Astronomy:Apollo Lunar Surface Experiments Package

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Short description: Scientific instrument package left by the Apollo astronauts on the Moon
ALSEP of the Apollo 16 mission

The Apollo Lunar Surface Experiments Package (ALSEP) comprised a set of scientific instruments placed by the astronauts at the landing site of each of the five Apollo missions to land on the Moon following Apollo 11 (Apollos 12, 14, 15, 16, and 17). Apollo 11 left a smaller package called the Early Apollo Scientific Experiments Package, or EASEP.

Background

The instrumentation and experiments that would comprise ALSEP were decided in February 1966. Specifically, the experiments, institutions responsible, and principal investigators and coinvestigators were:[1]

The ALSEP was built and tested by Bendix Aerospace in Ann Arbor, Michigan. The instruments were designed to run autonomously after the astronauts left and to make long-term studies of the lunar environment. They were arrayed around a Central Station which supplied power generated by a radioisotope thermoelectric generator (RTG) to run the instruments and communications so data collected by the experiments could be relayed to Earth. Thermal control was achieved by passive elements (insulation, reflectors, thermal coatings) as well as power dissipation resistors and heaters. Data collected from the instruments were converted into a telemetry format and transmitted to Earth.

Deployment

The ALSEP was stored in the Lunar Module's Scientific Equipment (SEQ) Bay in two separate subpackages. The base of the first subpackage formed the Central Station while the base of the second subpackage was part of the RTG. A subpallet was also attached to the second subpackage which usually carried one or two of the experiments and the antenna gimbal assembly. On Apollo 12, 13, and 14, the second subpackage also stored the Lunar Hand Tool Carrier (HTC). The exact deployment of experiments differed by mission. The following pictures show a typical procedure from Apollo 12.

Picture Description
ALSEP AS12-47-6913.jpg Pete Conrad opens the SEQ bay doors through a system of lanyards and pulleys.
ALSEP AS12-46-6783.jpg Alan Bean removes the second subpackage from the SEQ bay. This was accomplished by using the boom which can be seen extended and a pulley system to set it on the ground. By Apollo 17, astronauts felt that the use of the boom and pulley system complicated the operation. And as such, the entire system was removed for Apollo 17. On Apollo 11, Buzz Aldrin chose not to use the system because of a lack of time.
ALSEP AS12-46-6784.jpg The first subpackage, which Conrad had removed from the SEQ bay earlier.
ALSEP AS12-46-6786.jpg Bean lowers the RTG cask into a position where he can access it.
ALSEP AS12-46-6787.jpg Bean is beginning to remove the dome from the RTG cask. He is using a specialized tool called the Dome Removal Tool (DRT). Note how he has already prepared the RTG for fueling and has already deployed the HTC. Conrad has already removed the subpallet from the RTG subpackage.
ALSEP AS12-46-6788.jpg Bean discards the dome with the DRT still attached. Neither had a use afterward.
Putting the Plutonium 238 fuel into the SNAP 27.jpg Bean is attempting to remove the fuel element from the cask using the Fuel Transfer Tool (FTT). Note one of the Universal Hand Tools (UHT) attached to the RTG subpackage. On Apollo 12, the fuel element stuck in the cask because of thermal expansion (Bean could feel the heat through his suit). Conrad pounded the side of the cask with a hammer while Bean successfully worked it loose. He then inserted it into the RTG and discarded the FTT.
ALSEP AS12-46-6792.jpg Bean attaches the RTG subpackage to the carrybar in preparation for the traverse to the ALSEP deployment site. The carrybar would later be used as the mast for the antenna on the Central Station.
ALSEP AS12-46-6793.jpg During the traverse to the ALSEP deployment site, Conrad took this picture. His shadow indicates that he is carrying the subpallet with one of the two UHTs.
ALSEP AS12-46-6807.jpg Bean carries the ALSEP out to the deployment site.
ALSEP AS12-47-6919.jpg Conrad holds the carrybar in his left hand while he releases the antenna gimbal assembly with a UHT.
ALSEP Ap13-70-HC-77.jpg This photo shows Jim Lovell training for Apollo 13. He is currently deploying a mock-up of the Central Station. The Station was spring-loaded. After releasing Boyd bolts, the top of the Station would spring up, deploying it. Note the various locations on top of it which held some of the experiments before deployment. They were also held down with Boyd bolts that were released with a UHT.[4]

Common elements

Each ALSEP station had some common elements.

Name Diagram Picture Description
Central Station Central Station.jpg ALSEP Apollo 16 Central Station.jpg The picture shows the Central Station from Apollo 16's ALSEP.
The Central Station was essentially the command center for the entire ALSEP station. It received commands from Earth, transmitted data, and distributed power to each experiment. Communications with Earth were achieved through a 58 cm long, 3.8 cm diameter modified axial-helical antenna mounted on top of the Central Station and pointed towards Earth by the astronauts. Transmitters, receivers, data processors and multiplexers were housed within the Central Station. The Central Station was a 25 kg box with a stowed volume of 34,800 cubic cm. In addition, on Apollos 12 to 15, a Dust Detector was mounted on the Central Station which measured the accumulation of Lunar dust.
Radioisotope Thermoelectric Generator (RTG) ALSEP RTG ALSEP.png ALSEP Apollo 14 RTG.jpg The picture shows the RTG from Apollo 14 with the Central Station in the background.
The RTG was the power source for the ALSEP. It utilized the heat from the radioactive decay of plutonium-238 and thermocouples to generate approximately 70 watts of power. The base of the RTG was the base of the second ALSEP subpackage.
RTG Cask ALSEP Ap14-KSC-70P-508.jpg The RTG cask stored the plutonium-238 fuel element. It was located to left of the SEQ bay. The cask was designed to withstand a launch vehicle explosion in the event of an abort or a re-entry into Earth's atmosphere (which is what occurred on Apollo 13). The picture shows Edgar Mitchell practicing the removal of the fuel element.

List of experiments

Name Diagram Description
Active Seismic Experiment (ASE) Active Seismic Experiment Thumper.png Through the use of seismology the internal structure of the Moon could be determined to several hundred feet underground. The ASE consisted of three major components. A set of three geophones was laid out in a line by an astronaut from the Central Station to detect the explosions.[5] A mortar package was designed to lob a set of four explosives from varying distances away from the ALSEP. Finally, an astronaut-activated Thumper was used to detonate one of 22 charges to create a small shock. The diagram shows the Thumper device.
Charged Particle Lunar Environment Experiment (CPLEE) The CPLEE was designed to measure the fluxes of charged particles such as electrons and ions.
Cold Cathode Gauge Experiment (CCGE) Cold Cathode Gauge Experiment.jpg The CCGE was essentially a stand-alone version of the CCIG.
Cold Cathode Ion Gauge (CCIG) The CCIG experiment was designed to measure the pressure of the Lunar atmosphere. It was originally designed to be part of the SIDE, but its strong magnetic field would have caused interference. The CCIG is on the right of the SIDE in the diagram.
Heat Flow Experiment (HFE) The HFE was designed to make thermal measurements of the Lunar subsurface in order to determine the rate at which heat flows out of the interior.[6] The measurements could help determine the abundance of radioisotopes and help understand the thermal evolution of the Moon. The HFE consisted of an electronics box and two probes. Each probe was placed in a hole by an astronaut that was drilled to about 2.5 m deep.
Laser Ranging Retroreflector (LRRR) Laser Ranging Retroreflector.gif

Laser Ranging Retroreflector Apollo 15.gif

Main page: Lunar Laser Ranging Experiment
An LRRR is used to reflect a laser beam from Earth, the round-trip timing of the beam is an accurate gauge of the distance to the Moon. The information is used to study Lunar recession due to tidal dissipation and the irregular motion of the Earth. The LRRRs are the only experiments still in use today. The above diagram shows the Apollo 11 version. Apollo 14's was similar to Apollo 11's. The lower diagram shows the larger Apollo 15 version.
Lunar Atmosphere Composition Experiment (LACE) The LACE was designed to detect the composition of the Lunar atmosphere.
Lunar Ejecta and Meteorites Experiment (LEAM) ALSEP Lunar Ejecta and Meteorites Experiment.gif The LEAM was designed to detect secondary particles that had been ejected by meteorite impacts on the lunar surface and to detect primary micrometeorites themselves.[7] See Lunar soil for some experiment results.
Lunar Seismic Profiling Experiment (LSPE) ALSEP Lunar Seismic Profiling Experiment Charge.gif
NASA Apollo17 LSPE explosive.jpg
The LSPE was similar to the ASE except the expected depth was to be several kilometers. It consisted of three major components. A set of four geophones was laid out near the ALSEP by an astronaut.[5] The LSPE antenna was used to send signals to the charges. There were eight charges, each consisting of various sizes ranging from 18 to 6 lb (0.06 to 2.72 kg). The charges were deployed during the rover traverses.
Lunar Surface Gravimeter (LSG) ALSEP Lunar Surface Gravimeter.gif The LSG was designed to make very accurate measurements of lunar gravity and its change over time. It was hoped the data could be used to prove the existence of gravitational waves.
Lunar Surface Magnetometer (LSM) ALSEP Lunar Surface Magnetometer.svg The LSM was designed to measure the Lunar magnetic field. The data could be used to determine electrical properties of the subsurface. It was also used to study the interaction of solar plasma and the Lunar surface.
Passive Seismic Experiment (PSE) ALSEP Passive Seismic Experiment.jpg The PSE was designed to detect "moonquakes," either naturally or artificially created, to help study the structure of the subsurface.
Passive Seismic Experiment Package (PSEP) ALSEP Passive Seismic Experiment Package.gif Similar to the PSE, except it was self-supporting. This meant it carried its own power source (solar arrays), electronics, and communications equipment. In addition, the PSEP also carried a Dust Detector.
Solar Wind Spectrometer Experiment (SWS) ALSEP Solar Wind Spectrometer-en.svg The SWS was designed to study solar wind properties and its effects on the Lunar environment.
Suprathermal Ion Detector Experiment (SIDE) The SIDE was designed to measure various properties of positive ions in the Lunar environment, provide data on the plasma interaction between solar wind and the Moon, and to determine the electrical potential of the Lunar surface.

List of missions

Each mission had a different array of experiments.

Apollo 11 (EASEP)

On Apollo 11, Buzz Aldrin simply carried the EASEP to the deployment site by using handles. This is different from the carrybar used on later missions.

Because of the risk of an early abort on the Moon, geologists persuaded NASA to permit only experiments that could be set up or completed in 10 minutes.[8] As a result, Apollo 11 did not leave a full ALSEP package, but left a simpler version called the Early Apollo Surface Experiments Package (EASEP). Since there was only one 2 hour 40 minute EVA planned, the crew would not have enough time to deploy a full ALSEP, which usually took one to two hours to deploy. Both packages were stored in the LM's SEQ bay.

Engineers designed the EASEP to deploy with one squeeze handle, and the Laser Ranging Retro Reflector (LRRR) also deployed within ten minutes. Despite the simpler design, the seismometer was sensitive enough to detect Neil Armstrong's movements during sleep.[8]

Name Picture Notes
LRRR Apollo 11 Lunar Laser Ranging Experiment.jpg The transparent dust cover has already been removed and is 3–4 m further to the right. The metal reflector mirrors the black sky.
PSEP ALSEP AS11-40-5951.jpg Failed after 21 days.

Apollo 12

Layout for Apollo 12's ALSEP
Name Picture Notes
LSM ALSEP AS12-47-6920.jpg Stored on the first subpackage.
PSE ALSEP AS12-47-6917.jpg Stored on the first subpackage.
SWS ALSEP AS12-46-6812.jpg Stored on the first subpackage.
SIDE/CCIG ALSEP AS12-47-6922.jpg Stored on the second subpackage as part of the subpallet.
The CCIG can be seen to the left of the SIDE. The CCIG failed after only 14 hours.

The antenna gimbal assembly was stored on the subpallet. The stool for the PSE, the ALSEP tools, carrybar, and HTC was stored on the second subpackage.

Apollo 13

Planned layout for Apollo 13's ALSEP
A recording of the Apollo 13 S-IVB's impact on the lunar surface as detected by the Apollo 12 Passive Seismic Experiment.

Because of the aborted landing, none of the experiments were deployed. However, the Apollo 13 S-IVB stage was deliberately crashed on the Moon to provide a signal for the Apollo 12 PSE.

Name Notes
CPLEE Stored on the first subpackage.
CCGE Stored on the first subpackage.
Only time the CCGE was flown.
HFE Stored on the first subpackage.
PSE Stored on the first subpackage.

The antenna gimbal assembly was stored on the first subpackage. The stool for the PSE, the ALSEP tools, carrybar, and the Lunar drill was stored on the subpallet. The HTC was stored on the second subpackage.

Apollo 14

Layout for Apollo 14's ALSEP
Name Picture Notes
ASE ALSEP AS14-67-9361.jpg
ALSEP AS14-67-9374.jpg
The above image shows the mortar device. The lower one shows Lunar Module Pilot Edgar Mitchell operating the Thumper.
The mortar, geophones, and Thumper was stored on the first subpackage.
Thirteen of the twenty-two Thumper charges were fired successfully.[5] Because of concerns about the deployment of the mortar, none of the four explosives were fired. There was an attempt to fire them at the end of the ALSEP's operational lifetime, but the charges failed to work after being dormant for so long.
CPLEE ALSEP AS14-67-9364.jpg Stored on the first subpackage.
LRRR ALSEP AS14-67-9386.jpg Stored in Quad I of the LM and brought to the ALSEP site separately.
PSE ALSEP AS14-67-9362.jpg Stored on the first subpackage.
SIDE/CCIG ALSEP AS14-67-9373.jpg Stored on the subpallet.
The SIDE is in the upper-left corner while the CCIG is in the center of the picture.

The antenna gimbal assembly was stored on the subpallet. The stool for the PSE, the ALSEP tools, carrybar, and HTC was stored on the second subpackage.

Apollo 15

Layout of Apollo 15's ALSEP
Name Picture Notes
HFE ALSEP AS15-92-12416.jpg The center of the picture shows the electronics box and the two wires going to each of the probes.
Stored on the second subpackage.
During the drilling operations for each of the holes, more resistance was encountered than expected. As a result, the probes could not be inserted to their planned depth. Accurate scientific data could not be obtained from the Apollo 15 experiment until the data could be compared to Apollo 17's.
LRRR ALSEP AS15-85-11468.jpg Stored in Quad III of the LM and brought to the ALSEP site via the Lunar rover.
LSM ALSEP AS15-86-11588.jpg Stored on the first subpackage.
PSE ALSEP AS15-86-11591.jpg Stored on the first subpackage.
SWS ALSEP AS15-86-11593.jpg Stored on the first subpackage.
SIDE/CCIG ALSEP AS15-86-11596.jpg The SIDE is on the left while the CCIG is attached on the right.
Stored on the subpallet.
Note the tilt of the SIDE. This was necessary because of the latitude of Apollo 15's landing site. Also note the boom connecting the SIDE and CCIG. This redesign was done because earlier crews complained about the difficulty to deploy the SIDE/CCIG when only wires connected the two experiments.

The antenna gimbal assembly was stored on the subpallet. The ALSEP tools, carrybar, and stool for the PSE was stored on the second subpackage.

Apollo 16

Layout for Apollo 16's ALSEP
Name Picture Notes
ASE[1] ALSEP AS16-113-18377.jpg Apollo 14 Joe Engle training.jpg The pictures show the mortar pack (top) and thumper (bottom). Note the new mortar base used to improve the experiment after problems were encountered with Apollo 14's.
The mortar, geophones, and Thumper were stored on the first subpackage. The base of the mortar box was stored on the second subpackage.
After three of the explosives were fired successfully, the pitch sensor went off scale. It was then decided not to fire the fourth explosive. Nineteen of the Thumper charges were successfully fired.[5]
HFE ALSEP AS16-113-18369.jpg The picture shows the one heat flow probe that was successfully deployed.
Stored on the second subpackage.
After successfully deploying one of the probes, Commander John Young inadvertently caught his foot on the cable to the experiment from the Central Station. The cable was pulled out of its connector on the Central Station. Although some technicians and astronauts on Earth believed that a repair was feasible, mission control ultimately decided that the time necessary for a repair could be put to better use on other work, and so the experiment was terminated.
LSM ALSEP AS16-113-18374.jpg Stored on the first subpackage.
PSE ALSEP AS16-113-18346.jpg Stored on the first subpackage.

Apollo 17

Layout of Apollo 17's ALSEP
Name Picture Notes
HFE ALSEP AS17-134-20497.jpg One of the probes can be seen in the foreground while the electronics box and the other probe can be seen in the background.
LACE ALSEP AS17-134-20498.jpg
LEAM ALSEP AS17-134-20500.jpg The LEAM is in the foreground. The scientific validity of this experiment has been called into question because of some odd data.
LSPE ALSEP AS17-136-20704.jpg
150px
NASA LSPE geophones Apollo17.jpg
The upper image shows the antenna for the LSPE in the foreground. The middle image shows one of the charges. The bottom image shows the geophones.[5]
LSG ALSEP AS17-134-20501.jpg Because of a design error, the experiment could not accomplish what it was designed for.

After Apollo

The ALSEP system and instruments were controlled by commands from Earth. The stations ran from deployment until the support operations were terminated on 30 September 1977 due primarily to budgetary considerations. Additionally, by 1977 the power packs could not run both the transmitter and any other instrument. However, the transmitters were not switched off,[9] and all 5 ALSEPs were observed by the Soviet radio telescope RATAN-600 between 18 October and 28 November 1977, after the official termination of their mission.[10]

ALSEP systems are visible in several images taken by the Lunar Reconnaissance Orbiter during its orbits over Apollo landing sites.

See also

Notes

^ Encyclopedia Astronautica website, 14 February 1966 entry.

References

  1. 1.0 1.1 Apollo 16 Mission Science Experiments - Active Seismic, Lunar and Planetary Institute (accessed 11 Dec 2015)
  2. Experiment Operations During Apollo EVAs (accessed 11 Dec 2015)
  3. Labs, Sandia (2019-07-15). "Sandia National Laboratories: May 23, 1969: Sandia Helps in Apollo Moon Program" (in en). https://www.sandia.gov/news/publications/labnews/articles/special/Apollo_11/Sandia_helps_Apollo.html. 
  4. Boyd Bolts (Apollo Lunar Surface Journal)
  5. 5.0 5.1 5.2 5.3 5.4 Brzostowski and Brzostowski, pp 414-416
  6. Sarah Stanley (25 June 2018). "The Case of the Missing Lunar Heat Flow Data Is Finally Solved". Journal of Geophysical Research: Planets. https://eos.org/research-spotlights/the-case-of-the-missing-lunar-heat-flow-data-is-finally-solved. 
  7. Lunar Ejecta and Meteorites
  8. 8.0 8.1 Don L. Lind oral history transcript, NASA Johnson Space Center Oral History Project, 27 May 2005.
  9. Charles Redmond. National Aeronautics and Space Administration lyndon B. JohMon Spece Cent. Houston, Texas 77058 AC713 483-5111 Charles Redmond RELEASE NO: 77-47. September 12, 1977. "...Even though the experiments will be terminated, the transmitters will continue to serve Earth as a reference point in astronomy. The Jet Propulsion Laboratory will continue to use the signals from the ALSEP transmitters to assist in the Lab's deep space work including geodetic and astrometric studies and spacecraft navigation. Also, the motion of the lunar orbit will be accurately monitored against a background of extra-galactic stars to test gravitational theories".
  10. Naugolnaia, M. N.; Spangenberg, E. E.; Soboleva, N. S.; Fomin, V. A. Determination of selenographic coordinates of objects by RATAN-600. Pisma v Astronomicheskii Zhurnal, vol. 4, Dec. 1978, p. 562-565. (Soviet Astronomy Letters, vol. 4, Nov.-Dec. 1978, p. 302-303). Free to read

Bibliography

  • Brzostowski, M.A., and Brzostowski, A.C., Archiving the Apollo active seismic data, The Leading Edge, Society of Exploration Geophysicists, April, 2009.

External links