Polarimeter to Unify the Corona and Heliosphere (PUNCH)

PUNCH satellites being prepared for launch at Vandenberg Space Force Base in January 2025
Names	Explorer · SMEX
Mission type	Heliophysics
Operator	NASA
Website	punch.spaceops.swri.org
Spacecraft properties
Spacecraft type	Orbiters × 4
Bus	Custom, CYGNSS heritage
Manufacturer	Southwest Research Institute (SwRI)
Launch mass	40 kg (88 lb) each 160 kg (350 lb) total
Start of mission
Launch date	27 February 2025 (planned)[1]
Rocket	Falcon 9 Block 5
Launch site	Vandenberg, SLC-4E
Contractor	SpaceX
Orbital parameters
Reference system	Geocentric orbit
Regime	Sun-synchronous, low Earth orbit
Altitude	570 km (350 mi)[2]
Instruments
Narrow Field Imager (NFI) – 1 satellite Wide Field Imagers (WFIs) – 3 satellites
Mission insignia Explorers Program ← IXPE (Explorer 97) TRACERS →

Polarimeter to Unify the Corona and Heliosphere (PUNCH) is a future mission by NASA to study the unexplored region from the middle of the solar corona out to 1 AU from the Sun. PUNCH will consist of a constellation of four microsatellites that through continuous 3D deep-field imaging, will observe the corona and heliosphere as elements of a single, connected system. The four microsatellites were initially scheduled to be launched in October 2023, but were moved to launch alongside (rideshare) the SPHEREx space observatory on a Falcon 9 Block 5 rocket from Vandenberg Space Force Base on scheduled to liftoff on 27 February 2025.^[3][1]

On 20 June 2019, NASA announced that PUNCH and TRACERS were the winning candidates to become the next missions in the agency's Small Explorer program (SMEX).^[4]

PUNCH is led by Craig DeForest at the Southwest Research Institute (SwRI) in Boulder, Colorado. Including launch costs, PUNCH is being funded for no more than US$165 million.^[4]

The stated primary objective of PUNCH is "to fully discern the cross-scale physical processes, from microscale turbulence to the evolution of global-scale structures, that unify the solar corona and heliosphere".^[5] In other words, the mission aims to understand how the solar corona becomes the solar wind.^[6]

The two specific objectives are to understand how coronal structures become the ambient solar wind, and to understand the dynamic evolution of transient structures in the young solar wind.^[5] The Principal Investigator, Craig DeForest, thinks that such closer study will also lead to a better understanding of the causes of solar weather events like coronal mass ejections (CMEs), which can damage satellites and disrupt electrical grids and power systems on Earth.^[2][4]

The more we understand what drives space weather and its interaction with the Earth and lunar systems, the more we can mitigate its effects – including safeguarding astronauts and technology crucial to NASA's Artemis program to the Moon.^[4]

The mission configuration consists of a constellation of four observatories, each carrying one primary instrument.^[7]

• The Narrow Field Imager (NFI) sits on only one spacecraft, and is an externally occulted visible-light coronagraph.
• The Wide Field Imagers (WFIs) are side-looking heliospheric imagers with planar-corral baffles that sit on the remaining 3 spacecraft.
• The NFI spacecraft also carries a student-built instrument, the Student Thermal Energetic Activity Monitor (STEAM). STEAM is a solid-state X-ray spectrometer that views the entire Sun as a point source, to study the physics of coronal heating and solar flares.

The fields of view (FoV) of the 3 WFIs overlap slightly with each other and with the NFI, and the instruments' operation is synchronized. The instruments operate through polarized Thomson-scatter imaging of the transition from corona to heliosphere.^[8] PUNCH integrates images from its constellation of small satellites into a global composite after each orbit, covering ~6 orders of magnitude dynamic range. Through a stream of these images, PUNCH achieves 3D feature localization and accurate deep field imaging.^[9] The mission builds on Cyclone Global Navigation Satellite System (CYGNSS) experience with smallsat constellations.^[10]

To accomplish its science objectives, PUNCH will acquire polarized white-light images over a composite 90° field of view centered on the Sun, i.e. from a few solar radii to 45° from the Sun in all directions. This poses many challenges in data reduction, meaning that the greatest technical challenge of the mission is in ground-processing the images acquired by the four spacecraft.

The PUNCH science objectives require measuring the faint sunlight reflected off electrons contained in the corona and solar wind (the extended K-corona). Ten degrees from the Sun, the K-corona is 1000x fainter than the background stars,^[11] requiring precise photometric calibration across the individual cameras, to measure and remove the background starfield, galaxy, and related features—which constitute 99.9% of the light incident on the cameras. The camera images are co-aligned to within 0.03 pixel RMS, requiring precise measurement of the optical distortion of each lens system. Point spread function effects, such as optical coma, are identified and removed in the PUNCH data reduction pipeline;^[12] and minor photometric errors introduced by data compression are also tracked and eliminated.^[13] Polarimetry of the K-corona is affected by the polarization of the starfield itself,^[14] which required developing a novel formalism to enable background subtraction while preserving linear polarimetry.^[15]

The primary PUNCH data product is background-subtracted, polarimetric images produced by the constellation on a 4 minute cadence; these images are made available to everyone via NASA's SDAC facility and the Virtual Solar Observatory.

SwRI is collaborating with the Naval Research Laboratory (NRL) and the Rutherford Appleton Laboratory in Oxfordshire, England, United Kingdom.

PUNCH, which will operate in low Earth orbit, will work in synergy with NASA's Parker Solar Probe and the ESA's Solar Orbiter.^[2][8]

• Explorer program

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