Aeronomy of Ice in the Mesosphere

NASA satellite of the Explorer program

Aeronomy of Ice in the Mesosphere
Spacecraft properties
AIM (Explorer 90) spacecraft
Names	Explorer 90 AIM SMEX

Mission type	Atmospheric research
Operator	NASA
COSPAR ID	2007-015A
SATCAT no.	31304
Website	aim.hamptonu.edu
Mission duration	26 months (planned) 16 years, 11 months and 15 days (in progress)


Spacecraft	Explorer XC
Spacecraft type	Aeronomy of Ice in the Mesosphere
Bus	LEOStar-2
Manufacturer	Orbital Sciences Corporation
Launch mass	197 kg (434 lb) ^[1]
Dimensions	1.4 × 1.1 m (4 ft 7 in × 3 ft 7 in)


Start of mission
Launch date	25 April 2007, 20:26:03 UTC
Rocket	Pegasus-XL (F38)
Launch site	Vandenberg, Stargazer Runway 12/30
Contractor	Orbital Sciences Corporation
Entered service	2007


Orbital parameters
Reference system	Geocentric orbit
Regime	Sun-synchronous orbit
Perigee altitude	552 km (343 mi)
Apogee altitude	559 km (347 mi)
Inclination	97.90°
Period	95.63 minutes

Instruments
Cosmic Dust Experiment (CDE) Cloud Imaging and Particle Size (CIPS) Solar Occultation for Ice Experiment (SOFIE)
Explorer program ← THEMIS (Explorer 86-89) IBEX (Explorer 91) →

The Aeronomy of Ice in the Mesosphere (AIM or Explorer 90) is a NASA satellite launched in 2007 to conduct a planned 26-month study of noctilucent clouds (NLCs).^[2] It is the ninetieth Explorer program mission and is part of the NASA-funded Small Explorer program (SMEX).

In March 2023, NASA announced that battery power on the spacecraft had declined below the level needed to sustain operation.^[3]

Mission

The scientific purpose of the Aeronomy of Ice in the Mesosphere (AIM) mission is focused on the study of polar mesospheric clouds (PMCs) that form about 80 km (50 mi) above the surface of Earth in summer and mostly in the polar regions of Earth. The overall goal is to resolve why PMCs form and why they vary. AIM expected lifetime was at least two years. AIM measures PMCs and the thermal, chemical and dynamical environment in which they form. This will allow the connection to be made between these clouds and the meteorology of the polar mesospheric summer echoes. This connection is important because a significant variability in the yearly number of noctilucent ("glow in the dark") clouds (NLCs), one manifestation of PMCs, has been suggested as an indicator of global change. The body of data collected by AIM will provide the basis for a rigorous study of PMCs that can be reliably used to study past PMC changes, present trends and their relationship to global change. In the end, AIM will provide an expanded basis for the study of long-term variability in the climate of Earth. The AIM scientific objectives will be achieved by measuring near simultaneous PMC abundances, PMC spatial distributions, cloud particle size distributions, gravity wave activity, cosmic dust influx to the atmosphere needed to study the role of these particles as nucleation sites and precise, vertical profile measurements of temperature, H₂O, OH, CH₄, O₃, CO₂, NO, and aerosols. AIM carries three instruments: an infrared solar occultation differential absorption radiometer, built by the Space Dynamics Laboratory, Utah State University (Solar Occultation for Ice Experiment - SOFIE); a panoramic ultraviolet imager (Cloud Imaging and particle Size Experiment - CIPS); and, an in situ dust detector (Cosmic Dust Experiment - CDE), both designed and built by the Laboratory for Atmospheric and Space Physics, University of Colorado. Ball Aerospace & Technologies Corporation constructed the spacecraft bus and GATS, Inc., Newport News, Virginia, led the data management effort.^[4]^[5]

First seen in 1885, two years after the powerful eruption of the Indonesian volcano Krakatoa, scientists originally thought PMC's formed from the plumes of ash propelled into the sky during that eruption. But the clouds have persisted long after the effects of Krakatoa were felt. These days, some scientists think they are caused by space dust, while others believe that modern-day PMC's are indicators of changing climate of Earth. One thing is for certain: PMC's are shaped by the meteorology of the mesosphere, which does appear to be changing.^[6]

Spacecraft

The AIM satellite is a 197 kg (434 lb), 1.4 × 1.1 m (4 ft 7 in × 3 ft 7 in) spacecraft, powered by two solar panels, carrying three instruments:^[7]

Instruments

Instrument Name	Abbr.	Description and scientific objective
Cosmic Dust Experiment	CDE	The instrument records impacts from cosmic dust particles as they enter Earth's upper atmosphere. The instrument uses fourteen polyvinylidene fluoride detectors, which emit a pulse of charge when impacted by a hypervelocity dust particle (velocity 1 km/s (0.62 mi/s)). A measurement of the value and variability of the cosmic dust input will allow scientists to determine the role the particles have in PMC (Polar Mesospheric Cloud) formation. CDE is a nearly identical replica to the Student Dust Counter on the New Horizons mission.^[8]
Cloud Imaging and Particle Size	CIPS	The instrument has four cameras positioned at different angles, which provide multiple views of the clouds from different angles and will allow a determination of the sizes of the ice particles that make up the cloud,^[9] and can be used to infer gravity waves in the atmosphere.^[10]
Solar Occultation for Ice Experiment	SOFIE	The SOFIE uses solar occultation to measure cloud particles, temperature and atmospheric gases involved in forming the clouds. The instrument will reveal the mixture of chemicals that prompt NLC's formation, as well as the environment in which the clouds form.^[11]

Launch

On 25 April 2007, AIM was launched into a circular 550 km (340 mi) Sun-synchronous orbit by a Pegasus-XL launch vehicle, which was air-launched from the Lockheed L-1011 Stargazer aircraft operated by Orbital Sciences Corporation (OSC).^[12]

References

^ ESA. "AIM (Aeronomy of Ice in the Mesosphere)". Archived from the original on 5 August 2020. Retrieved 31 March 2020.
^ "NASA AIM web page". 6 March 2015. This article incorporates text from this source, which is in the public domain.
^ "NASA's AIM Mission Ends Operational Support". NASA. 16 March 2023. Retrieved 9 September 2023.
^ "Display: Aeronomy of Ice in the Mesosphere (Explorer 90) 2007-015A". NASA. 28 October 2021. Retrieved 7 December 2021. This article incorporates text from this source, which is in the public domain.
^ "Clouds, Clouds, Burning Bright". NASA. 18 April 2011. Retrieved 7 December 2021. This article incorporates text from this source, which is in the public domain.
^ "AIM — NASA Science". NASA. Archived from the original on 24 March 2010. Retrieved 7 December 2021. This article incorporates text from this source, which is in the public domain.
^ Space Dynamics Laboratory (2010). "Programs: AIM – SOFIE". Utah State University Research Foundation. Archived from the original on 19 February 2007. Retrieved 16 March 2010.
^ "Cosmic Dust Experiment (CDE)". Hampton University. 2010. Retrieved 16 March 2010.
^ Russell, James M.; Bailey, Scott M.; Gordley, Larry L.; Rusch, David W.; Horányi, Mihály; Hervig, Mark E.; Thomas, Gary E.; Randall, Cora E.; Siskind, David E.; Stevens, Michael H.; Summers, Michael E.; Taylor, Michael J.; Englert, Christoph R.; Espy, Patrick J.; McClintock, William E.; Merkel, Aimee W. (1 March 2009). "The Aeronomy of Ice in the Mesosphere (AIM) mission: Overview and early science results". Journal of Atmospheric and Solar-Terrestrial Physics. 71 (3–4): 289–299. Bibcode:2009JASTP..71..289R. doi:10.1016/j.jastp.2008.08.011. ISSN 1364-6826.
^ Cora E. Randall; Carstens, J.; France, J. A.; Harvey, V. L.; Hoffmann, L.; Bailey, S. M.; Alexander, M. J.; Lumpe, J. D.; Yue, J.; Thurairajah, B.; Siskind, D. E. (16 July 2017). "New AIM/CIPS global observations of gravity waves near 50-55 km: AIM/CIPS Observations of Gravity Waves". Geophysical Research Letters. 44 (13): 7044–7052. doi:10.1002/2017GL073943. S2CID 133954210.
^ "Solar Occultation For Ice Experiment". GATS INC. 2010. Retrieved 16 March 2010.
^ "AIM Mission - Launch". NASA. 4 June 2007. Archived from the original on 16 March 2010. Retrieved 16 March 2010. This article incorporates text from this source, which is in the public domain.

External links

AIM home
SOFIE Instrument and science description, view or download data
AIM Mission Profile by NASA
Taking AIM at Night-Shining Clouds: 10 Years, 10 Science Highlights

Explorers Program

List of Explorers Program missions

Missions

1958–1992	Explorer 1 2^† 3 4 5^† S-1^† 6 (S-2) 7 (S-1A) S-46A^† 8 S-56^† 9 (S-56A) S-45^† 10 11 (S-15) S-45A^† S-55^† 12 (EPE-A) 13 (S-55A) 14 (EPE-B) 15 (EPE-C) 16 (S-55B) 17 (AE-A) 18 (IMP-A) 19 (AD-A) S-66A (BE-A)^† 20 (IE-A) 21 (IMP-B) 22 (BE-B) 23 (S-55C) 24 (AD-B) 25 (Injun 4, IE-B) 26 (EPE-D) 27 (BE-C) 28 (IMP-C) 29 (GEOS-A) 30 (Solrad 8) 31 (DME-A) 32 (AE-B) 33 (IMP-D) 34 (IMP-F) 35 (IMP-E) 36 (GEOS-B) 37 (Solrad 9) 38 (RAE-A) 39 (AD-C) 40 (Injun 5) 41 (IMP-G) 42 (Uhuru, SAS-A) 43 (IMP-I) 44 (Solrad 10) 45 (SSS-A) 46 (MTS) 47 (IMP-H) 48 (SAS-B) 49 (RAE-B) 50 (IMP-J) 51 (AE-C) 52 (Hawkeye 1) 53 (SAS-C) 54 (AE-D) 55 (AE-E) DADE-A^† DADE-B^† 56 (ISEE-1) 57 (IUE) 58 (HCMM) 59 (ICE) 60 (SAGE) 61 (Magsat) 62 (DE-1) 63 (DE-2) 64 (SME) 65 (CCE) 66 (COBE) 67 (EUVE)
MIDEX	69 (RXTE) 71 (ACE) 77 (FUSE) 78 (IMAGE) 80 (WMAP) FAME 84 (Swift) 85–89 (THEMIS) 92 (WISE) 95 (TESS) 96 (ICON) SPHEREx MUSE HelioSwarm UVEX
SMEX	68 (SAMPEX) 70 (FAST) 73 (TRACE) 74 (SWAS) 75 (WIRE)^† 81 (RHESSI) 83 (GALEX) 90 (AIM) 91 (IBEX) 93 (NuSTAR) 94 (IRIS) GEMS 97 (IXPE) PUNCH TRACERS COSI
UNEX/MO/I	HETE-1^† 72 (SNOE) 76 (TERRIERS)^† 79 (HETE-2) INTEGRAL 82 (CHIPSat) CINDI Suzaku TWINS Hitomi^† NICER GOLD XRISM AWE GUSTO SunRISE EZIE CASE

Proposals

Proposals	FINESSE Arcus OHMIC ASTRE EXCEDE ESCAPE

Green titles indicates active current missions
Grey titles indicates cancelled missions
Italics indicate missions yet to launch
Symbol ^† indicates failure en route or before intended mission data returned

v t e ← 2006 Orbital launches in 2007 2008 →
January	Cartosat-2, SRE-1, Lapan-TUBsat, Pehuensat-1 Progress M-59 NSS-8
February	Beidou-1D THEMIS A, THEMIS B, THEMIS C, THEMIS D, THEMIS E IGS Radar 2, IGS Optical 3V
March	ASTRO, CFESat, FalconSAT-3, MidSTAR-1, NEXTSat, STPSat-1 Skynet 5A, INSAT-4B
April	Soyuz TMA-10 Anik F3 Hai Yang 1B Compass-M1 EgyptSat 1, Saudisat-3, SaudiComsat-3, SaudiComsat-4, SaudiComsat-5, SaudiComsat-6, SaudiComsat-7, CP-3, CP-4, CAPE-1, Libertad 1, AeroCube 2, CSTB-1, MAST AGILE, AAM NFIRE AIM
May	Astra 1L, Galaxy 17 Progress M-60 NigComSat-1 Yaogan 2, Zheda PiXing 1 Globalstar 65, Globalstar 69, Globalstar 71, Globalstar 72 Sinosat-3
June	Kosmos 2427 COSMO-1 STS-117 (ITS S3/4) Ofek-7 TerraSAR-X USA-194 Genesis II Kosmos 2428
July	SAR-Lupe 2 Zhongxing 6B DirecTV-10
August	Progress M-61 Phoenix STS-118 (ITS S5, SpaceHab LSM) Spaceway-3, BSAT-3a
September	INSAT-4CR JCSAT-11 Kosmos 2429 Kaguya (Okina, Ouna) Foton-M No.3, YES2 WorldView-1 CBERS-2B Dawn
October	Intelsat 11, Optus D2 Soyuz TMA-11 USA-195 USA-196 Globalstar 66, Globalstar 67, Globalstar 78, Globalstar 70 Kosmos 2430 STS-120 (Harmony) Chang'e 1 Kosmos 2431, Kosmos 2432, Kosmos 2433
November	SAR-Lupe 3, Rubin-7 USA-197 Yaogan 3 Skynet 5B, Star One C1 Sirius 4
December	Globus-1M No.11L COSMO-2 USA-198 Radarsat-2 USA-199 Horizons-2, Rascom-QAF 1 Progress M-62 Kosmos 2434, Kosmos 2435, Kosmos 2436
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Cubesats are smaller. Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).