Apollo 14 Cold Cathode Ion Gage Experiment


Instrument Overview
===================
The Cold Cathode Ion Gage Experiment (CCIG, also referred to as the
Cold Cathode Gage Experiment, or CCGE) was deployed as part of the
Apollo Lunar Surface Experiments Package (ALSEP) on Apollos 12, 14, and
15.  It was designed to measure the density of neutral particles to
determine the amount of gas present at the lunar surface.  This data
helps constrain the source and loss mechanisms of the tenuous lunar
atmosphere.  A cold cathode ionization gage was used for this purpose.
The gage can determine the amount of gas present, expressed as
concentrations of particles per cubic cm or pressure in torr, but not
its composition.  The CCIG gage head was roughly 18 x 10 x 12 cm and
used 6.5 W.  The instrument consisted of the cold cathode ionization
gage and associated electronics.  The mass of the experiment package
was 5.7 kg. (Note that the term ''Gage'', not ''Gauge'', was the
accepted use for this experiment.)

The CCIG gage unit was carried in a compartment of the SIDE instrument
and was removed and set up on the lunar surface by the deploying
astronaut.  The gage unit was connected by a cable to the SIDE package
and attached to the end of the SIDE ground screen holding tube, which
was designed to pivot down to the ground and hold the CCIG in place a
fixed distance from the SIDE, and with the proper orientation of the
gage head.  This avoided the difficulties encountered with Apollo 12
and 14 units, where the extreme stiffness and springiness of the
electrical cable, plus the low lunar gravity, made it difficult to
position the gage head.

The cold cathode ionization gage is a cylindrical sensor unit in a
stainless steel envelope consisting of stainless steel coaxial
electrodes.  The cathode is a spool running through the center axis of
the cylinder.  A cylindrical anode surrounds the cathode, and both
electrodes are in an axial magnetic field of 0.09 Tesla (900 Gauss)
produced by a permanent magnet.  A magnetic shield is mounted around
the gage and its magnet.  A potential of +4500 volts was applied to the
anode by a power supply consisting of a regulator, converter,
voltage-multiplier network, and feedback network to the low voltage
supply.  This created a self-sustained Townsend discharge in the gage
in which electrons remained largely trapped in the magnetic field with
enough energy to ionize any gas particles they would strike.  The ions
would then be collected at the cathode, producing a current.  The
cathode was connected to an auto-ranging, auto-zeroing electrometer
that measured currents in the range 1.0E-13 to 1.0E-16 amps.  A
temperature detector was included to enable conversion of the readings
to equivalent pressure.

Baffles are mounted in the cylinder between the opening and the
electrodes.  A dust cover closed but did not seal the opening before
deployment and was pulled aside by the squib motor and spring on
command.  Because the CCIG was not evacuated, adsorbed gases produced
an elevated response at turn-on.  The gases escaped from the gage
rapidly at first and then slowly baked out during the lunar day.

The device was sensitive to gas density rather than pressure.  The
response varied somewhat with gas composition, but errors due to the
uncertainties in composition were expected to be within a factor of
two.  The data from the experiment have been expressed as equivalent
density for a nitrogen lunar atmosphere.  The CCIG had three
auto-switched, overlapping, sensitivity ranges enabling detection of
the lunar atmosphere from 2.E+5 to 1.E+11 particles/cubic cm
(equivalent nitrogen).  In the normal operational mode the basic cycle
repeated five measurements (separated by 2.4 s), three measurements
(separated by 40 s), and 16 seconds of calibration and auto-zeroing
every 2.5 min.  Temperature and other engineering functions were also
sampled within this 2.5-min cycle.  In a ground commanded special mode,
one measurement was obtained every 2.4 s, with no other measurements
being performed.  More details are available in ''Apollo Scientific
Experiments Data Handbook'', JSC-09166, NASA TMX-58131, August 1974
(revised April 1976).

The Apollo 14 ALSEP central station was located at 3.6440 S latitude,
17.4775 W longitude. The CCGE was deployed approximately 16 meters
south-southeast of the central station and 180 meters W of the Lunar
Module. The instrument was turned on at approximately 23:59 UT on 5
February 1971. The readings were initially saturated at full scale
because of gas trapped within the gage. At about 1:20 UT on 6 February
the level was below saturation (4 x 10E-7 torr) and continued to
decrease. At 1:40 UT the high voltage power supply was turned off
because it was believed arcing was taking place. The unit was operated
for short periods of time during LM venting before the second EVA and
during housekeeping functions after the second EVA and was then turned
off until lunar sunset. The instrument operated during lunar night but
was only turned on for brief periods during the lunar day to minimize
the possibility of high voltage arcing. On 5 April 1971 the analog to
digital converter became erratic and no processing of positive-value
data inputs was possible. This problem was not serious and affected only
the temperature and housekeeping data. Full daytime operation was
obtained in November 1971. Near the end of nighttime operation in
February 1972 the data dropped out but returned at sunrise 4 days later.
This problem occurred intermittently during nighttime operation until
November 1972 when all nighttime data were lost for the next two months,
followed by complete nighttime data in late March 1973 and then two more
months of no nighttime data.

On 15 April 1973 the CCGE/SIDE (Suprathermal Ion Detector Experiment)
went into standby mode, attributed to arcing in the high-voltage supply
at elevated daytime temperatures. Operation was restored over the next
lunar night and operation after this was not attempted during the lunar
day. On 5 January 1975 the instrument was commanded off.   
																										 

References
==========
Apollo 14 Preliminary Science Report, NASA SP-272, published by NASA,
Washington, D.C., 1971.

Apollo Scientific Experiments Data Handbook, NASA Technical Memorandum
X-58131, JSC-09166, published by NASA Johnson Space Center, Houston,
Texas, Aug. 1974 (revised Apr. 1976).

Johnson, F.S., D.E. Evans, and J.M. Carroll, Chapter 7. Cold Cathode 
Gage (Lunar Atmosphere Detector), Apollo 12 Preliminary Science Report, 
NASA SP-235, pp. 93-97, Washington D.C., 1970.

Johnson, F.S., D.E. Evans, and J.M. Carroll, Chapter 13. Cold Cathode
Gage Experiment (Lunar Atmosphere Detector), Apollo 15 Preliminary
Science Report, NASA SP-289, pp. 13-1 to 13-5, Washington D.C., 1972.

Bates, J.R., W.W. Lauderdale, and H. Kernaghan, ALSEP Termination Report,
NASA Reference Publication Series, NASA RF-1036, published by NASA Johnson
Space Center, Houston, Texas, Apr. 1979.


Source
======
The NASA Space Science Data Coordinated Archive (NSSDCA, formerly NSSDC) 
provided this description.