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Breakthrough Listen

Breakthrough Listen is a $100 million, ten-year initiative launched in July 2015 by tech investor and physicist through the Breakthrough Initiatives to search for signs of intelligent extraterrestrial life using advanced radio and optical telescopes. It is the most comprehensive and powerful program ever undertaken, surveying over one million nearby stars, the and center, and the 100 nearest galaxies for technosignatures such as radio signals or pulses. The project utilizes world-leading facilities, including the 100-meter Robert C. Byrd Green Bank Telescope in , , for high-sensitivity radio observations; the 64-meter Parkes Telescope in , , equipped with a multibeam receiver for broad-spectrum searches; the MeerKAT radio array in for 24/7 monitoring of millions of stars; and the 2.4-meter Automated Planet Finder at in , , for detecting potential laser communications across near-ultraviolet to near-infrared wavelengths. These instruments provide up to 50 times the sensitivity of prior efforts, enabling detection of faint signals equivalent to aircraft from the nearest 1,000 stars or a 100-watt from distances up to 25 trillion miles. Directed by Principal Investigator Dr. Andrew Siemion of the Berkeley SETI Research Center at the , the program involves an international team of astronomers, engineers, and data scientists who process petabytes of using innovative techniques, including a recent system that processes 600 times faster than previous methods. All collected is publicly released through the Breakthrough Listen Open Data Archive, fostering global collaboration and enabling independent analyses that have led to discoveries like new fast radio bursts and studies of atmospheres. Despite identifying signals of interest, such as the 2019 candidate later attributed to human interference, no confirmed extraterrestrial technosignatures have been found as of November 2025, underscoring the vast scale of the cosmic search.

History and Establishment

Announcement and Launch

Breakthrough Listen was publicly announced on , 2015, at the Royal Society in by physicist , philanthropist , and astronomer . The event marked the initiation of the Breakthrough Initiatives, a broader program including Listen as its flagship effort, timed to coincide with the 46th anniversary of the . The motivations for launching Breakthrough Listen stemmed from recent advances in telescope sensitivity and data processing capabilities, which enabled a far more comprehensive search for extraterrestrial intelligence than previous efforts. These technological improvements addressed the limitations of earlier programs, which had been hampered by funding shortages and sporadic observations since the era following the detection of the intriguing but unconfirmed " in 1977. Milner emphasized the need for a sustained, large-scale initiative to systematically scan the skies, revitalizing the field after decades of underinvestment. The project officially launched its observational campaigns in January 2016, beginning with "first light" data collection at the in . This startup phase committed $100 million over 10 years to fund the extensive surveys, positioning Breakthrough Listen as the most ambitious program to date.

Funding

Breakthrough Listen is primarily funded by the Breakthrough Initiatives, a philanthropic organization co-founded by , with an initial commitment of $100 million over a 10-year period beginning in 2016. This substantial private investment marked the largest dedicated funding for a (SETI) effort to date, enabling extensive observational campaigns without reliance on traditional government grants. The budget supports telescope access and operational support, with approximately 20% of observing time dedicated to the in and 25% to the in , reflecting the project's emphasis on radio frequency searches. Funding also covers optical observations using the Automated Planet Finder at in , as well as data processing, software development, and analysis infrastructure, including computational resources for handling petabytes of data. These allocations ensure balanced coverage across radio and optical spectra, with significant investment in backend systems to manage the high-volume data streams generated by the telescopes. The 10-year funding period, aligned with the observational campaign starting in January 2016, is set to conclude in 2026. As of November 2025, Breakthrough Listen remains heavily dependent on philanthropic sources and continues operations under the original commitment, with the project actively conducting surveys and analyses.

Project Leadership

Breakthrough Listen was founded under the leadership of Andrew Siemion, who serves as the principal investigator and director of the Berkeley SETI Research Center at the , and Dan Werthimer, co-founder and chief scientist of the project and director of the SERENDIP program at UC . Siemion and Werthimer have steered the project's scientific direction since its inception in , leveraging their expertise in and to oversee observational campaigns and data analysis efforts. The project's initial institutional hubs were the in , and the UC Berkeley SETI Research Center, where much of the early infrastructure and team were based. In 2023, Breakthrough Listen relocated its international headquarters to the Department of Physics at the , establishing a new partnership with the to enhance computational resources and access to upcoming facilities like the . This shift maintained continuity in leadership, with Siemion continuing as at the site. Key scientific advisors have included prominent figures such as , former director of the SETI Institute's Center for Research, and , an astronomer known for discoveries, both of whom contributed to the initiative's early strategy and target selection as part of the leadership team. The project also draws on international collaborators, including affiliations with Radboud University in the and the through Siemion's roles, fostering a global network of expertise. Through 2025, the leadership structure has remained stable, with no major reported amid the institutional to , allowing focus on ongoing observational and analytical advancements.

Objectives and Significance

Overview and Goals

Breakthrough Listen is a decade-long astronomical initiative launched in 2015 as the most comprehensive (SETI) to date, focusing on the detection of technosignatures—signs of technology from advanced civilizations beyond . The core objective is to survey one million of the nearest stars, the centers of the and galaxies, the , and 100 nearby galaxies for engineered signals that could indicate intelligent life. This effort aims to dramatically expand the scope of previous SETI searches by covering a broad swath of the sky and , prioritizing signals that are statistically unlikely to arise from natural processes. The project employs some of the world's most powerful radio telescopes, including the 100-meter Robert C. Byrd in and the 64-meter Parkes Telescope in , to conduct radio observations across a frequency range of 1 to 10 GHz. Optical searches complement these efforts using the 2.4-meter Automated Planet Finder at in , which scans for brief pulses or other transient emissions. Technosignatures targeted by the initiative include radio signals, such as those potentially from communications or systems, and short-duration optical transmissions, both designed to be distinguishable from astrophysical like cosmic microwave background radiation or stellar emissions. Originally planned as a 10-year program with a $100 million , Breakthrough Listen emphasizes by releasing raw observational data to the public, enabling global researchers and citizen scientists to analyze datasets for potential signals. This approach not only accelerates discovery but also fosters broader participation in the quest to answer whether humanity is .

Importance in SETI Research

Breakthrough Listen has played a pivotal role in reviving the field of the Search for Extraterrestrial Intelligence () following the termination of NASA's dedicated program in , when eliminated federal funding amid budget constraints and political opposition. This cutoff ended a era of government-supported SETI efforts that had begun with in 1960, leaving the discipline reliant on limited private donations totaling around $1.5 million annually. With its $100 million commitment over 10 years, Breakthrough Listen represents the largest investment in SETI since , enabling a comprehensive, decade-long survey that has reinvigorated the search by providing sustained resources and access to world-class telescopes. A key advancement offered by Breakthrough Listen is its enhanced sensitivity, allowing detection of signals 50 times weaker than those searchable by prior instruments, thereby expanding the potential to identify technosignatures from distant or faint sources. This capability stems from utilizing some of the most powerful radio telescopes available, such as the 100-meter and the 64-meter Parkes Telescope, which cover 10 times more sky area, five times more of the , and operate 100 times faster than previous efforts. Such improvements have broadened the scope to include a million nearby stars and the centers of 100 nearby galaxies, setting a new benchmark for the depth and breadth of SETI observations. The project fosters an interdisciplinary approach by integrating astronomy with advanced and techniques, fundamentally redefining how technosignatures are detected amid vast datasets. For instance, algorithms have been applied to analyze radio spectrograms, identifying patterns that traditional methods might overlook, as demonstrated in searches yielding new candidates of interest. This fusion not only accelerates data reduction and archiving but also enhances the reliability of distinguishing potential extraterrestrial signals from radio frequency interference. Philosophically and scientifically, Breakthrough Listen holds profound significance by addressing fundamental questions about the prevalence of life and technological civilizations across the , potentially reshaping our understanding of humanity's place in the . By systematically probing for radio and optical signals, it contributes to the broader quest to quantify the distribution of advanced life in the , offering empirical insights into the and the rarity or commonality of intelligent societies. This effort underscores SETI's role in exploring existential inquiries through rigorous, data-driven science.

Search Methodology

Observation Targets

Breakthrough Listen primarily targets one million of the closest to for its radio and optical searches for technosignatures. These are selected from the solar neighborhood, extending out to approximately 5,000 light-years, with an emphasis on those most likely to host habitable , including Sun-like G-type , cooler K-type , and abundant red dwarf M-type . This focus on spectral types associated with stable habitable zones prioritizes systems where liquid water could exist on planetary surfaces, drawing from catalogs like and to ensure comprehensive coverage of potential host . In addition to the broad stellar survey, the project includes observations of the and of the , where stellar density is highest, increasing the chances of detecting signals from numerous nearby civilizations. Extragalactic targets comprise the centers of the 100 nearest galaxies, such as the (M31) and other members, to probe for powerful technosignatures from advanced societies in neighboring systems. A supplementary set of 1,649 stars serves as representatives across all spectral types, spanning the Hertzsprung-Russell diagram from main-sequence dwarfs to giants, ensuring the search samples diverse stellar environments. Target prioritization emphasizes proximity to minimize signal attenuation and interstellar interference, combined with high stellar density in regions like the and the potential for habitable worlds based on exoplanet surveys. Since 2019, Breakthrough Listen has integrated with NASA's (TESS) mission, incorporating over 1,000 TESS Objects of Interest—primarily small, rocky exoplanets in or near habitable zones—into its observation queue to target edge-on systems ideal for detecting planetary transits and associated technosignatures. This collaboration enhances the focus on promising candidates for life-bearing worlds. Through 2025, the target list has been updated with new exoplanet catalogs from TESS and other missions, including recent observations of 27 eclipsing exoplanet systems selected for their habitable potential. These updates maintain the strategy's core emphasis on proximity, density, and habitability prospects without altering the foundational million-star and 100-galaxy framework.

Data Acquisition and Processing

Breakthrough Listen acquires vast amounts of radio data using the (GBT) in , the in , and the radio array in , generating approximately 1 petabyte of data per year through high-sensitivity observations across frequencies from 700 MHz to 26 GHz. Observations with , which began in 2021, enable 24/7 monitoring of millions of stars using its 64 antennas for enhanced sensitivity and coverage in the 0.6–15 GHz range. These observations involve streaming at rates up to 86 gigabits per second, enabling the capture of wide bandwidths—up to 10 GHz at the GBT, 4.875 GHz at Parkes, and up to 3 GHz per receptor at —with dual to maximize signal detection sensitivity. Raw data are recorded in the Green Bank Ultimate Pulsar Processing Instrument (GUPPI) format at GBT and similar formats at other facilities, which support the project's focus on nearby stars, the , and other targets of interest. For optical searches, data are acquired using the 2.4-meter Automated Planet Finder (APF) telescope at in , scanning targets in the near-ultraviolet to near-infrared wavelengths (350–1100 nm) for short-duration pulses indicative of technosignatures. The APF employs a high-resolution spectrograph to detect pulsed signals with integration times as short as 60 seconds, covering up to 50 stars per night. Optical data processing involves custom pipelines for pulse detection and characterization, with raw and reduced data released publicly through the Breakthrough Listen . The radio processing pipeline begins with GPU-accelerated (FFT) conversion of raw voltage data into filterbank spectrograms, producing three resolution tiers: high at ~3 Hz channels, high time resolution at ~349 µs integrations, and medium resolution at ~3 kHz channels. Central to initial analysis is the turboSETI software, a Python-based tool that performs incoherent dedispersion across a range of drift rates (from -100 to +100 Hz/s) to detect signals potentially indicative of technosignatures, while applying GPU-accelerated filtering to efficiently scan for candidates above a statistical threshold. This pipeline enables rapid screening of the enormous datasets, prioritizing hits for further scrutiny without exhaustive computation on every frequency-time pixel. All raw and processed data have been publicly released through the since 2017, totaling over several petabytes across releases such as the 1 PB and subsequent 2 PB additions from surveys. This openness facilitates contributions and independent analyses. Access is provided via portals at seti..edu/opendata and breakthroughinitiatives.org/opendatasearch, including tools like blimpy for Python-based and . Quality control is integral to the , with radio frequency (RFI) mitigation achieved through alternating "ON" (target) and "OFF" (off-target reference) scans, enabling subtraction of human-generated signals and blanking of known at rates of 0.1–0.9% of the data depending on the and . involves periodic observations of pulsars and flux standards at the GBT, Parkes, and , ensuring accurate flux density measurements and system temperature corrections, though full retrospective of the archive remains ongoing to standardize all datasets. These steps maintain the integrity of the search, minimizing false positives while preserving potential faint technosignatures.

Breakthrough Listen Exotica Catalog

The Breakthrough Listen Exotica Catalog serves as a comprehensive archive designed to expand the scope of searches by targeting a diverse array of astronomical objects that could produce unusual radio signals potentially mimicking artificial emissions. Launched as part of the initiative's efforts to survey "one of everything" in the , the catalog compiles 963 entries representing 816 distinct targets, categorized to include prototypes of standard phenomena, superlative examples with extreme properties, enigmatic anomalies, and control samples expected to yield null results. This approach aims to characterize natural sources of "exotica"—unexplained or rare radio emissions—thereby reducing false positives in observations and enhancing the understanding of astrophysical interlopers. Key entries in the highlight potential origins of non-natural-appearing signals, such as analogs to the repeating source FRB 121102, which exhibit periodic bursts that could resemble engineered transmissions if not properly contextualized. Other notable inclusions are transient events like afterglows or peculiar pulsars whose emissions do not align with conventional astrophysical models, providing a repository for investigating signals that deviate from expected natural behaviors. These selections prioritize objects capable of generating narrowband or impulsive radio features, ensuring the captures a broad spectrum of potential signal confounders. The catalog's classification system organizes targets based on their astrophysical characteristics, with criteria emphasizing rarity, extremity, and inexplicability rather than direct signal metrics; however, it incorporates considerations for potential emission properties like and repetition to guide observations of exotic signals. Initially published in with detailed notes on entry selection, the framework was refined in the 2021 formal release to include a dedicated anomaly subclassification for unresolved phenomena, though no major updates have been documented through 2025. This structure facilitates systematic archiving and of exotica, enabling follow-up studies on signal origins. In the broader context of research, the Exotica Catalog informs hypotheses by systematically observing natural candidates for anomalous signals, helping to delineate boundaries between astrophysical noise and potential artificiality without asserting any detections. By integrating these targets into Breakthrough Listen's observational pipeline, the catalog supports hypothesis testing for extraterrestrial technologies while advancing general through commensal .

Key Results and Discoveries

Early Findings

The Breakthrough Listen project initiated its observational campaign in 2015, with the first major data release occurring in 2017. This release encompassed an of radio observations toward 692 nearby stars, conducted using the Robert C. Byrd (GBT) in the frequency range of 1.1–1.9 GHz between August 2015 and November 2016. No engineered technosignatures were detected; eleven candidate signals were identified but all were confirmed as (RFI) through on-off source observations and subsequent . These results validated the project's instrumental sensitivity and RFI , establishing a baseline for future searches with a detection equivalent to narrowband signals of approximately $10^{13} W effective isotropic radiated power (EIRP) from sources within 50 parsecs. Building on this foundation, observations expanded through 2019, incorporating data from both the GBT and CSIRO Parkes Observatory. Between January 2016 and March 2019, a total of 1327 nearby stars were surveyed across 1.10–3.45 GHz, involving over 1700 hours of telescope time and generating approximately 4.3 petabytes of raw data. Again, no narrowband technosignatures were found after processing billions of frequency channels and identifying 51.71 million RFI candidates for rejection; the search sensitivity reached upper limits of $2.1 \times 10^{12} W EIRP for GBT L-band observations and $9.1 \times 10^{12} W for Parkes, allowing detection of signals comparable to or weaker than strong human-made transmitters like the Arecibo planetary radar at distances up to several kiloparsecs. This equated to roughly 20 times the sensitivity needed to detect an Arecibo-like signal from the Galactic Center, though at reduced effectiveness for distant sources due to beam dilution. The first public data release (DR1) in 2019 made this dataset openly available, enabling community validation and further analysis. These early non-detections provided valuable constraints on the prevalence of , limiting the fraction of observed stars hosting high-duty-cycle, narrowband transmitters above the sensitivity thresholds to less than 0.45% in the L-band and 2.0% at Parkes. For nearby systems, the results implied that any advanced civilizations would need to employ highly directional beaming or lower-power intermittent signals to evade detection, informing models of leakage and search strategies. Initial galactic plane surveys, begun in with Parkes, complemented targeted efforts by covering broader regions encompassing millions of stars at lower per-star sensitivity, though full analysis of this ~100 petabyte extended beyond 2019. Key early publications included peer-reviewed papers validating the methodology and interpreting null results. Enriquez et al. (2017) detailed the initial 692-star survey and RFI handling, while Price et al. (2020) presented the expanded 1327-star analysis, emphasizing probabilistic constraints and data release protocols; both underscored the implications for parameter space exploration without evidence of nearby broadcasters. Supporting works, such as Lebofsky et al. (2019), described the infrastructure enabling these outcomes.

Notable Candidate Signals

One of the most prominent candidate signals identified by Breakthrough Listen is , detected in archival data from observations conducted in April and May 2019 using the Parkes radio telescope in , targeting the direction of , the nearest star to . This narrowband signal appeared at approximately 982 MHz, exhibited Doppler drifting consistent with a source in relative motion, and was observed over 30 hours across multiple scans, prompting initial excitement as a potential due to its proximity to Proxima b, a planet in the star's . However, follow-up analyses in 2021, including re-observations with the and detailed RFI mitigation studies, attributed BLC1 to an product from local human-generated interferers, such as electronic devices, rather than an extraterrestrial origin; no repetitions were detected in subsequent targeted observations. In July 2021, a deep learning-based search applied to 480 hours of data from 820 nearby stars yielded eight additional candidate signals with technosignature-like properties, including emissions and potential Doppler signatures, marking the first use of such methods to uncover previously overlooked candidates. These signals, analyzed through autoencoders and classifiers to distinguish them from noise and known RFI, were subjected to rigorous verification, including re-observations and multi-wavelength checks, but none repeated or confirmed as non-terrestrial upon peer-reviewed scrutiny. The process highlighted the value of automated pipelines in flagging intriguing events for human review, though all were ultimately linked to terrestrial interference or instrumental artifacts. Breakthrough Listen's investigation protocol for candidates emphasizes rapid follow-up with multiple telescopes, such as Parkes, , and , alongside community vetting through data releases and publications to rule out prosaic explanations. By 2025, expanded surveys incorporating enhancements have processed petabytes of data without yielding confirmed technosignatures, though ongoing scrutiny of transient events, including FRB-like bursts from habitable zone targets, continues to refine exclusion criteria and detection thresholds; for instance, a June 2025 study of 27 transiting exoplanets selected from the TESS catalogue found no anomalous radio emissions during occultations. Additionally, a March 2025 analysis of the GBT archive, covering 3077 stars across multiple bands, set upper limits indicating less than 1% of stars host transmitters brighter than approximately 0.3 times an Arecibo radar equivalent.

Technological Innovations

AI and Computational Advances

In 2025, Breakthrough Listen introduced a real-time end-to-end deep learning system for detecting fast radio bursts (FRBs) and technosignatures, developed in collaboration with NVIDIA and the SETI Institute using the Allen Telescope Array. This neural network-based approach, built on NVIDIA's Holoscan platform, employs a modified ResNet-34 architecture with a learnable masking layer to process dynamic spectra directly, bypassing traditional dedispersion techniques for enhanced efficiency in identifying complex signal patterns. Trained using PyTorch with an ADAM optimizer and categorical cross-entropy loss on simulated pulse-injected data, the system achieves a 600-fold speed increase over conventional methods like SPANDAK, enabling rapid analysis of vast datasets. The system's performance includes processing 86 gigabits per second of data streams 160 times faster than real-time, with 99.12% accuracy, 98% recall at high signal-to-noise ratios, and a false positive rate reduced to 0.40% at a 0.999 threshold—representing a tenfold improvement in false positive reduction compared to prior pipelines. Validation tests on Crab Pulsar giant pulses successfully recovered 10 events from 77 minutes of observations with a false positive rate of approximately 0.01%, demonstrating its robustness for low-signal events while maintaining high precision across dispersion measures. This advancement evolves the Breakthrough Listen Single-pulse (BLSP) pipeline by integrating for real-time anomaly classification, leveraging the open-source digital signal processing library and Holoscan SDK to handle low-latency inferencing at sites. The enhanced pipeline outperforms earlier versions through a 100-fold increase in model parameters and dynamic masking, allowing better detection of unexpected technosignature-like anomalies without exhaustive parameter sweeps. Breakthrough Listen has released the AI models and code as open-source resources, including the BLADE_FRBNN repository on and pretrained weights on , facilitating community-driven analysis and scalable deployment on global telescopes.

Instrument and Telescope Upgrades

The Breakthrough Listen project has significantly enhanced the capabilities of the Robert C. Byrd (GBT), a 100-meter dish, through the deployment of a wideband data recording system that enables observations across a broad frequency range of 0.7 to 12 GHz with high . This upgrade, implemented since 2015, supports the project's intensive surveys by allowing for the capture and storage of vast datasets at rates up to 25 /s, facilitating deeper searches for technosignatures. At the Parkes Observatory's 64-meter telescope (Murriyang), receiver improvements include the installation of the Ultra-Wideband Low (UWL) receiver, which provides continuous coverage from 704 MHz to 4.032 GHz, consolidating the bandwidth of four prior receiver systems into a single package. This enhancement, completed around , has expanded the Breakthrough Listen Parkes Data Recorder's capabilities, enabling faster sky surveys and improved sensitivity for detecting potential extraterrestrial signals while reducing setup times between observations. Additionally, upgrades to the multibeam receiver have allowed simultaneous observations of multiple sky positions, enhancing RFI rejection and overall survey efficiency. In the optical domain, Breakthrough Listen employs the 2.4-meter Automated Planet Finder (APF) telescope at for targeted searches of laser-like technosignatures from nearby stars. Operational since 2016, the APF's Levy spectrograph enables robotic, high-resolution spectroscopic observations to detect narrow, persistent optical pulses indicative of directed energy communications, complementing radio efforts by scanning hundreds of stars per night. As of 2025, Breakthrough Listen is integrating data from the , which became operational that year with its 3.2-gigapixel camera imaging the southern sky every few nights. Preparations include cross-correlating Rubin's optical transient detections—such as variable stars and moving objects—with radio data from facilities like the GBT, Parkes, and to identify potential technosignatures across wavelengths. Ongoing maintenance and expansions through 2025 encompass the addition of feeds to form an all-sky radio monitor at Westerbork Synthesis Radio Telescope, announced in May 2025 and deployed progressively for continuous transient detection. This hardware augmentation, in collaboration with ASTRON and the , broadens Breakthrough Listen's coverage to the entire visible sky, day and night, enhancing real-time searches.

Future Plans and Current Status

Ongoing Observations

As of November 2025, Breakthrough Listen has made substantial progress in its ambitious survey of 1 million nearby stars and 100 nearby galaxies, leveraging multiple radio telescopes including , Parkes, and to accumulate thousands of hours of observation time. This progress builds on targeted observations of stellar populations within 100 parsecs, with ongoing efforts expanding coverage across the and extragalactic centers to enhance sensitivity for technosignatures. Recent observational campaigns have prioritized exoplanet host stars identified through data from the (JWST) and the (TESS), integrating multi-wavelength approaches that combine radio searches with optical and constraints on planetary systems. A notable 2025 effort examined 27 confirmed and candidate eclipsing exoplanets from the TESS catalog, analyzing archival radio data from 2018–2022 for signals potentially modulated by planetary transits or occultations, marking the first use of such eclipsing events in searches. These campaigns emphasize high-priority targets with habitable-zone planets, aiming to detect intermittent or directional technosignatures that might correlate with exoplanetary dynamics. The project generates petabyte-scale data volumes annually, with public releases archived for global and monitoring systems deployed to transients such as fast radio bursts or anomalous emissions. In November 2025, Breakthrough Listen announced a revolutionary AI system, developed in collaboration with , that achieves a 600× speed increase in signal detection, enabling of complex signal morphologies and enhancing the efficiency of searches. For instance, the May 2025 deployment of an all-sky radio monitor at Westerbork Observatory, equipped with feeds and Holoscan computing, enables continuous scanning of the northern sky for variable sources and technosignatures, processing data streams in near to prioritize follow-up observations. Key operational challenges include mitigating radio frequency interference (RFI) amid increasingly crowded spectra from terrestrial sources like constellations and networks, requiring advanced algorithms to distinguish human-generated noise from potential signals. Breakthrough Listen addresses these by implementing statistical vetting processes and operating in radio-quiet zones, though adapting to new interference patterns remains an ongoing priority to maintain survey sensitivity.

Planned Expansions

Following the initial 10-year funding period ending in , Breakthrough Listen anticipates extensions through additional funding to sustain operations and complete comprehensive surveys, including a full scan of the for technosignatures. This extension aims to leverage ongoing advancements in capabilities and to deepen the search beyond the original scope of one million nearby stars. New collaborations are set to enhance Breakthrough Listen's capabilities starting in 2025, integrating data from the Vera C. Rubin Observatory's Legacy Survey of Space and Time, which will provide optical observations of approximately 20 billion galaxies and stars to identify anomalies potentially indicative of technology. Additionally, partnerships with (SKA) precursors, such as MeerKAT and the Murchison Widefield Array, will enable higher-sensitivity radio surveys, with full SKA integration planned as the array reaches operational phases in the late 2020s. These synergies extend to optical and gamma-ray searches through collaborations with Cherenkov Telescope Array facilities like , facilitating multi-wavelength cross-verification of candidate signals. Methodological expansions will broaden technosignature detection, incorporating machine learning to sift through billions of channels for narrowband signals and transient events. Long-term objectives target a detailed census of millions of stars across the and nearby galaxies, scaling observations to encompass non-radio wavelengths like gamma rays for potential high-energy technosignatures from probes or engineered emissions. These efforts, supported by post-2025 instrumentation upgrades, aim to systematically map potential habitats for intelligent life over the late and beyond.

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