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EIRSAT-1

EIRSAT-1, or Educational Irish Research Satellite-1, is a 2U that marked Ireland's inaugural foray into space with its launch on 1 December 2023 aboard a rocket from , . Developed over six years by a team of more than 50 students and academic staff at (UCD), in collaboration with the European Space Agency's (ESA) Fly Your Satellite! programme, the satellite measured approximately 10 cm by 10 cm by 23 cm and operated in at an altitude of around 500 km. It carried three key payloads: the Gamma-ray Module (GMOD) for detecting cosmic gamma-ray bursts and solar flares using a sensor, the ENBIO Module (EMOD) for evaluating novel thermal control coatings on surfaces, and the Wave-Based Control () software for testing advanced attitude determination and control algorithms via . The mission concluded successfully with the satellite's deorbit on 4 September 2025, where it burned up in Earth's atmosphere in adherence to international mitigation standards. The EIRSAT-1 project represented a landmark in and , fostering hands-on for participants while advancing technologies in gamma-ray , thermal management, and control systems. GMOD, co-developed with firm SensL in , successfully detected 10 gamma-ray bursts and 2 solar flares, providing valuable data on cosmic events with a compact, low-power alternative to traditional detectors. EMOD featured temperature-monitored panels coated by ENBIO Ltd. to assess their performance in environments, contributing to improved for extreme conditions. Meanwhile, enabled precise pointing experiments, demonstrating innovative wave-based algorithms that enhanced magnetic torque rod operations without additional hardware. The also incorporated a UCD-built Deployment Module () with UHF and VHF antennas, alongside a coarse , to support reliable communications and basic attitude sensing. Beyond its technical achievements, EIRSAT-1's success has spurred Ireland's ecosystem, inspiring subsequent initiatives such as the COMCUBE-S project and the National Space Strategy for Research, Innovation, and Capabilities Development. Supported by ESA's PRODEX programme and involving over 100 agency experts, the mission underscored the potential of student-led efforts in contributing to Europe's ambitions while building national expertise in design, operations, and .

Development

Project Selection and Funding

In March 2017, a team from University College Dublin (UCD), led by Professor Lorraine Hanlon, submitted a proposal for EIRSAT-1 to the European Space Agency's (ESA) Fly Your Satellite! 2 programme, an educational initiative aimed at enabling university students across Europe to design, build, and launch their own CubeSats. The project was selected in May 2017 as one of six winning proposals out of 27 submissions, following a competitive pitching session at ESA's European Space Research and Technology Centre (ESTEC) in the Netherlands; this marked Ireland's first involvement in such a student-led satellite mission. The selection highlighted the project's alignment with ESA's goals for hands-on space education and technology demonstration. The total budget for EIRSAT-1 amounted to €1,500,000, primarily funded by the through its Education Office and technology programmes (including PRODEX for development), the Research Council (IRC) for student support, and Science Foundation Ireland (SFI) for key components such as the gamma-ray module. UCD served as the lead institution, coordinating with partners like for contributions, while ESA covered launch costs as part of the programme. This financial backing enabled the project's progression from concept to realization, fostering interdisciplinary among students, academics, and .

Timeline and Key Milestones

The EIRSAT-1 project began in 2017 following its selection for the European Space Agency's (ESA) Fly Your Satellite! programme, marking the start of Ireland's first satellite development effort led by University College Dublin (UCD). The team completed the Preliminary Design Review (PDR) in late 2017, validating the initial mission concept, subsystems, and payloads with involvement from both UCD and ESA. In 2018, the project advanced to the Critical Design Review (CDR), which was successfully passed, confirming the detailed engineering designs and paving the way for hardware fabrication and prototyping. This milestone, supported by funding from ESA's Fly Your Satellite! programme, enabled progression to the build phase. Integration and testing activities spanned from 2019 to 2022, encompassing subsystem assembly, functional verification, and rigorous environmental qualification of the Engineering Qualification Model (EQM). Key efforts included antenna testing in 2020 and a comprehensive environmental test campaign at ESA's CubeSat Support Facility in 2021, involving vibration, thermal vacuum, and electromagnetic compatibility trials to simulate space conditions. By mid-2022, the Flight Model underwent final assembly and integration at UCD, followed by additional verification tests to ensure compliance with launch requirements. In 2023, the completed satellite achieved a major delivery milestone, departing in for integration with the launch vehicle at , . The overall development spanned approximately six years, from initial selection to pre-launch readiness, demonstrating sustained collaboration between students, faculty, and ESA experts.

Mission Objectives

Scientific and Technological Goals

EIRSAT-1's primary scientific goal was the detection and characterization of gamma-ray bursts (GRBs), the most energetic explosions in the , using the Gamma-ray Module (GMOD), a novel scintillator-based detector. This payload aimed to observe GRBs in the 50-600 keV energy range, providing data on their spectra, light curves, and positions to contribute to multi-messenger astronomy by enabling coincident detections with other observatories. The mission targeted an expected detection rate of 11-14 GRBs over its lifetime, advancing the of compact gamma-ray instruments for future missions. A key technological objective was the in-orbit testing of advanced thermal protective coatings through the ENBIO Module (EMOD), which evaluated the performance of SolarWhite and SolarBlack materials developed by ENBIO Orbital Technologies. These coatings were designed to manage heat dissipation and absorption in harsh space environments, with the experiment monitoring their resistance to atomic oxygen erosion and thermal cycling in (LEO). The results informed the development of durable materials for next-generation , enhancing efficiency in thermal control systems for small satellites. Additionally, EIRSAT-1 demonstrated a wave-based attitude determination and control system (ADCS) via the Wave-Based Control (WBC) payload, which used interactions between onboard magnetic coils and Earth's magnetic field to achieve precise satellite pointing without reaction wheels. This method, tested for detumbling and stabilization, enabled attitude accuracy within a few degrees, supporting applications like optical communications while minimizing power and mass requirements. The approach represented an innovative, low-complexity alternative to traditional ADCS for resource-constrained CubeSats. These goals were pursued during the mission's actual duration of approximately 21 months in at an initial altitude of around 525 km, aligning with the planned parameters of 9-24 months while adhering to mitigation guidelines.

Educational and Goals

The EIRSAT-1 provided hands-on involvement for more than 50 students at (UCD), primarily postgraduates in physics, engineering, computer science, and mathematics, along with supporting academic and professional staff, in the satellite's design, construction, testing, and operations. This practical experience extended to the development of scientific objectives, such as detection, allowing students to apply interdisciplinary skills in a real-world context. As part of the European Space Agency's (ESA) Fly Your Satellite! programme, EIRSAT-1 aimed to build space engineering skills among participants and address shortages in the Irish space industry by fostering collaborations between student teams and industry partners. The initiative included the creation of a dedicated Spacecraft Operations module at UCD, which trained an additional 20 MSc students in satellite management techniques. Public outreach efforts encompassed regular updates on the project's official website, media engagements such as live launch broadcasts viewed by 64,000 people, and educational activities that engaged 3,000 schoolchildren through mission-themed workshops and the transmission of a student-co-written poem from . These activities sought to inspire broader participation in STEM fields across , highlighting as an accessible career path. In the long term, EIRSAT-1 contributed to establishing a sustainable capability at UCD by demonstrating Ireland's ability to independently develop and operate , paving the way for subsequent university-led missions and placements in the national space sector.

Design and Subsystems

Spacecraft Bus and Structure

EIRSAT-1 is configured as a 2U , measuring 10 cm × 10 cm × 22.7 cm and weighing 2.3 kg, adhering to standard CubeSat specifications for deployment. The core structure is based on a modified (COTS) Clyde Space 2U platform, constructed primarily from anodized aluminum to provide rigidity and lightweight durability suitable for launch and orbital stresses. This aluminum frame includes end caps, support rods, side panels, and corner rails, secured with aluminum alloy screws, enabling a compact yet robust enclosure that withstands the vibrations and thermal variations of (LEO). The structure incorporates a deployable UHF and VHF system via a custom (ADM) integrated into the -Z end cap, featuring coiled copper-beryllium elements that extend post-deployment for reliable communication. Body-mounted solar panels, sourced from AAC Clyde Space, are affixed to the X and Y faces of the aluminum , providing essential power generation while maintaining the satellite's overall constraints. These elements are designed to deploy and operate seamlessly within the , ensuring minimal interference during integration and launch. Payload integration occurs within this constrained volume using a bus architecture, which standardizes the stacking and interfacing of printed circuit boards to facilitate compatibility with protocols and simplify assembly. The three payloads are accommodated alongside core bus components, with the structure modified to secure them firmly without exceeding dimensional limits. Thermal control is achieved through specialized coatings, such as SolarWhite and SolarBlack applied to aluminum panels, along with (MLI) blankets and insulating struts, to regulate temperatures across the -60°C to +100°C range encountered in . This approach ensures structural integrity and operational stability throughout the mission.

Power, Communication, and Control Systems

The of EIRSAT-1, supplied by AAC Clyde Space, manages energy generation, storage, and distribution for the 2U . It features four body-mounted 2U arrays, each equipped with five Spectrolab UTJ triple-junction cells in a 5s1p configuration, delivering an optimal power output of 5 W per array under ideal conditions. These arrays are integrated into the spacecraft structure to harness during orbital daylight, providing the primary power source while the operates in . For eclipse periods, the EPS incorporates a 30 Wh standalone Li-ion in a 2s3p configuration, certified to standards (EP-WI-032), which stores excess energy from the solar arrays and ensures continuous operation by supplying power through the EPS . The , a third-generation 3U model from AAC Clyde Space, regulates voltages at 3.3 V, 5 V, and 12 V with latching current limiting to protect subsystems, enabling efficient power allocation across the 's components. The communication system facilitates , tracking, and command (TT&C) functions using a compact UHF also provided by AAC Clyde Space. It operates on the UHF band for downlink at 430-440 MHz with a data rate of 9.6 kbps employing GMSK modulation and a convolutional encoder compliant with CCSDS standards, allowing reliable of housekeeping data and to ground stations. Uplink commands are received via VHF at 140-150 MHz using AFSK modulation at 1.2 kbps, both adhering to the protocol for error-corrected data exchange. One UHF for downlink and one VHF for uplink, deployed via the Antenna Deployment Module () post-launch, ensure omnidirectional coverage, with the system configured to transmit a every 1.5 minutes during nominal operations to support initial acquisition and ongoing monitoring. Control systems are centered on the On-Board Computer (OBC), a MicroSemi SmartFusion2 system-on-chip featuring a 150 MHz ARM Cortex-M3 processor, which handles data processing, autonomy, and subsystem coordination. Equipped with 8 MB of EDAC-protected MRAM for critical operations, 4 GB of NAND flash storage (with allocations for payload data logging), and a MicroSD slot for additional capacity, the OBC runs flight software developed using the NASA's cFS framework to manage schedules, fault detection, and mode transitions. Attitude determination relies on integrated sensors within the AAC Clyde Space ADCS motherboard, including a fine sun sensor on the +Z face for precise solar vector estimation, coarse sun sensors on the solar arrays for broad-field detection, and triaxial magnetometers and rate gyroscopes to measure Earth's magnetic field and angular velocity for orientation referencing. These sensors provide the foundational data for basic attitude awareness, with the OBC processing inputs via I²C interfaces. Actuation is achieved using three-axis magnetorquers integrated into the ADCS motherboard and solar panel structures to maintain stable pointing without active propulsion. The EPS and communication antennas are mounted directly to the aluminum structure for thermal and mechanical integration.

Payloads

Gamma-ray Module (GMOD)

The Gamma-ray Module (GMOD) serves as the primary scientific payload on EIRSAT-1, a compact scintillation-based detector designed to observe transient astrophysical events, particularly gamma-ray bursts (GRBs), from . The core hardware features a cerium bromide (CeBr₃) scintillator crystal measuring 25 mm × 25 mm × 40 mm, hermetically sealed within an aluminum enclosure topped with a window to protect against environmental hazards while allowing light transmission. This is optically coupled to a 4 × 4 array of photomultipliers (SiPMs) from ON Semiconductor's J-series (model 60035), providing an active detection area of 25.06 mm × 25.06 mm in a common-anode configuration. The SiPM array is read out via a custom SIPHRA (ASIC), which handles charge-sensitive amplification, shaping, and 12-bit digitization of the signals across 16 independent channels. The detection principle exploits the scintillation process in CeBr₃, where incident gamma rays interact via , , or , converting into visible flashes proportional to the deposited . These photons are detected by the SiPMs, which operate as arrays of avalanche photodiodes biased above to provide internal (typically 10⁶), amplifying the weak scintillation signals into measurable electrical pulses without requiring high-voltage tubes. This design enables operation in the 30 keV to 2 MeV range, suitable for capturing the prompt emission spectra of GRBs, which typically peak in the tens to hundreds of keV. The module's low power consumption of approximately 400 mW and mass of 336 g for the detector assembly make it compatible with constraints. Data processing occurs onboard via the EIRSAT-1 spacecraft's processor, which acquires time-tagged event (TTE) data from the 16 channels at up to 1 kHz sampling rates. Event triggering is implemented through configurable algorithms that monitor count rates using single- or double-channel moving averages over user-defined signal and integration windows (e.g., 64 ms to 1 s), generating alerts for potential transients when exceeding statistical thresholds. Upon triggering, the system produces binned light curves, energy spectra, and TTE packets, which are downlinked via the spacecraft's S-band transmitter as part of the housekeeping . This autonomous processing minimizes data volume while prioritizing scientifically valuable events. The GMOD is integrated at the +Z face of the EIRSAT-1 bus to maximize exposure during nominal pointing modes. Calibration of GMOD involves ground-based measurements with standard radioactive sources such as ²⁴¹Am (59.4 keV), ¹³⁷Cs (662 keV), and ⁶⁰Co (1.17 and 1.33 MeV), positioned at the crystal center or endcap to map channels to energy via a : E = 3.56 \times 10^{-5} \times \text{channel}^2 + 0.42 \times \text{channel}. compensation is achieved using an embedded PT100 resistance sensor, with SiPM bias voltages adjustable from -25 V to -28.3 V via a to maintain stability across -20°C to +40°C. The flight model's energy resolution is 7.07% (FWHM) at 662 keV, fitted empirically as \text{FWHM (\%)} = \frac{0.6294}{\sqrt{E}} + 6.8994 \times 10^{-3}, supporting of transients. Sensitivity specifications, derived from Monte Carlo simulations using the MEGAlib toolkit with a detailed EIRSAT-1 mass model, yield a sky-averaged effective area of approximately 10 cm² across the operational energy band, peaking at tens to hundreds of keV. This enables detection of GRBs with fluences as low as 2 photons cm⁻² in the 50–300 keV range, projecting approximately 18 detections per year at >10σ significance during a one-year , assuming a 60% observing and typical GRB populations. The prioritizes robustness to orbital radiation backgrounds, with collimation provided by the structure to suppress off-axis noise.

ENBIO Module (EMOD)

The ENBIO Module (EMOD) is a experiment designed to characterize the degradation of novel oxide-based thermal coatings, SolarWhite and SolarBlack, under the harsh conditions of , including exposure to atomic oxygen, ultraviolet radiation, and thermal cycling. Developed by students at in collaboration with ENBIO Ltd., an Irish company specializing in spacecraft surface treatments, EMOD aims to provide critical data on the long-term performance of these coatings for future satellite applications. SolarWhite and SolarBlack, which have already been incorporated into the European Space Agency's mission, offer high solar reflectance and low emittance (for SolarWhite) or high emittance and low solar absorptance (for SolarBlack), making them promising for passive thermal control systems. The hardware of EMOD consists of a Coupon Assembly () mounted on the +Z face of the EIRSAT-1 , featuring four aluminum coupons (each × × 1 mm, made from Al2024-T3 alloy) exposed directly to the . Two coupons are coated with SolarBlack and two with SolarWhite, arranged in a and thermally isolated from the structure using PEEK , a baseplate, and to ensure accurate exposure without interference from the 's thermal profile. Resistance temperature detectors (RTDs) are affixed to the underside of each coupon to monitor temperature variations in real-time, enabling in-orbit assessment of thermal behavior, while the of EIRSAT-1 facilitates direct interaction with oxygen . Performance evaluation relies on pre-flight and in-orbit comparisons of key properties, including solar absorptivity (α), thermal emissivity (ε), and mass loss due to environmental . In-orbit from the RTDs allows calculation of α/ε ratios through thermal balance analysis during orbital cycles. This approach, supported by ENBIO Ltd.'s expertise, validates the coatings' suitability for industrial-scale use in next-generation thermal management, potentially reducing reliance on systems.

Wave-Based Control (WBC)

The payload on EIRSAT-1 represents an innovative application of to satellite attitude dynamics, specifically tailored for detumbling and precise pointing maneuvers using only magnetic actuation. This approach avoids the need for momentum storage devices like reaction wheels, relying instead on the interaction between the spacecraft and to generate corrective torques. Developed by the Dynamics and Control Group at (UCD), WBC treats the satellite's as a wave propagation problem, where control inputs launch "waves" that propagate through the system and are absorbed upon return to suppress vibrations and achieve rest-to-rest maneuvers without detailed modeling of the satellite's flexible modes. At the hardware level, utilizes three orthogonal magnetic torquer coils integrated into the EIRSAT-1 structure, each capable of producing a moment to interact with the and induce rotation about the respective axes. These torquers, driven by the onboard power system, enable underactuated in low-Earth where the provides a time-varying reference for generation. The system processes inputs from attitude determination sensors to compute the required moments in , ensuring the can perform 3-axis stabilization without accumulating . The core algorithm employs a pseudowave formulation to decompose the measured attitude and angular velocity into outgoing and returning wave components at the control interface, allowing for precise cancellation of disturbances and boundary reflections. This formulation, rooted in one-dimensional wave mechanics extended to rigid-body rotations, uses transfer functions to filter and recombine waves for damping and positioning, achieving design pointing accuracy of less than 5 degrees. Robust to variations in system parameters, such as up to 30% changes in elastic properties, the algorithm avoids traditional modal analysis and mode truncation errors common in flexible spacecraft control. Software implementation occurs on EIRSAT-1's onboard computer (OBC), where the WBC code runs as a dedicated module within the flight , interfacing directly with the determination and (ADCS) for sensor data acquisition and actuator commands. This real-time execution, developed using tools like /, ensures low computational overhead suitable for the CubeSat's resource constraints. The WBC briefly integrates with basic ADCS sensors, including coarse and fine sun sensors, magnetometers, and rate gyroscopes, to provide the necessary attitude estimates for wave decomposition. Extensive ground testing in UCD's Helmholtz cage facility validated the implementation prior to launch.

Launch

Pre-Launch Preparation

The Engineering Qualification Model (EQM) of EIRSAT-1 underwent environmental testing from 13 September to 15 October 2021 at ESA's CubeSat Support Facility in Redu, , including vibration tests, thermal vacuum cycles from -20°C to +50°C, and electromagnetic compatibility assessments. These confirmed compliance with mission requirements and resolved minor anomalies. Payload integration for the Flight Model (FM) occurred at University College Dublin (UCD) in 2022, culminating in full assembly by July of that year, where the Gamma-ray Module (GMOD), ENBIO Module (EMOD), Wave-Based Control (WBC) payload, and Antenna Deployment Module were incorporated into the Clyde Space 2U bus structure. The FM then underwent environmental testing from 25 July to 19 August 2022 at ESA's CubeSat Support Facility in ESEC-Galaxia, Belgium, including vibration testing with an electrodynamic shaker and thermal vacuum testing with bake-out to 58°C and temperature cycling to simulate space conditions. The testing completed successfully, after which the satellite returned to UCD for final functional tests. Software development, utilizing Bright Ascension's GenerationOne Flight Software Development Kit (FSDK) with on the onboard computer, included final uploads and verifications in early 2023 to load primary operational images, backup configurations, and failsafe modes, ensuring autonomous operations for activation and data handling. Post-integration functional tests in validated communication links, power distribution, and subsystem interoperability, with dimensions measured at 10 × 10 × 22.7 cm and mass at 2.4 kg, meeting standards. In late November 2023, the fully assembled was shipped from Ireland to , , for integration into the Falcon 9's 425 Project rideshare mission dispenser. Upon arrival, technicians performed mating operations to secure the satellite within the deployer, followed by final health checks including power-on diagnostics, RF signal verifications, and leak tests to confirm structural integrity and operational readiness. Concurrently, the UCD student team, supported by ESA's Fly Your Satellite! programme, underwent intensive training at ESA's (ESOC) in , , from October 23 to 27, 2023, simulating anomaly responses, command sequencing, and data analysis in the main to prepare for post-deployment operations.

Launch Event and Deployment

EIRSAT-1 launched on 1 December 2023 at 18:19 UTC aboard a SpaceX Falcon 9 Block 5 rocket from Space Launch Complex 4E (SLC-4E) at Vandenberg Space Force Base in California. The mission, known as the 425 Project, primarily carried a South Korean reconnaissance satellite alongside multiple rideshare payloads, including EIRSAT-1 as Ireland's inaugural satellite. Rigorous pre-launch testing had confirmed the satellite's readiness for integration and flight. Approximately 90 minutes after liftoff, EIRSAT-1 was successfully deployed from the rocket's dispenser into a at an altitude of around 520 km. This , with an inclination near 98 degrees, provided the stable lighting conditions essential for the satellite's experimental payloads. Initial contact with EIRSAT-1 was confirmed on 2 December 2023 through the project's ground station network, including the primary facility at , verifying the satellite's health and orbital insertion. The beacon signal at 437.1 MHz was received shortly after deployment, marking the transition to operational status.

Operations

Commissioning Phase

Following its deployment from the SpaceX rocket on 1 December 2023, EIRSAT-1 entered the commissioning phase, during which the ground operations team at verified the satellite's health and functionality. The first signal acquisition occurred within hours of deployment, with the initial beacon received around 20:28 UTC over the , confirming basic and orbital parameters. Formal command contact with the ground station was established on 2 December 2023, allowing the team to monitor initial operations. Antenna deployment via the custom Antenna Deployment Module began approximately 45 minutes after orbital injection, around 20:34 UTC on 1 December 2023, with successful extension of the antennas confirmed through subsequent by early December. The body-mounted panels required no physical extension but were verified functional by mid-December 2023, as power generation from the Electrical Power Subsystem () stabilized and supported nominal battery charging. Subsystem checkouts proceeded systematically in the first weeks, confirming the On-Board Computer (OBC) processed commands reliably, the Communications (COMMS) subsystem maintained uplink and downlink integrity, and the delivered expected voltage and current levels. Basic (ADCS) functionality was tested, including detumbling the from a post-deployment spin rate that peaked at about 50 degrees per second (initially 5 degrees per second) using magnetic torquers, achieving stability by mid-December 2023. The payload activation sequence commenced with the Gamma-ray Module (GMOD), prioritized for its primary scientific role in detecting gamma-ray bursts; initial power-up and calibration were performed in December 2023 to align sensor parameters and verify detector response, followed by activation of the ENBIO Module (EMOD) and Wave-Based Control () software payload. This phase, lasting several weeks, ensured all systems transitioned smoothly to operational mode without major anomalies.

In-Orbit Timeline

Following the successful completion of the commissioning phase, which verified all subsystems and enabled progression to nominal operations, EIRSAT-1 entered early in-orbit activities in early 2024. By March 15, 2024, the satellite had achieved a significant milestone of 100 days in space, during which it completed over 1,500 orbits and traveled approximately 65 million kilometers. This period focused on stabilizing the spacecraft after initial post-launch spinning issues and confirming the functionality of its payloads for ongoing use. From mid-2024 onward, EIRSAT-1 transitioned into routine payload operations, with the gamma-ray module, ENBIO module, and wave-based control system activated for regular and testing. These activities continued steadily through 2025, supported by consistent ground passes. In August 2025, the team conducted successful testing of the wave-based control payload, demonstrating advanced satellite pointing capabilities through a software update and in-orbit maneuvers. Throughout its operational lifespan, EIRSAT-1 relied on the ground station for approximately seven line-of-sight passes per day, supplemented by expertise and resources under the Fly Your Satellite! program. The mission spanned approximately 21 months, from its launch on December 1, 2023, until the transmission of final beacons on September 4, 2025.

Mission Results

Gamma-ray Observations

EIRSAT-1's Gamma-ray Module (GMOD) achieved its first astrophysical detection with GRB240821B, a long-duration occurring on 21 August 2024, characterized by emissions lasting over 2 seconds and associated with the core-collapse of a massive . The , binned at 1.2 seconds, revealed multiple pulses indicative of the burst's extended emission phase, with data captured in the instrument's operational energy range of approximately 60 keV to 1.5 MeV. Just 79 minutes prior, GMOD detected GRB240821A, a short-duration burst under 2 seconds, demonstrating the payload's capability to handle rapid successive events and validating its dual-burst detection performance. The for this event, also binned at 1.2 seconds, displayed a single prominent peak, consistent with short bursts often linked to mergers. Energy spectra from both detections were analyzed to contribute prompt alerts to the international community, enabling coordinated follow-up observations. These observations were corroborated by contemporaneous detections from Fermi Gamma-ray Burst Monitor and SVOM, allowing for refined localization of GRB240821A to arcsecond precision through optical follow-up with the European Southern Observatory's , which identified the host galaxy at a corresponding to about 3 billion light-years and confirmed the event as originating from a . The combined gamma-ray data from EIRSAT-1 supported multi-messenger astronomy efforts by providing early-time spectral and temporal information that facilitated the detection of electromagnetic counterparts, enhancing understanding of short burst progenitors. Over the course of the mission, GMOD detected a total of 10 gamma-ray bursts and 2 flares, underscoring its role in expanding the network of small-satellite contributions to transient despite the constraints of platforms.

Technology and Materials Experiments

The ENBIO Module (EMOD) experiment on EIRSAT-1 evaluated the in-orbit performance of novel management coatings developed by ENBIO Ltd., specifically SolarBlack and SolarWhite oxide-based surfaces designed for . These coatings were tested for the first time in low-Earth orbit using four coupons equipped with resistance temperature detectors (RTDs) mounted on the satellite's exterior. Over the mission duration, which spanned approximately 1.75 years from launch in December 2023 until deorbiting in September 2025, the experiment monitored temperature variations to assess changes in emissivity and absorptivity due to space environmental factors such as atomic oxygen, ultraviolet radiation, and cycling. Preliminary analysis of the EMOD data indicated minimal in the coatings' thermal properties after extended , with observed changes in and absorptivity remaining within acceptable limits for operational use on future missions, such as ESA's . This outcome validated the durability of the oxide coatings under real space conditions, providing essential data for material qualification in harsh orbital environments. The experiment's success highlighted the coatings' resistance to , supporting their application in passive control systems for small satellites. The Wave-Based Control (WBC) payload demonstrated a novel software-based attitude control algorithm that leveraged the for three-axis maneuvers. In August 2025, during dedicated in-orbit tests spanning three consecutive orbits, the system successfully initiated spin-up and achieved precise with accuracy within a few degrees. This performance metric, evaluated through metrics including and , confirmed the algorithm's efficacy in resource-constrained platforms without additional hardware. Both EMOD and WBC payloads achieved full technology qualification, reaching Technology Readiness Level (TRL) 9 through successful flight operations and data collection on magnetic field interactions for control and material durability in vacuum. The stable pointing provided by WBC enhanced the consistency of EMOD's exposure to orbital conditions, enabling more reliable thermal data acquisition across the mission. These results underscore the synergies between the experiments, advancing Irish contributions to satellite technology validation.

End of Mission and Legacy

Deorbiting and Mission Conclusion

EIRSAT-1 concluded its mission in September 2025, approximately 21 months after its launch on December 1, 2023, primarily due to natural caused by atmospheric drag. The satellite underwent passive deorbiting from its initial altitude of 515 km, relying on atmospheric drag to lower its perigee until re-entry. This approach ensured compliance with disposal guidelines established by the (ESA), which recommend deorbiting within 25 years to mitigate risks. By early 2025, the satellite's altitude had decayed to approximately 230 km, leading to its uncontrolled re-entry and atmospheric burn-up around September 4-5, 2025. In the final days of operations, the mission team performed payload shutdown procedures and completed data downlink activities, including the transmission of final beacons on September 4, 2025, which confirmed the satellite's health status prior to re-entry. As part of these concluding efforts, a software update was uplinked to the spacecraft's Wave-Based Control (WBC) payload to enable additional magnetic experiments during the descent phase. Post-mission analysis involved the ground team at recovering and archiving all remaining and scientific data downlinked before signal loss, providing a comprehensive for of the satellite's performance and functionality. No physical was possible due to the complete atmospheric disintegration during re-entry, but the analysis focused on validating mission objectives and informing future Irish space projects.

Scientific and Educational Impact

EIRSAT-1 advanced the scientific understanding of gamma-ray bursts (GRBs) by successfully detecting 10 cosmological GRBs and two solar flares during its mission, providing valuable observational data that contributed to multi-messenger astronomy efforts and the study of high-energy astrophysical phenomena. The mission's Gamma-ray Module (GMOD) offered a compact platform for such observations, enabling the qualification of novel materials through the ENBIO Module (EMOD), which tested thermal management coatings in low-Earth orbit for the first time and validated their performance for future spacecraft applications. Additionally, the in-orbit demonstration of advanced control technologies, including the wave-based attitude determination and control system (ADCS), supported the development of precise orbital pointing methods essential for subsequent small satellite missions. Technologically, EIRSAT-1 marked the first of a (SiPM)-based GRB detector, a miniaturised instrument that replaced traditional tubes with a low-power, compact alternative suitable for CubeSats, thereby influencing designs for future nanosatellite gamma-ray observatories. The wave-based control algorithm, applied to the satellite's magnetotorquers, achieved successful in-orbit slewing and stabilization, demonstrating its efficacy for flexible structures and paving the way for adoption in smallsat attitude control systems. The mission had a profound educational impact, training over 50 postgraduate students in physics, engineering, computer science, and mathematics through hands-on involvement in satellite design, build, and operations, while an additional 20 students gained expertise via a dedicated orbital operations course. This effort established the UCD Centre for Space Science and led to the creation of a formal space programme at the university, fostering a new generation of Irish space professionals. Furthermore, EIRSAT-1 boosted Ireland's participation in the space sector by proving national capabilities in end-to-end satellite development and operations, inspiring thousands of schoolchildren through outreach reaching over 10,000 people and enhancing public awareness of STEM fields. As a , the culminated in a public "bids adieu" event in October 2025, marking the satellite's deorbit and celebrating its achievements, which inspired national interest in space exploration and earned recognition through the 2024 UCD Research Impact Case Study Competition award.