Q-PACE

Q-PACE
Names	Cu-PACE
Mission type	Astrophysics
Operator	University of Central Florida
COSPAR ID	2021-002X
SATCAT no.	473XX
Website	sciences.ucf.edu/physics/microgravity/q-pace/
Mission duration	- (planned: 3 years)
Spacecraft properties
Spacecraft	Q-PACE
Spacecraft type	CubeSat
Bus	3U CubeSat
Manufacturer	University of Central Florida
Launch mass	3 kg (6.6 lb)
Dimensions	10 × 10 × 37.6 cm
Power	Solar panels, rechargeable battery
Start of mission
Launch date	17 January 2021, 19:39:00 UTC
Rocket	LauncherOne ; (air launch to orbit)
Launch site	Mojave Air and Space Port
Contractor	Virgin Galactic
Orbital parameters
Reference system	Geocentric orbit
Regime	Low Earth orbit
Altitude	500 km
Period	100.0 minutes
	Small Innovative Missions for Planetary Exploration (SIMPLEx) Program LunaH-Map →

Last updated April 14, 2024

CubeSat Particle Aggregation and Collision Experiment (Q-PACE) or Cu-PACE,^[4] was an orbital spacecraft mission that would have studied the early stages of proto-planetary accretion by observing particle dynamical aggregation for several years.^[5]

Current hypotheses have trouble explaining how particles can grow larger than a few centimeters. This is called the meter size barrier. This mission was selected in 2015 as part of NASA's ELaNa program, and it was launched on 17 January 2021.^[6] As of March 2021, however, contact has yet to be established with the satellite, and the mission was feared to be lost. The mission was eventually terminated.

Overview

Q-PACE was led by Joshua Colwell at the University of Central Florida and was selected NASA's CubeSat Launch Initiative (CSLI) which placed it on Educational Launch of Nanosatellites ELaNa XX.^[7] The development of the mission was funded through NASA's Small Innovative Missions for Planetary Exploration (SIMPLEx) program.^[5]^[8]

Observations of the collisional evolution and accretion of particles in a microgravity environment are necessary to elucidate the processes that lead to the formation of planetesimals (the building blocks of planets), km-size, and larger bodies, within the protoplanetary disk. The current hypotheses of planetesimal formation have difficulties in explaining how particles grow beyond one centimeter in size, so repeated experimentation in relevant conditions is necessary.^[9]

Q-PACE was to explore the fundamental properties of low‐velocity (< 10 cm/s (3.9 in/s)) particle collisions in a microgravity environment in an effort to better understand accretion in the protoplanetary disk.^[10] Several precursor tests and flight missions were performed in suborbital flights as well as in the International Space Station.^[1]^[11] The small spacecraft does not need accurate pointing or propulsion, which simplified the design.

On 17 January 2021, Q-PACE launched on a Virgin Orbit Launcher One, an air launch to orbit rocket that was dropped from the Cosmic Girl airplane over the Pacific Ocean.^[12] As of March 2021, however, contact was not established with the satellite after it reached orbit,^[13] and the spacecraft was declared lost and the mission ended.

Objectives

The main objective of Q-PACE was to understand protoplanetary growth from pebbles to boulders by performing long-duration microgravity collision experiments. The specific goals are:^[1]

Quantify the energy damping in multi-particle systems at low collision speeds (< 1 mm/s (0.039 in/s) to 10 cm/s (3.9 in/s))
Identify the influence of a size distribution on the collision outcome.
Observe the influence of dust on a multi-particle system.
Quantify statistically rare events: observe a large number of similar collisions to arrive at a probabilistic description of collisional outcomes.

Method

Q-PACE was a 3U CubeSat with a collision test chamber and several particle reservoirs that contain meteoritic chondrules, dust particles, dust aggregates, and larger spherical particles. Particles will be introduced into the test chamber for a series of separate experimental runs.

The scientists designed a series of experiments involving a broad range of particle size, density, surface properties, and collision velocities to observe collisional outcomes from bouncing to sticking as well as aggregate disruption in tens of thousands of collisions.^[9]^[14] The test chamber will be mechanically agitated to induce collisions that will be recorded by on‐board video for downlink and analysis.^[10] Long duration microgravity allows a very large number of collisions to be studied and produce statistically significant data.^[1]

Related Research Articles

<span class="mw-page-title-main">Planetesimal</span> Solid objects in protoplanetary disks and debris disks

Planetesimals are solid objects thought to exist in protoplanetary disks and debris disks. Believed to have formed in the Solar System about 4.6 billion years ago, they aid study of its formation.

A small satellite, miniaturized satellite, or smallsat is a satellite of low mass and size, usually under 1,200 kg (2,600 lb). While all such satellites can be referred to as "small", different classifications are used to categorize them based on mass. Satellites can be built small to reduce the large economic cost of launch vehicles and the costs associated with construction. Miniature satellites, especially in large numbers, may be more useful than fewer, larger ones for some purposes – for example, gathering of scientific data and radio relay. Technical challenges in the construction of small satellites may include the lack of sufficient power storage or of room for a propulsion system.

The Space Test Program (STP) is the primary provider of spaceflight for the United States Department of Defense (DoD) space science and technology community. STP is managed by a group within the Advanced Systems and Development Directorate, a directorate of the Space and Missile Systems Center of the United States Space Force. STP provides spaceflight via the International Space Station (ISS), piggybacks, secondary payloads and dedicated launch services.

The NASA Launch Services Program (LSP) is responsible for procurement of launch services for NASA uncrewed missions and oversight of launch integration and launch preparation activity, providing added quality and mission assurance to meet program objectives. LSP operates under the NASA Space Operations Mission Directorate (SOMD).

Technology Education Satellite (TechEdSat) is a successful nano-sat flight series conducted from the NASA Ames Research Center in collaboration with numerous universities. While one of the principal aims has been to introduce young professionals and university students to the practical realm of developing space flight hardware, considerable innovations have been introduced. In addition, this evolving flight platform has tested concepts for Low Earth Orbit (LEO) sample return, as well as planetary nano-sat class mission concepts.

Nanoracks LLC is a private in-space services company which builds space hardware and in-space repurposing tools. The company also facilitates experiments and launches of CubeSats to Low Earth Orbit.

<span class="mw-page-title-main">PhoneSat</span>

PhoneSat is an ongoing NASA project of building nanosatellites using unmodified consumer-grade off-the-shelf smartphones and Arduino platform and launching them into Low Earth Orbit. This project is part of NASA's Small Spacecraft Technology Program and was started in 2009 at NASA Ames Research Center.

Lunar IceCube is a NASA nanosatellite orbiter mission that was intended to prospect, locate, and estimate amount and composition of water ice deposits on the Moon for future exploitation. It was launched as a secondary payload mission on Artemis 1, the first flight of the Space Launch System (SLS), on 16 November 2022. As of February 2023 it is unknown whether NASA team has contact with satellite or not.

NG-11, previously known as OA-11, is the twelfth flight of the Northrop Grumman robotic resupply spacecraft Cygnus and its eleventh flight to the International Space Station under the Commercial Resupply Services (CRS-1) contract with NASA. The mission launched on 17 April 2019 at 20:46:07 UTC. This is the last mission from the extended CRS-1 contract; follow-up missions are part of the CRS-2 contract. Cygnus NG-11 was also the first mission to load critical hardware onto Cygnus within the last 24 hours prior to launch, a new Antares feature.

SpaceX CRS-19, also known as SpX-19, was a Commercial Resupply Service mission to the International Space Station. The mission is contracted by NASA and was flown by SpaceX on a Falcon 9 rocket.

Educational Launch of Nanosatellites (ELaNa) is an initiative created by NASA to attract and retain students in the science, technology, engineering and mathematics disciplines. The program is managed by the Launch Services Program (LSP) at NASA's Kennedy Space Center in Florida.

The Damping and Vibrations Experiment (DAVE), also known as CP-7, is a technology demonstration nanosatellite developed by the PolySat laboratory at California Polytechnic State University, San Luis Obispo, in collaboration with Northrop Grumman. The spacecraft adheres to the 1U CubeSat standard and is currently in a 93° inclination orbit. DAVE will study the vibration of metal beams damped with tungsten particles in a micro-gravity environment. The test elements are driven by a piezoelectric actuator, and vibration data is collected via an accelerometer at the tip of each beam. DAVE was launched into a high-inclination orbit as a secondary payload on the final flight of the Delta II launch vehicle as part of the ELaNa-18 ride-share mission with NASA's ICESat-2 primary payload. The launch occurred out of Vandenberg Air Force Base, California on September 15 at 6:02 AM local time. DAVE was deployed alongside three other CubeSat spacecraft: University of Central Florida's SurfSat, and two ELFIN spacecraft from University of California, Los Angeles.

TROPICS(Time-Resolved Observations of Precipitation structure and storm Intensity with a Constellation of Smallsats) is a NASA constellation of six small satellites, 3U CubeSats, that will measure temperature and moisture profiles and precipitation in tropical systems with unprecedented temporal frequency. This data will enable scientists to study the dynamic processes that occur in the inner core of the storm resulting in rapid genesis and intensification. William Blackwell of the Massachusetts Institute of Technology's Lincoln Laboratory in Lexington, Massachusetts is the principal investigator. The constellation was initially planned to be delivered to orbit on three launches between June and July 2022. Due to the loss of the first two satellites after a launch failure in June 2022, the first satellites were delivered to orbit aboard a Rocket Lab Electron rocket on 7 May 2023.

RSat-P is a microsatellite built by the United States Naval Academy (USNA) in Annapolis, Maryland. The small spacecraft is a 3U CubeSat intended to demonstrate capabilities for minor in-orbit repair of a much larger, conventional spacecraft.

NG-15, previously known as OA-15, was the fifteenth launch of the Northrop Grumman robotic resupply spacecraft Cygnus and its fourteenth flight to the International Space Station (ISS) under the Commercial Resupply Services (CRS) contract with NASA. The mission launched on 20 February 2021 at 17:36:50 UTC. This is the fourth launch of Cygnus under the CRS-2 contract.

SpaceX CRS-26, also known as SpX-26, was a Commercial Resupply Service mission to the International Space Station (ISS) launched on 26 November 2022. The mission was contracted by NASA and flown by SpaceX using a Cargo Dragon. This was the sixth flight for SpaceX under NASA's CRS Phase 2 contract awarded in January 2016.

<span class="mw-page-title-main">Small Innovative Missions for Planetary Exploration</span> NASA program

Small Innovative Missions for Planetary Exploration (SIMPLEx) is a planetary exploration program operated by NASA. The program funds small, low-cost spacecraft for stand-alone planetary exploration missions. These spacecraft are intended to launch as secondary payloads on other missions and are riskier than Discovery or New Frontiers missions.

SpaceX CRS-27, also known as SpX-27, was a Commercial Resupply Service mission to the International Space Station (ISS) launched on 15 March 2023. The mission was contracted by NASA and was flown by SpaceX using Cargo Dragon C209. This was the seventh flight for SpaceX under NASA's CRS Phase 2.

References

1 2 3 4 5 6 Q-PACE: the CubeSat Particle Aggregation and Collision Experiment Archived 19 January 2019 at the Wayback Machine Josh Colwell, Julie Brisset, Addie Dove, Larry Roe, Jürgen Blum; University of Central Florida, August 2017
↑ Krebs, Gunter. "LauncherOne (L2)". Gunter's Space Page. Retrieved 7 August 2019.
↑ Herrera, Chabeli (26 October 2018). "Virgin Orbit releases the first photos of its rocket-plane hybrid, LauncherOne" . Orlando Sentinel . Archived from the original on 7 August 2019. Retrieved 7 August 2019.
↑ "NASA Announces Sixth Round of CubeSat Space Mission Candidates" (Press release). SpaceRef. 6 February 2015. Retrieved 17 January 2021.^{[ permanent dead link ]}
1 2 NASA, Small Innovative Missions for Planetary Exploration Program Abstracts of selected proposals, August 8, 2015. Retrieved Nov. 17, 2022.
↑ "Upcoming ELaNa CubeSat Launches". NASA. 6 May 2020. Retrieved 7 May 2020. This article incorporates text from this source, which is in the public domain .
↑ "NASA's Space Cubes: Small Satellites Provide Big Payoffs". NASA. 8 September 2015. Archived from the original on 17 June 2019. Retrieved 19 April 2020. This article incorporates text from this source, which is in the public domain .
↑ Clark, Stephen (5 August 2019). "NASA's first interplanetary smallsats may struggle to stay under cost caps". Spaceflight Now. Archived from the original on 7 August 2019. Retrieved 7 August 2019.
1 2 CubeSat Particle Aggregation Collision Experiment (Q-PACE): Design of a 3U CubeSat mission to investigate planetesimal formation Stephanie Jarmak, Julie Brisset, Joshua Colwell, Adrienne Dove, et al.; Acta Astronautica Volume 155, February 2019, Pages 131-142 doi : 10.1016/j.actaastro.2018.11.029
1 2 Q‐PACE: the CubeSat Particle Aggregation and Collision Experiment. Archived 17 December 2019 at the Wayback Machine Josh Colwell, Julie Brisset, Addie Dove, Larry Roe, January 2016
↑ Planetesimal Formation Archived 17 April 2019 at the Wayback Machine Center for Microgravity Research, University of Central Florida Accessed on 17 April 2019.
↑ Burghardt, Thomas (17 January 2021). "LauncherOne reaches orbit on second attempt with NASA CubeSats". NASASpaceFlight.com. Retrieved 17 May 2023.
↑ Foust, Jeff (26 March 2021). "NASA looking for earlier launch of lunar orbiter smallsat mission". SpaceNews . Retrieved 26 March 2021. Q-PACE launched Jan. 17 as part of the Launch Demo 2 mission by Virgin Orbit's LauncherOne. However, Glaze said that, since launch, controllers have yet to make contact with Q-PACE. "There's dwindling hopes on Q-PACE," she said.
↑ Krebs, Gunter. "Q-PACE (Cu-PACE)". Gunter's Space Page. Archived from the original on 17 April 2019. Retrieved 7 August 2019.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Colwell-Dove_2017-1] 1 2 3 4 5 6 Q-PACE: the CubeSat Particle Aggregation and Collision Experiment Archived 19 January 2019 at the Wayback Machine Josh Colwell, Julie Brisset, Addie Dove, Larry Roe, Jürgen Blum; University of Central Florida, August 2017

[2] Krebs, Gunter. "LauncherOne (L2)". Gunter's Space Page. Retrieved 7 August 2019.

[hybrid_launch_2018-3] Herrera, Chabeli (26 October 2018). "Virgin Orbit releases the first photos of its rocket-plane hybrid, LauncherOne" . Orlando Sentinel . Archived from the original on 7 August 2019. Retrieved 7 August 2019.

[CU-PACE-4] "NASA Announces Sixth Round of CubeSat Space Mission Candidates" (Press release). SpaceRef. 6 February 2015. Retrieved 17 January 2021.^{[ permanent dead link ]}

[simplex-2015-5] 1 2 NASA, Small Innovative Missions for Planetary Exploration Program Abstracts of selected proposals, August 8, 2015. Retrieved Nov. 17, 2022.

[ELaNa-6] "Upcoming ELaNa CubeSat Launches". NASA. 6 May 2020. Retrieved 7 May 2020. This article incorporates text from this source, which is in the public domain .

[PR-7] "NASA's Space Cubes: Small Satellites Provide Big Payoffs". NASA. 8 September 2015. Archived from the original on 17 June 2019. Retrieved 19 April 2020. This article incorporates text from this source, which is in the public domain .

[8] Clark, Stephen (5 August 2019). "NASA's first interplanetary smallsats may struggle to stay under cost caps". Spaceflight Now. Archived from the original on 7 August 2019. Retrieved 7 August 2019.

[Acta_Feb_2019-9] 1 2 CubeSat Particle Aggregation Collision Experiment (Q-PACE): Design of a 3U CubeSat mission to investigate planetesimal formation Stephanie Jarmak, Julie Brisset, Joshua Colwell, Adrienne Dove, et al.; Acta Astronautica Volume 155, February 2019, Pages 131-142 doi : 10.1016/j.actaastro.2018.11.029

[Colwell_2016-10] 1 2 Q‐PACE: the CubeSat Particle Aggregation and Collision Experiment. Archived 17 December 2019 at the Wayback Machine Josh Colwell, Julie Brisset, Addie Dove, Larry Roe, January 2016

[11] Planetesimal Formation Archived 17 April 2019 at the Wayback Machine Center for Microgravity Research, University of Central Florida Accessed on 17 April 2019.

[12] Burghardt, Thomas (17 January 2021). "LauncherOne reaches orbit on second attempt with NASA CubeSats". NASASpaceFlight.com. Retrieved 17 May 2023.

[13] Foust, Jeff (26 March 2021). "NASA looking for earlier launch of lunar orbiter smallsat mission". SpaceNews . Retrieved 26 March 2021. Q-PACE launched Jan. 17 as part of the Launch Demo 2 mission by Virgin Orbit's LauncherOne. However, Glaze said that, since launch, controllers have yet to make contact with Q-PACE. "There's dwindling hopes on Q-PACE," she said.

[Gunter_Q-PACE-14] Krebs, Gunter. "Q-PACE (Cu-PACE)". Gunter's Space Page. Archived from the original on 17 April 2019. Retrieved 7 August 2019.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

[14]

v t e ← 2020 Orbital launches in 2021 2022 →
January	Türksat 5A PICS 1, PICS 2, Q-PACE, TechEdSat-7 Tiantong-1 03 Starlink V1.0-L16 (60 satellites) Starlink v1.0 R1 (10 satellites), ION-SCV 002 ( Flock-4s × 8 , SpaceBEE × 12), Capella 3, Capella 4, ICEYE × 3, Hawk × 3, Astrocast × 5, Flock-4s × 40, HYPSO-1 , Kepler × 8, Lemur-2 × 8, PTD-1 , SpaceBEE × 24 Yaogan 31-02 (3 satellites)
February	Kosmos 2549 / Lotos-S1 №4 Starlink V1.0-L18 (60 satellites) TJS 6 Progress MS-16 Starlink V1.0-L19 (60 satellites) Cygnus NG-15 (MMSAT-1, GuaraniSat-1 , Maya-2 , OPUSAT-II , RSP-01 , STARS-EC , WARP-01 ) Yaogan 31-03 (3 satellites) Amazônia-1, SpaceBEE × 12
March	Starlink V1.0-L17 (60 satellites) Starlink V1.0-L20 (60 satellites) Shiyan 9 Yaogan 31-04 (3 satellites) Starlink V1.0-L21 (60 satellites) CAS500-1, Suisen / Fukui Prefectural Satellite, Kepler 6 , Kepler 7 Photon Pathstone, BlackSky Global 9 Starlink V1.0-L22 (60 satellites) OneWeb L5 (36 satellites) Gaofen 12-02
April	Starlink V1.0-L23 (60 satellites) Shiyan 6-03 Soyuz MS-18 SpaceX Crew-2 OneWeb L6 (36 satellites) USA-314 / KH-11 18 Pléiades-Neo 3, Lemur-2 AMANDA-SVANTE, Lemur-2 SPECIAL K Tianhe Starlink V1.0-L24 (60 satellites) Yaogan 34
May	Starlink V1.0-L25 (60 satellites) Yaogan 30-08 (3 satellites) Starlink V1.0-L27 (60 satellites) Starlink V1.0-L26 (52 satellites), Capella 6 USA-315 / SBIRS-GEO 5 HaiYang-2D Starlink V1.0-L28 (60 satellites) Tianzhou 2 OneWeb L7 (36 satellites)
June	Fengyun 4B SpaceX CRS-22 SXM-8 USA-316, USA-317, USA-318 Shenzhou 12 USA-319 / GPS IIIA-05 Yaogan 30-09 (3 satellites) Kosmos 2550 / Pion-NKS №1 Progress MS-17 Brik-II , STORK-4 , STORK-5 Starlink V1.0-R2 (3 satellites), ION-SCV 003 ( SPARTAN ), SHERPA FX2 (Lynk 05, Astrocast × 5, Lemur-2 × 3, SpaceBEE × 12), SHERPA LTE1 ( KSF1 × 4), Capella 5, ICEYE × 4, Hawk × 3, ÑuSat × 4, Lemur-2 × 3, LINCS A , LINCS B , SpaceBEE × 12, SpaceBEE NZ × 4, Tiger-2 , TROPICS Pathfinder
July	OneWeb L8 (36 satellites) Jilin-1 Kuanfu-01B, Jilin-1 Gaofen-03D x 3 Fengyun-3E Tianlian I-05 Yaogan 30-10 (3 satellites) Nauka (European Robotic Arm) Eutelsat Quantum, Star One D2
August	Jilin-1 Mofang-01A† ChinaSat 2E Cygnus NG-16 EOS-03 / GISAT-1† Pléiades Neo 4 OneWeb L9 (34 satellites) TJS-7 SpaceX CRS-23 ( Maya-3 , Maya-4 )
September	Gaofen 5-02 ChinaSat 9B Kosmos 2551 / EO MKA №1 Starlink G2-1 (51 satellites) OneWeb L10 (34 satellites) Inspiration4 Tianzhou 3 Jilin-1 Gaofen-02D Shiyan 10 Landsat 9, CUTE
October	Soyuz MS-19 OneWeb L11 (36 satellites) CHASE Shenzhou 13 Lucy Shijian 21 SES-17, Syracuse 4A QZS-1R Jilin-1 Gaofen-02F Progress MS-18
November	RAISE-2, HIBARI, Z-Sat, DRUMS, TeikyoSat-4, ASTERISC, ARICA, NanoDragon, KOSEN-1 SpaceX Crew-3 CERES x 3 DART (LICIACube) Progress M-UM (Prichal) Yaogan 32-2 (2 satellites) Yaogan 35 (3 satellites)
December	Starlink 24 (48 satellites) Soyuz MS-20 IXPE Ekspress-AMU3 Ekspress-AMU7 Starlink 25 (52 satellites) Türksat 5B SpaceX CRS-24 Inmarsat-6 F1 James Webb Space Telescope
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).