Thermal, Power, Sensors & Instruments — SST Portfolio Cluster¶

SST has funded 15 projects in thermal management, power systems, energy storage, sensors, instruments, and imaging. Unlike propulsion and communications — where multiple SST projects produced commercial products and flight missions — this cluster is predominantly academic research that advanced TRL within labs but rarely produced visible downstream impact. The exception is the U Michigan boomless magnetometer, which published in JGR and is being tested on a CubeSat mission.

Last updated: 2026-04-14 (session 22)

Overview¶

Technology	SST Projects	Key Orgs	Max TRL Achieved	Flight?
Deployable radiators	3	U Dayton, Penn State, Cal State LA	TRL 5 (AMDROHP)	No
Cryocoolers	2	USU (Swenson ×2)	TRL 5	No
Integrated power + thermal	1	UIUC	TRL 5	No
Nano-enhanced power	1	RIT	TRL 5	No
Structural batteries	1	U Miami	TRL 5	No
Low-temp energy storage	1	JPL	TRL 5	No
Alpha/betavoltaic	1	ARC + GRC	TRL 4	No
Boomless magnetometer	1	U Michigan (Moldwin)	TRL 6	Testing on MiTEE
THz receiver	1	ASU (Groppi)	TRL 5	No
Mini FTS spectrometer	1	GSFC	TRL 5	No
Milli-arcsecond imaging	1	UIUC (Kamalabadi)	TRL 6	No

Thermal Management (5 projects)¶

Passively Deployed Radial Radiator (155366)¶

TRL: not reported | Period: 2024-01 → 2025-12
Lead: University of Dayton, OH
States: MD, OH
Very recent project (2024-2025). Passive radial radiator for CubeSat waste heat. No documents or outcomes data available yet.

Outcome: unknown (too recent) | Confidence: speculative

Passive SMA Heat-Pipe Radiators (155365)¶

TRL: not reported | Period: 2024-01 → 2025-12
Lead: Penn State, PA
States: OH, PA
Shape-memory alloy (SMA) heat-pipe radiators that passively deploy using thermal activation. For high-intensity small spacecraft.

Outcome: unknown (too recent) | Confidence: speculative

AMDROHP — Additively Manufactured Deployable Radiator (106830)¶

TRL: 3→5 | Period: 2020-07 → 2024-10
Lead: California State University–Los Angeles (AANAPISI MSI)
PI: Yen J. Kuo | Co-I: Eric Sunada (JPL), Scott Roberts
Destination: Moon and Cislunar
3D-printed deployable radiator with oscillating heat pipes (OHP). Target: 50W dissipation in LEO for CubeSat form factor. Flexible OHP joints with >6 W/K conductance, 5,000 W/m/K effective thermal conductivity.
MSI institution — one of few SST projects at a minority-serving institution.

Outcome: no-visible-outcome | Confidence: speculative

Active CryoCubeSat (91561)¶

TRL: 3→5 | Period: 2015-11 → 2018-10
Lead: USU | PI: Charles M. Swenson
States: CA, MD, UT (ANNH MSI)
Mechanical pumped fluid loop (MPFL) + pulse tube cryocooler for 75–100K detector temperatures. Additive manufacturing for embedded conformal coolant channels.
Same PI as ATACOI [95587] — Charles Swenson runs a persistent cryogenic thermal program at USU. Two SST projects, same research thread.

Outcome: no-visible-outcome (academic) | Confidence: confirmed

Active Thermal Architecture for Cryogenic Optical Instruments — ATACOI (95587)¶

TRL: 3→5 | Period: 2018-03 → 2022-01
Lead: USU | PI: Charles M. Swenson
Destination: Earth
Advanced thermal control for cryogenic electro-optical instruments on CubeSats. Successor to Active CryoCubeSat — same PI, extended research program.
Together with [91561], this represents a 7-year persistent USU cryogenic thermal research thread (2015–2022).

Outcome: no-visible-outcome (academic) | Confidence: confirmed

Power Systems (4 projects)¶

Integrated Power System with Active Thermal Control (91380)¶

TRL: 3→5 | Period: 2015-10 → 2017-12
Lead: UIUC | PI: Alexander Ghosh
States: CA, IL
Carbon fiber solar panels with embedded microvascular fluid channels for combined power generation, energy storage, and active thermal management. Scalable from 6U to 100 kg.
Interesting multifunctional concept but no visible downstream.

Outcome: no-visible-outcome | Confidence: speculative

Nano-Enabled Space Power System (90693)¶

TRL: 4→5 | Period: 2016-08 → 2018-08
Lead: Rochester Institute of Technology | PI: Ryne Raffaelle
States: NY, OH
Nanomaterial-enhanced solar cells, wire harnesses, and lithium-ion batteries. Improved performance without changing physical dimensions.

Outcome: no-visible-outcome | Confidence: speculative

Lightweight Structural Battery Systems (94116)¶

TRL: 3→5 | Period: 2016-08 → 2018-08
Lead: University of Miami | PI: Ryan Kakkainen
States: FL, OH
Carbon fiber + graphitic electrodes in electrolytic polymer = structural elements that double as battery. Reduces mass by combining load-bearing and energy storage functions.
Structural batteries remain an active research area in aerospace but have not reached flight.

Outcome: no-visible-outcome | Confidence: speculative

SmallSat Low-Temperature Energy Storage (91359)¶

TRL: 3→5 | Period: 2013-10 → 2014-12
Lead: JPL | PI: Sharlene Katz
States: CA, CO
Destination: Others Inside the Solar System
Battery/ultra-capacitor hybrid power system for extreme low temperatures. Eliminates battery heaters for deep-space missions.
Short 14-month project. No visible follow-on.

Outcome: no-visible-outcome | Confidence: speculative

Alpha/Betavoltaic Power Sources (10936)¶

TRL: 3→4 | Period: 2011-08 → 2012-03
Lead: ARC + GRC | PI: Eric Clark
Destinations: Moon, Mars, Foundational Knowledge
Assessment of small radioisotope power supplies using direct energy conversion (alpha/betavoltaic) for future NASA missions. Essentially a feasibility study — 7 months.
Closed out March 2012.

Outcome: no-visible-outcome (feasibility study) | Confidence: confirmed

Sensors, Instruments & Imaging (4 projects)¶

Boomless CubeSat Magnetometer (94109)¶

TRL: 3→6 | Period: 2016-08 → 2018-08
Lead: University of Michigan | PI: Mark Moldwin
States: MD, MI
Destinations: Earth, Sun
Quad-Mag: four magnetometer sensors on a single CubeSat card. Blind source separation algorithms identify and subtract spacecraft-generated magnetic noise, eliminating the need for a deployable boom. Science-grade measurements from inside the satellite bus.
Published in JGR Space Physics (2023): Hoffmann, Moldwin, Strabel, Ojeda — "Enabling Boomless CubeSat Magnetic Field Measurements with Quad-Mag" (NTRS 53950636251698).
Being tested on the MiTEE CubeSat (U Michigan Miniature Tether Electrodynamics Experiment).
This is the highest-downstream-impact sensor project in the SST portfolio — peer-reviewed publication + CubeSat flight test.

Outcome: transitioned (published + CubeSat test) | Confidence: suggestive

Terahertz Receiver for Small Satellite Remote Sensing (94030)¶

TRL: 3→5 | Period: 2016-08 → 2018-08
Lead: Arizona State University (ANNH MSI) | PI: Christopher Groppi
States: AZ, CA, OH
Destinations: Earth, Mars, Others Inside the Solar System
Schottky diode THz receiver repackaged using micromachining for CubeSat form factor. 10× mass/volume reduction. Enables remote sensing of water and atomic oxygen (opaque in Earth's atmosphere but scientifically critical).
Groppi is a prominent radio astronomy instrumentalist (ASU Terahertz lab).

Outcome: no-visible-outcome | Confidence: speculative

Mini Fourier-Transform Spectrometer (106803)¶

TRL: 3→5 | Period: 2013-10 → 2015-09
Lead: GSFC | PI: John C. Allen
States: MD, NC
FT spectrometer on a chip — mid-infrared spectral signatures for atmospheric composition, mineralogy, surface processes. Eliminates bulky free-space optics and mechanical scan mirrors.

Outcome: no-visible-outcome | Confidence: speculative

Milli-Arcsecond Imaging with Smallsat Super-Resolution (95523)¶

TRL: 3→6 | Period: 2018-03 → 2022-01
Lead: UIUC | PI: Farzad Kamalabadi
States: IL, MD
Destination: Sun
Computational diffractive optical sensing + formation flying = milli-arcsecond imaging. Unprecedented resolution using photon sieves and advanced image processing. Demonstrated in lab at TRL 6.
NSF also awarded Kamalabadi funding for related work (Award 1936663).
No flight mission or commercial product. Remains in academic research phase.

Outcome: no-visible-outcome (academic) | Confidence: confirmed

Cross-Cutting Findings¶

1. Academic TRL Ceiling at 5–6¶

Every project in this cluster hit TRL 5 or 6 and stopped. No thermal, power, or sensor project reached flight (TRL 7+). The exception is the Quad-Mag magnetometer, which is being tested on MiTEE but hasn't flown independently. This contrasts sharply with propulsion (5 flights) and communications (6+ flights).

2. USU Thermal Thread: 5 SST Projects, 1 Persistent Capability¶

Utah State University has 5 SST projects (the most of any university), clustered around thermal management and propulsion: - [91561] Active CryoCubeSat (Swenson, 2015–2018) - [95587] ATACOI (Swenson, 2018–2022) - [91602] ISAAC solar-panel antenna (Baktur, 2015–2017) - [106834] 3D Printed Hybrid Propulsion (Whitmore, 2020–2025) — transitioned to Marshall HLS - [95587] ATACOI (note: Swenson ran both cryo projects)

Swenson's 7-year cryogenic thermal thread is the academic analog of ARC's institutional capability building. The propulsion work (Whitmore) had visible downstream; the thermal work did not, despite similar TRL advancement.

3. MSI Representation¶

Four MSI-connected projects in this cluster: AMDROHP at Cal State LA (AANAPISI), Active CryoCubeSat at USU (ANNH), THz Receiver at ASU (ANNH), and SCALES at Cal Poly Pomona (HSI + AANAPISI). None produced flights. By contrast, the only MSI with a confirmed flight in the entire SST portfolio is SDSU (Hispanic-Serving Institution) — FIGARO-FT HAB flight Sep 2024 — and that's in the comms/PNT cluster, not thermal/power. See University Academic Outcomes.

4. No Acquisition Targets¶

Unlike propulsion and bus companies, none of the thermal/power/sensor researchers or their institutions became acquisition targets or commercial product lines. The technology stayed in labs. This may reflect the nature of the subsystems: thermal and power are integrator-dependent (you need a mission to fly them), while propulsion and comms have standalone product value.

Smallsat Propulsion — the propulsion cluster (23 projects, 5 flights)
Autonomy, GN&C, Computing — includes RadSat (rad-tolerant computing, flew → lunar surface)
University Academic Outcomes — full university cluster analysis, MSI outcomes
Archetypes — Institutional Capability Builder matches USU pattern

Org pages for this cluster¶

U Dayton — radial radiator (2024, too recent)
Penn State — SMA heat-pipe radiators (2024, too recent)
Cal State LA — AMDROHP 3D-printed radiator
U Miami — structural battery
RIT — nano-enabled power
U Michigan — boomless magnetometer (Moldwin)
ASU Tempe — THz receiver (Groppi)
UIUC — integrated power + milli-arcsecond imaging (Kamalabadi)
USU — 5 SST projects (thermal + propulsion)

Thermal, Power, Sensors & Instruments — SST Portfolio Cluster¶

Overview¶

Thermal Management (5 projects)¶

Passively Deployed Radial Radiator (155366)¶

Passive SMA Heat-Pipe Radiators (155365)¶

AMDROHP — Additively Manufactured Deployable Radiator (106830)¶

Active CryoCubeSat (91561)¶

Active Thermal Architecture for Cryogenic Optical Instruments — ATACOI (95587)¶

Power Systems (4 projects)¶

Integrated Power System with Active Thermal Control (91380)¶

Nano-Enabled Space Power System (90693)¶

Lightweight Structural Battery Systems (94116)¶

SmallSat Low-Temperature Energy Storage (91359)¶

Alpha/Betavoltaic Power Sources (10936)¶

Sensors, Instruments & Imaging (4 projects)¶

Boomless CubeSat Magnetometer (94109)¶

Terahertz Receiver for Small Satellite Remote Sensing (94030)¶

Mini Fourier-Transform Spectrometer (106803)¶

Milli-Arcsecond Imaging with Smallsat Super-Resolution (95523)¶

Cross-Cutting Findings¶

1. Academic TRL Ceiling at 5–6¶

2. USU Thermal Thread: 5 SST Projects, 1 Persistent Capability¶

3. MSI Representation¶

4. No Acquisition Targets¶

Related Pages¶

Org pages for this cluster¶