are of the surface barrier type. An important feature is the use of
key-hole detectors for L1 and L2. The active area of the detectors is
accurately defined by using a mask to precisely define the area over
which the Au and Al contacts are deposited.

Beyond the charge-sensitive preamplifiers and shaping amplifiers, a
LET electronics system consists of coincidence circuitry to determine
if an event has occurred, pulse-height analyzers and a rate
accumulator system as shown previously in Figure 7. As summarized in
Table III, there are two analysis modes based upon the amplitude of
the sum L1 + 0.42L2 + 0.2L3, and events are labeled Type S[1], or Type
S[2] accordingly.

This is the same type of slant threshold as was discussed for the HET
system. However the LET system requires a smaller dynamic range and so
gain-switching is not necessary. These events are separately stored
and normally read out into telemetry with equal priority in the
readout polling scheme. Detector thresholds are set at 200 keV for L1
and L2, at 1 MeV for L3, and at 300 keV for L4. Pulse-height analyzers
with 4096-channels are provided for L1, L2 and L3. A versatile command
system allows for change of the pulse-height analysis conditions, the
rate logic, readout priority and power on/off control of the various
preamplifiers. E.g., LET analysis may occur also for L1 or L1L2
coincidences. The LET data system and polling were described as part
of the HET discussion.

With the specified detector thresholds, the energy ranges specified in
Table III are calculated. These calculations are based on the standard
energy-loss tables; previous experience shows that corrections to the
tables will have to be made on the basis of future calibration data.

Figure 10 shows typical response curves for particles of several
types. The energy loss, [DELTA]E, in L1+L2 is plotted as a function of
residual energy, E', in L3. The different tracks for various particle
types can be used to calculate the mass of the particles. Any
uncertainties in  [DELTA]E or E' result in uncertainties in the
calculated mass, with the largest uncertainties being the angle of
incidence of the particle.

C. THE ELECTRON TELESCOPE (TET)

A light-weight electron energy-spectrometer has been developed for the
energy range from ~=5 to 110 MeV. Like the HET, this system uses
double-grooved solid state devices which allows an all-solid state
detector design with adequate energy resolution and background
rejection so that meaningful spectra can be obtained even at the
relatively low electron intensities near earth.

Figure 6 gives a schematic cross section of the electron telescope. It
consists of eight solid-state detectors (D[1] to D[8]) and six
tungsten absorbers (A[2] to A[7]) in a cylindrical geometry. Like the
HET system, the detector-absorber stack is surrounded by a grid of
solid-state-guard detectors (G[2] to G[8]). The TET electronics are a
simplified version of the HET/LET system shown in Figure 7.

Electrons and their energies are identified by a double-dE/dx
measurement in detectors D[1] and D[2] and by a simultaneous
measurement of their range, as determined by the penetration of
detectors D[3] through D[7]. The use of range spectroscopy, while
providing satisfactory energy resolution and background rejection, has
the additional virtue of being insensitive to electronic gain drifts,
thus permitting the use of simpler electronics systems.

Energy calibrations of prototypes of electron range-telescopes for
energies from 1 MeV to 1 GeV have been performed on particle
accelerators (Figure 11). These data allow the unfolding of energy
spectra from measured range distributions. As an example, we show in
Table IV the expected range distributions (determined from the
calibrated detector response) for the three hypothetical electron
energy spectra shown in Figure 12. The application of a simple
unfolding technique to these data results in the very satisfactory
reproduction of the input spectra shown by the TET data points in
Figure 12. At low energies, the expected data points from the HET
telescopes are also included in the figure showing the adequate
overlap of energy ranges for TET and HET.

Conservative estimates of maximum background levels during the mission
are shown by the dashed areas. This background is generated by the
spacecraft Radioisotope Thermal Generators (RTG) (below ~=2.5 MeV) and
by interacting high-energy protons in the detector stack.

Acknowledgements

The Voyager cosmic ray experimenters would like to acknowledge their
gratitude to Donald E. Stilwell, the Experiment Engineer, and to
William Althouse, A. C. Cummings, and T. L. Garrard of Caltech; M. F.
Beazley, W. D. Davis and H. E. Trexel of Goddard and J. Otte of JPL
and the many others whose devotion and hard work made it possible to
deliver an experiment whose inflight performance is expected to reach
the scientific objectives as originally proposed.

References

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TABLE I
HET telescope parameters

TABLE II
HET S[1] resolution

TABLE III
LET telescope parameters
(SL = slant condition)

TABLE IV
TET telescope range distributions and maximum background levels for
the three hypothetical cosmic ray electron spectra shown in Figure 12.

Fig. 1. Relative abundances of the elements from hydrogen to iron,
normalized to carbon. The closed circles without error bans which are
joined by a light line represent the element abundances in the Solar
System. The symbols for the cosmic-ray abundances at 1 AU represent
results from different experiments. This experiment will cover the
same range of elements with emphasis on particle composition as a
function of energy.

Fig. 2 Typical. H. He, C, N and O spectra at 1 AU Note the flat
spectrum of ^(4)He and the anomalous abundances of O and N relative to
C between ~=2 and 30 MeV/nuc.

Fig. 3. GSFC IMP-7 and Pioneer-11 flux values for 1.2-2.1 MeV protons
for 6-month period extending from 1 November 1973 to 1 May 1974. Data
have been  averaged over 6-hour periods. The increase in early
November appears to be the only flare-associated increase in this
period. The co-rotating increases which exceeded 1 proton/cm^2-sec
ster-MeV have been numbered. Only one co-rotating event (No. 1) is
larger on IMP7 than on Pioneer 11.

Fig. 4. Jovian electron increases observed at 1 AU with the Caltech
IMP 7 and 8 instruments.

Fig. 5. The assembled Voyager cosmic ray experiment. The weight is 7.5
kg and the nominal power is 5.35 W.

Fig. 6. Schematic of the HET, LET and TET detector systems.

Fig. 7. Diagram of one HET/LET electronic system. There is an
identical system for the other HET and 2 LET telescopes. Note that the
HET and LET systems share the same post-amplifiers and height
analysers. The tag bits identify the telescope where the event
originated as well as the event type.

Fig. 8. Picture of double-grooved detector used in the HET telescopes.
A similar device with wider guard ring is used in the TET telescope.
(The detector is resting on a glass dish.)

 Fig. 9. Calculated HET response curves for stopping particles
entering the A and B sides of a HET telescope. Also shown are the
limits for the high gain and low gain modes.

Fig. 10. Calculated LET response for particles which penetrate L[1]
and L[2] and stop in L[3]. The effects of the finite opening angle are
seen for oxygen incident normal to the telescope (0 [deg.]) and at the
maximum opening angle (25 [deg.]).

Fig. 11. Electron-calibration results for prototype TET shown in
insert. The response curves shown represent the fractional
distribution of mono-energetic electrons over the telescope ranges.

Fig. 12. Hypothetical electron spectra (solid lines) for heliocentric
radii of 1 AU, 5 AU and the interstellar medium. Data points show the
resolving power of the HET and TET. The dashed area shows the expected
RTG and cosmic-ray generated background. The sharp increase in
detector background at low energies is due to the RTG.