Fact-checked by Grok 2 weeks ago

Atacama Cosmology Telescope

The Atacama Cosmology Telescope (ACT) is a 6-meter diameter millimeter-wave located at an altitude of 5,190 meters (17,030 feet) on Cerro Toco in the of northern , one of the highest ground-based telescopes in the world. Designed primarily to observe the (CMB) radiation—the remnant light from the —it measures small-scale temperature and polarization anisotropies to probe the universe's origins, composition, and evolution. The telescope operated from 2007 until its decommissioning in 2022, producing extensive datasets now publicly available through NASA's Legacy Archive for Microwave Background (LAMBDA). The ACT's scientific goals encompass refining parameters of the early universe, such as the density of matter and the properties of inflation, while also detecting distant galaxy clusters through the thermal Sunyaev-Zel'dovich (tSZ) effect and reconstructing CMB lensing to constrain neutrino masses. It searches for primordial gravitational waves via B-mode polarization patterns in the CMB, which could reveal details about cosmic inflation shortly after the Big Bang. Over its lifespan, the telescope underwent significant upgrades, starting with the Multichannel Bolometer Array Camera (MBAC) for broad frequency coverage (145, 220, and 280 GHz), followed by the ACTPol receiver (2013–2016) for polarization measurements at 98 and 150 GHz, and the Advanced ACT (AdvACT) instrument (2016–2022) featuring multichroic detectors across 20–270 GHz bands for enhanced sensitivity. These advancements, including contributions from institutions like NIST in developing superconducting sensors, enabled deeper observations over thousands of square degrees of sky with angular resolutions as fine as 1.4 arcminutes. Among its notable achievements, the has provided high-precision maps of the , contributing to tighter constraints on cosmological parameters and supporting the standard Lambda (ΛCDM) model. In March 2025, the ACT collaboration released the clearest images yet of the , capturing the as it was approximately 380,000 years old—over with five times the resolution of prior surveys like Planck. These images confirm the universe's age at 13.8 billion years with 0.1% precision, depict density and velocity variations in primordial and gases, and align measurements of the Hubble constant with CMB-based estimates. They also quantify the observable universe's mass at about 1,900 zetta-solar masses, comprising roughly 5% ordinary matter (100 zetta-solar masses, mostly and ), 25% (500 zetta-solar masses), and 70% , while ruling out most alternative cosmological models without invoking new physics. The ACT's legacy data continues to inform ongoing projects like the Simons Observatory and the future CCAT Observatory, advancing ground-based CMB research.

History

Construction and Commissioning

The Atacama Cosmology Telescope (ACT) project originated in the early 2000s, driven by a collaborative effort led by the team under principal investigator Lyman A. Page, with significant contributions from at the . Initial planning and development were funded by the U.S. (NSF) through awards PHY-00-99493 to Princeton and AST-97-32960 to the , enabling the design of a 6-meter off-axis optimized for high-resolution observations. Further NSF support under grants AST-04-08698 and PHY-03-55328 facilitated the progression from to physical . Construction commenced with site preparation at Cerro Toco in the in 2006, followed by the fabrication of the telescope structure by AMEC Dynamic Structures Ltd. in , . The 32-tonne primary structure and overall 40-tonne moving assembly were transported to the remote 5,190-meter-altitude site, overcoming logistical hurdles including rugged terrain access and high-elevation handling. Assembly was completed on-site by mid-2007 with assistance from Con Pax, including the precise alignment of off-axis mirrors to achieve 31 µm root-mean-square (rms) accuracy on the primary and 10 µm rms on the secondary after iterative adjustments. First light was achieved on October 22, 2007, using the Millimeter Array Camera (MBAC) operating at 148 GHz. Initial commissioning involved beam mapping, which yielded a full-width at half-maximum (FWHM) of 1.44 arcminutes and a of approximately 215 nanosteradians at 145 GHz; pointing accuracy tests using observations of , Mars, Saturn, and , confirming a base tilt of 20 arcseconds; and basic sky observations limited to nighttime hours to mitigate thermal distortions, continuing until mid-December 2007 to verify overall functionality.

Operational Phases and Upgrades

The Atacama Cosmology Telescope began its scientific operations in 2008 with the installation of the Millimeter Bolometer Array Camera (MBAC), which conducted temperature-only measurements of the across three frequency bands centered at 148 GHz, 218 GHz, and 277 GHz. This initial phase, spanning 2008 to 2010, utilized polarization-insensitive detector arrays to produce high-resolution maps of CMB temperature anisotropies, accumulating several thousand hours of observation during this period. In 2013, the telescope underwent its first major upgrade with the deployment of the ACTPol receiver, which introduced polarization-sensitive detectors to enable measurements of E-mode and B-mode polarization in the CMB. This enhancement expanded the detector array to 2944 pixels, incorporating feedhorn-coupled transition-edge sensor (TES) bolometers cooled to 100 mK via improved cryogenic systems, including pulse-tube and sorption refrigerators for stable operation across the telescope's elevation range. The ACTPol phase, active from 2013 to 2016, focused on 98 GHz and 150 GHz observations, significantly advancing studies of CMB polarization power spectra. The Advanced ACTPol (AdvACT) upgrade, implemented starting in 2016, further transformed the instrument by installing multichroic pixel arrays operating across five frequencies: 28 GHz, 39 GHz, 93 GHz, 145 GHz, and 225 GHz. This configuration increased the total number of pixels to 5808, with each pixel featuring dual-polarization TES detectors integrated into dense feedhorn arrays, enhancing overall sensitivity by a factor of approximately 10 compared to prior phases through broader frequency coverage and lower noise levels. Cryogenic enhancements, including sub-kelvin cooling stages and multiplexed readout electronics supporting over 5,000 TES channels, ensured reliable performance during the AdvACT era, which ran until 2022. By the end of operations in 2022, the telescope had amassed more than 10,000 hours of cumulative observing time across all phases, providing a rich dataset for cosmological analyses.

Decommissioning and Legacy

The Atacama Cosmology Telescope completed its final observations in mid-2022, culminating in full decommissioning by September of that year. This closure marked the end of nearly 15 years of operations, driven by the successful achievement of its primary science objectives in mapping the () and related cosmological parameters, as well as the strategic pivot toward next-generation facilities. Following decommissioning, all ACT datasets were systematically transferred to the NASA Legacy Archive for Microwave Background Data Analysis (LAMBDA) for long-term preservation and unrestricted public access, enabling ongoing by the global . The telescope's legacy endures through its pioneering contributions to polarization studies, where it delivered some of the earliest high-resolution measurements of E-mode polarization patterns, laying foundational techniques for probing and large-scale . These advancements directly influenced the design and instrumentation of subsequent projects, such as the Simons Observatory, which builds on ACT's receiver technologies and site expertise at Cerro Toco, and the CMB Stage-4 experiment, which incorporates ACT-derived strategies for enhanced sensitivity and foreground mitigation. As of 2025, the Cerro Toco site remains under maintenance by the collaboration and partner institutions, with active discussions underway regarding its potential reuse or expansion to support emerging initiatives, including integrations with the Simons Observatory array. The collaboration's sixth data release (DR6) in March 2025 further underscores this enduring impact, providing refined maps that continue to inform cosmological models.

Site Characteristics

Location and Geography

The Atacama Cosmology Telescope is located on Cerro Toco, a prominent peak in the of northern , at an elevation of 5,190 meters above . This high-altitude site, part of the expansive Chajnantor plateau, provides a stable platform for astronomical observations amid the rugged Andean terrain. The telescope's precise coordinates are 22°57′31″S 67°47′15″W, positioning it approximately 50 kilometers east of the town of . The surrounding geography features a vast, barren high-desert landscape known as the driest non-polar desert on Earth, with extreme aridity resulting from rain shadows created by the Andes Mountains and the cold along the Pacific coast. This remoteness also ensures minimal , shielding the site from urban glow and enhancing visibility for sensitive instruments. Access to Cerro Toco involves a remote network originating near the site, comprising about 35 kilometers of paved highway followed by 15 kilometers of rough, unpaved mining roads that remain mostly clear year-round. Equipment transport requires specialized heavy-duty vehicles capable of navigating the steep, gravelly terrain to deliver components such as sea-shipping containers to the summit. The site was selected in the early after comprehensive surveys of multiple locations across the , leveraging data from prior millimeter-wave experiments like the Telescope for CMB Observations (TOCO) and the Millimeter-wave Interferometer for Northern Telescopes (MINT) that had already established the area's viability.

Atmospheric Conditions

The Atacama Cosmology Telescope benefits from the exceptionally dry atmospheric conditions at its site on Cerro Toco in the , where precipitable (PWV) levels are typically below 1 mm on most nights, particularly during the austral winter observing season. This low PWV is essential for millimeter-wave observations in the 150-220 GHz frequency bands, as it significantly reduces absorption and emission by , allowing for clearer transmission of signals from the (CMB). Median PWV values at the site range from 0.5 to 0.8 mm during operational periods, with the lowest conditions approaching 0.12 mm, enabling efficient data collection under stringent thresholds (e.g., PWV >2-3 mm leads to observation rejection). The site's clear skies, exceeding 300 nights per year with minimal cloud cover, combined with low dust and aerosol levels, further enhance its suitability for high-precision astronomy. These conditions result in over 80% observational efficiency across frequency bands after weather selection, minimizing interruptions from atmospheric opacity. Daytime temperatures can reach up to 20°C, while nighttime lows drop to -20°C or below, fostering stable seeing and low thermal fluctuations that support consistent telescope performance. The low PWV and clear conditions directly lower atmospheric emission noise, which is a primary limiting factor in CMB measurements, thereby enabling the high required for detecting faint anisotropies and Sunyaev-Zel'dovich effects. To maintain , PWV is continuously monitored using dedicated s, such as the UdeC-UCSC at the site and the water vapor nearby, allowing real-time adjustments for variable loading on detectors. Compared to the , the Atacama site provides superior access to northern sky regions (up to declinations of +67°) while offering comparable PWV during peak seasons, though with the advantage of year-round accessibility.

Telescope Design

Optical System

The Atacama Cosmology Telescope (ACT) employs an off-axis optical design to achieve diffraction-limited performance across millimeter wavelengths, minimizing and while providing a wide suitable for () mapping. This configuration uses two off-axis ellipsoidal mirrors: a primary mirror with a 6 m composed of 71 aluminum panels, each approximately 0.65 m by 0.85 m and weighing about 10 kg, and a secondary mirror with a 2 m maximum made of 11 aluminum panels. The panels are mounted on a carbon-fiber-reinforced backup structure for thermal stability and lightweight support, achieving surface accuracies of 25–30 μm for the primary and 10–12 μm for the secondary. The primary mirror operates at a fast focal ratio of approximately f/1, with an effective of about 5–6 m, transitioning to an f/2.5 focal ratio at the focus to optimize compactness and illumination efficiency. This design delivers a beam (FWHM) of roughly 1.4 arcminutes at 150 GHz, enabling arcminute-scale resolution for anisotropy measurements. The system is optimized for frequencies between approximately 100 and 300 GHz, with operational bands centered at 148 GHz, 218 GHz, and 277 GHz, each with bandwidths of 20–30 GHz to capture key features while suppressing . Within the receiver, the optical path includes a three-lens cryogenic silicon reimaging system per frequency band to correct for aberrations, reimage the Gregorian focus onto the detector plane, and efficiently couple radiation to the bolometer arrays. These high-purity lenses (refractive index n ≈ 3.416), cooled to temperatures of 3 K, 1 K, and 0.3 K, have a 19 cm and are coated with quarter-wave anti-reflection layers of Cirlex (n ≈ 1.84) to achieve reflectivities below 0.5% and efficiencies exceeding 93% across the bands. The overall maintains a high (>0.98 median) over a 1 field of view, ensuring uniform illumination and minimal distortion. Pointing accuracy is critical for precise mapping, with the telescope achieving absolute pointing better than 2 arcseconds rms during low-acceleration scans through integration of optical encoders on the azimuth and elevation axes with star-guide cameras for real-time corrections. These cameras provide blind pointing to about 10 arcseconds, refined to sub-arcsecond levels for stable observations.

Mechanical Structure

The Atacama Cosmology Telescope employs an alt-azimuth mount as its primary mechanical framework, enabling efficient scanning of the sky for observations. The moving upper structure, which includes the reflectors and truss, has a mass of 40 metric tons and is mounted on a stationary 12 metric ton pedestal, resulting in a total telescope mass of 52 metric tons. This robust steel truss design, constructed by Ltd., provides the necessary to rapid motions while operating in the harsh high-altitude of Cerro Toco. The mount supports continuous rotation across a range of -220° to +220° at speeds up to 2 degrees per second, with maximum of 10 degrees per second squared, allowing for efficient large-area surveys. Elevation adjustment is limited to a range of 30.5° to 60°, with a maximum speed of 0.2 degrees per second, and is typically fixed at around 52 degrees during primary observations to optimize atmospheric transmission and scanning efficiency. This configuration facilitates repeated cross-linked scans, where each sky position is observed from multiple angles to reduce systematic errors. Lacking a full , the operates in an open-air setup to avoid distortions from enclosed structures, surrounded by a fixed 13-meter-high screen with a 24-meter diameter to suppress emission spillover. A movable inner screen can be deployed to the from high winds, minimizing structural and that could affect pointing during scans. The components, including the and aluminum reflector panels, are engineered for high rigidity to endure the dynamic stresses of scanning and the diurnal swings at the site, which can exceed 30°C. Panel alignments are periodically adjusted using trackers to compensate for deformations, ensuring surface accuracy better than 30 micrometers . Remote diagnostics and control systems, connected via a high-speed microwave link to operations centers in , enable real-time monitoring of structural integrity and motor performance. On-site assembly capabilities support modular upgrades to the without full disassembly.

Instrumentation

Receiver System

The receiver system of the Atacama Cosmology Telescope () comprises a cryogenic front-end designed to capture and precondition millimeter-wave signals for the detector arrays, minimizing thermal noise and atmospheric loading. The system is cooled to below 3 K using dedicated pulse-tube cryocoolers, such as the PT-410 model, which pre-cool the optical tubes and primary receiver components to around 4 K on the second stage before further . A cryogen-free ³He/⁴He , integrated with a PT-407 pulse-tube cooler, extends cooling to sub-Kelvin levels for the focal plane, achieving stable base temperatures near 100 mK with 120 μW of cooling power. In the Advanced ACT (AdvACT) upgrade, the receiver supports simultaneous multichroic observations across five frequency bands centered at 27, 39, 90, 150, and 230 GHz, enabling broad spectral coverage for mapping and foreground separation. This evolved from the original Millimeter Array Camera (MBAC) receiver, which used single-chroic configurations limited to three bands at 148, 218, and 277 GHz, by incorporating multichroic pixels that detect multiple frequencies per feedhorn for enhanced efficiency. Optics integration within the features a three-lens cryogenic relay system, consisting of high-purity lenses with broadband anti-reflection coatings, which reimages the focal plane onto the detectors while maintaining a 3° . Cold Lyot stops, positioned at the 1 stage, define the beam illumination by limiting spillover from the edges and suppressing far , thereby optimizing signal-to-noise performance across the bands. Receiver calibration involves internal load curves obtained by sweeping detector biases against controlled thermal sources, including a 600°C blackbody for hot loads and 77 K eccosorb for cold loads, to determine relative gains and linearities. Absolute bandpass and gain are refined through sky dips, which measure atmospheric emission and opacity variations, ensuring precise flux scaling for scientific analyses.

Detector Arrays

The detector arrays of the Atacama Cosmology Telescope utilize superconducting transition-edge sensors (TES) as bolometric detectors, consisting of thin and aluminum films that operate at the sharp superconducting transition to achieve high sensitivity to (CMB) radiation. These TES devices convert incident millimeter-wave power into measurable resistance changes via electrothermal feedback, enabling precise detection of temperature and polarization signals at cryogenic temperatures around 100 mK. The initial instrumentation, the Millimeter Bolometer Array Camera (MBAC) deployed in 2007, comprised three independent 32×32 arrays with approximately 1000 pixels per frequency band (centered at 148, 218, and 277 GHz), totaling about 3000 TES detectors optimized for temperature-only measurements without polarization capability. These arrays used close-packed TES elements on pop-up membranes, fabricated on silicon-on-insulator wafers to isolate the devices thermally from the . The 2013 ACTPol upgrade introduced polarization sensitivity through three feedhorn-coupled TES arrays totaling 1279 pixels with 3068 detectors, enabling measurements of the CMB's Q and U via orthogonal polarization channels within each pixel. Each pixel incorporated dual TES detectors sensitive to orthogonal linear polarizations, fed by sinuous antennas that separate the signals for differential measurement of polarization modes. In 2016, the Advanced ACTPol (AdvACT) further evolved the arrays with over 5600 multichroic (TES) detectors across new multichroic arrays in the low-frequency (27/39 GHz), medium-frequency (90/150 GHz), and high-frequency (150/230 GHz) bands, with each pixel containing multiple TES detectors tuned to distinct frequencies for enhanced mapping efficiency. These arrays achieved a per-detector noise equivalent difference () of approximately 300–500 μK √s at 150 GHz, balancing with operational stability under varying optical loading. Following decommissioning in 2022, AdvACT datasets are publicly available through NASA's archive. The TES arrays were fabricated through a collaboration between the National Institute of Standards and Technology (NIST) and NASA's (GSFC), involving processes such as bilayer deposition, for absorbers, and micromachining on large-diameter wafers to scale production. Readout employs time-domain multiplexing with superconducting quantum interference device () amplifiers, allowing simultaneous sampling of thousands of channels at rates up to 100 kHz per detector while minimizing crosstalk.

Observing Program

Survey Strategy

The Atacama Cosmology Telescope () primarily targets deep fields in the southern sky through its ACTPol and Advanced (AdvACT) observing campaigns, focusing on regions such as the deep56 (D56) field spanning 834 deg² and the BOSS-North (BN) field covering 1,633 deg², with total deep coverage approximately 2,500 deg² across equatorial and southern patches. These surveys emphasize high-resolution (CMB) measurements while avoiding the to minimize foreground contamination, achieving overall sky coverage of approximately 17,000 deg² in data releases up to DR4. The telescope employs a scanning mode consisting of continuous scans at speeds of approximately 1.5° per second, with the pointed at declinations ranging from -50° to +10° to optimize access to clean extragalactic regions. Scans occur at constant elevations between 30° and 60°, incorporating cross-linking by alternating rising and setting observations to enhance data uniformity and reduce systematic errors. To achieve required depth, the strategy involves multiple passes over each field across observing seasons from to , enabling to levels as low as 10 μK-arcmin in the deepest regions through repeated coverage and seasonal mapping. Optimization relies on simulations in longitude-speed-altitude () space to ensure uniform sensitivity and minimize idle time to under 1.3%, with field selection prioritizing overlaps with optical surveys for validation. Ancillary data integration includes cross-correlations with optical surveys such as the Dark Energy Survey (DES) to validate detections identified in maps. This approach supports robust cosmological analyses by combining ACT's millimeter-wave data with multi-wavelength observations.

Data Processing and Releases

The data processing pipeline for the Atacama Cosmology Telescope (ACT) transforms raw time-ordered data (TOD) from its arrays into cleaned sky maps of the (). Initial stages focus on TOD cleaning, which involves despiking to remove hits, modeling and subtraction using or , and common-mode removal across detectors to eliminate telescope-related drifts. Map-making follows, employing maximum likelihood techniques such as the MADmap , which iteratively estimates the sky signal by solving the incorporating the pointing model, beam response, and correlated noise covariance. This approach ensures unbiased reconstruction of anisotropies on arcminute scales while suppressing atmospheric residuals. Component separation is then applied to the multi-frequency maps to extract the from astrophysical foregrounds, including galactic , , and free-free emission. The internal (ILC) method is widely used, constructing a weighted sum of frequency channels that minimizes foreground variance while preserving the CMB's blackbody ; for data, this is often implemented in or needlet to handle scale-dependent foregrounds effectively. In recent analyses, tools classify and filter short-duration artifacts in TOD, enhancing data quality for measurements. Calibration ensures the maps reflect true sky brightness temperatures. Absolute calibration relies on nightly observations of planets, particularly Uranus, whose millimeter-wave emission is modeled precisely using ephemerides and brightness temperature profiles, converting raw power to thermodynamic temperature units with ~2% uncertainty. Relative calibration between detectors and frequencies is refined via cross-power spectra with external references like Planck CMB maps, achieving inter-frequency consistency at the 1% level and verifying large-scale fidelity. Beam solid angles and pointing are characterized through dedicated planet scans and optical encoder data. ACT data releases have progressively increased in scope, coverage, and precision, culminating in public datasets enabling diverse cosmological studies. DR1 (2011) released maps from the 2008 season, covering ~1,000 deg² at 148 GHz with initial power spectra. DR2 (2013) incorporated 2008–2010 , expanding to ~2,500 deg² across 148 and 218 GHz. DR4 (2020) provided coadded maps over 13,200 deg² at 150 GHz, including component-separated products. DR5 (2021) added from small deep fields (~280 deg² at 150 GHz) and enhanced simulations. DR6 (March 2025) marks the final major release, featuring full-mission and maps across 19,000 deg² in 98, 150, and 220 GHz bands, with median depths of ~10 µK-arcmin, derived power spectra (TT, TE, EE, BB), and full matrices accounting for noise correlations and masking. All ACT data products, including raw maps, noise realizations, transfer functions, and validation simulations, are publicly accessible via the NASA Legacy Archive for Microwave Background Data Analysis (LAMBDA). This repository supports interactive visualization tools and provides standardized formats (e.g., ) for community analysis, ensuring reproducibility and broad impact in CMB research.

Scientific Objectives

Primary Goals

The primary goals of the center on probing the early universe through high-resolution measurements of (CMB) anisotropies, which provide a snapshot of conditions shortly after the . By mapping temperature fluctuations in the CMB at arcminute angular scales, ACT aimed to test foundational models such as the inflationary , which posits a rapid expansion phase driven by a , against alternatives like cyclic cosmologies. These observations enabled the extraction of primordial power spectrum information, helping to verify the standard framework and understand the initial density perturbations that seeded large-scale . A key objective was to constrain fundamental cosmological parameters, including the baryon density Ω_b, density Ω_c, and Hubble constant H_0, by resolving the acoustic peaks in the CMB angular power spectrum. These peaks arise from sound waves in the early , offering precise tests of the standard ΛCDM model and insights into the composition of the at recombination. ACT's multi-frequency observations at 145, 220, and 280 GHz facilitated the separation of primordial signals from foreground contaminants, allowing for accurate determinations of these parameters with percent-level precision. To investigate and , ACT sought to leverage the acoustic oscillation (BAO) scale imprinted in the acoustic peaks, which serves as a standard ruler for measuring cosmic expansion history, alongside the integrated Sachs-Wolfe (ISW) effect, which traces the decay of gravitational potentials due to acceleration. These measurements aimed to quantify the equation-of-state parameter for and the normalization, probing the tension between early- and late-universe observations. By cross-correlating data with large-scale structure tracers, ACT intended to isolate late-time ISW contributions from primordial signals. Another core goal involved detecting and characterizing galaxy clusters through the thermal Sunyaev-Zel'dovich (tSZ) effect, where inverse of photons by hot intracluster gas produces a spectral distortion observable across ACT's frequency bands. This blind survey approach targeted the growth rate of cosmic structure, providing constraints on dynamics and the amplitude of matter fluctuations σ_8, independent of baryonic physics assumptions. Such studies complemented optical and follow-ups to map cluster evolution over . Finally, through its polarization-sensitive upgrades like ACTPol, the telescope aimed to search for primordial B-mode polarization patterns in the , which would be direct evidence of tensor perturbations generated during and reveal the energy scale of this epoch. These faint signals, distinguished from E-mode polarization via their curl nature, required ultra-sensitive detectors to overcome galactic foregrounds and achieve the necessary signal-to-noise for detecting or constraining the tensor-to-scalar ratio r.

Key Measurements

The Atacama Cosmology Telescope (ACT) targeted high-precision measurements of the (CMB) anisotropy power spectra, including temperature-temperature (), electric polarization-electric polarization (), and temperature-electric polarization () correlations, extending to multipoles up to \ell = 5000. These spectra provided constraints on cosmological parameters by probing the statistical of CMB fluctuations on small angular scales, where the telescope's high resolution was particularly advantageous. ACT reconstructed CMB lensing convergence maps using quadratic estimators applied to temperature and polarization data, enabling the mapping of the projected from large-scale structure along the . This technique isolated the lensing signal by exploiting non-Gaussian features in the observed fields, offering insights into the distribution of matter in the universe. The telescope measured Sunyaev-Zel'dovich (SZ) signals, including the thermal SZ effect through the Compton y-parameter, which quantifies the inverse of photons by hot gas in galaxy clusters, and the kinetic SZ effect, which traces peculiar velocities of clusters via Doppler shifts in the spectrum. These observables allowed for the study of cluster properties and content independent of . Additionally, ACT performed cross-correlations between CMB lensing maps and galaxy overdensities from surveys, facilitating tomographic analyses of structure growth and evolution of matter clustering. Combined analyses from ACT data achieved percent-level precision on parameters such as \sigma_8, the amplitude of matter fluctuations on 8 h^{-1} Mpc scales, particularly when integrating power spectra, lensing, and SZ measurements with external datasets like Planck. This level of accuracy supported stringent tests of \LambdaCDM cosmology and deviations potentially linked to inflation.

Major Scientific Results

Early Discoveries

In its initial years of operation starting in 2007, the Atacama Cosmology Telescope (ACT) achieved a landmark result with the first clear detection of seven acoustic peaks in the cosmic microwave background (CMB) temperature-temperature (TT) power spectrum, providing strong confirmation of the Lambda cold dark matter (ΛCDM) cosmological model. This measurement, based on 2008 observations at 148 GHz and 218 GHz covering approximately 500 square degrees of sky, resolved the higher-order peaks (second through seventh) with high significance, enabling precise tests of inflationary cosmology and the physics of the early universe. The data demonstrated excellent agreement with ΛCDM predictions, with the peaks arising from baryon acoustic oscillations in the primordial plasma. Building on this, ACT produced one of the earliest large-scale catalogs of galaxy clusters detected via the Sunyaev-Zel'dovich (SZ) effect, identifying over 100 objects across multiple surveys by 2011, including the exceptionally massive merging cluster "El Gordo" (ACT-CL J0102-4915) at redshift z=0.87. El Gordo, with an estimated mass exceeding 10^15 solar masses, stood out as one of the most extreme clusters known at the time, offering insights into rare high-mass systems and cluster formation in the early universe. The SZ detections, which probe the hot through , complemented and optical follow-ups to refine cluster masses and redshifts, advancing studies of large-scale structure growth. The deployment of the ACTPol receiver in 2013 enabled the first polarization-sensitive observations, yielding initial maps that detected the E-mode (EE) power spectrum of CMB polarization with high fidelity. These measurements, spanning multipoles from 200 to 3000, revealed six acoustic peaks in the EE spectrum, consistent with ΛCDM expectations from primordial scalar perturbations, and provided early constraints on the optical depth to reionization (τ ≈ 0.09). The polarization data, cleaner than temperature maps due to reduced foreground contamination, marked a key step toward detecting primordial B-mode signals. In 2015, ACT reported the first statistical detection of galaxy cluster peculiar velocities through the kinetic SZ (kSZ) effect, using cross-correlations between ACT maps and large-scale structure surveys like the Baryon Oscillation Spectroscopic Survey (BOSS). This pairwise kSZ signal, measured at 3.3σ significance, quantified bulk motions of clusters with an amplitude A_kSZ = 1.08 ± 0.26, directly tracing velocities and offering an independent probe of structure growth independent of distance assumptions. The result highlighted ACT's role in measuring the on large scales. These early discoveries collectively tightened cosmological constraints, achieving 2-3% precision on key parameters such as the of fluctuations σ_8 ≈ 0.82 and the present-day density Ω_m ≈ 0.28 when combining power spectra, SZ cluster abundances, and other datasets. This precision helped validate ΛCDM while identifying tensions with cluster-based inferences of structure growth.

Recent Findings

In 2019, the Advanced ACTPol (AdvACT) upgrade enabled the production of gravitational lensing maps of the () with improved compared to previous ACTPol analyses, covering thousands of square degrees of sky. These maps facilitated tighter constraints on the sum of masses when combined with primary data. The 2020 Data Release 4 (DR4) polarization analysis from ACT provided a high-significance detection of lensing-induced B-mode polarization in the CMB, confirming the expected secondary contribution from gravitational lensing of primordial E-modes. This measurement, derived from multifrequency observations spanning 2013–2016, also refined the Hubble constant to H_0 = 67.6 \pm 1.1 km/s/Mpc in a flat \LambdaCDM model when joint with WMAP, aligning closely with Planck results. Data Release 6 (DR6) in 2025 delivered the clearest CMB images to date, based on observations from 2013–2020 with enhanced noise levels three times lower than Planck in polarization and five times better angular resolution. These maps enabled precise measurements of E-mode polarization power spectra up to multipoles \ell \approx 5000, supporting standard \LambdaCDM cosmology. Joint analyses with Planck legacy data addressed tensions in \LambdaCDM parameters, such as the structure growth amplitude S_8 = 0.830 \pm 0.014, reducing discrepancies with late-universe probes to below 1.5\sigma. The DR6 results confirm the universe's age at 13.8 billion years with 0.1% precision and align measurements of the Hubble constant with CMB-based estimates. They also quantify the observable universe's mass at about 1,900 zetta-solar masses, comprising roughly 5% ordinary matter, 25% dark matter, and 70% dark energy, while ruling out most alternative cosmological models without invoking new physics. In cluster science, has identified over 4,000 Sunyaev-Zel'dovich ()-detected galaxy clusters across more than 13,000 square degrees, forming the largest SZ-selected catalog to date with signal-to-noise greater than 4. These clusters, spanning redshifts up to z > 1, probe through the growth of structure, yielding constraints on the growth function f\sigma_8 that test deviations from and \LambdaCDM on cosmological scales. Broader implications from these findings include no evidence for primordial gravitational waves in the B-mode spectra, with tensor-to-scalar ratio limits r < 0.07 at 95% confidence, consistent with single-field slow-roll models.

Collaborating Institutions

Leadership and Funding

The Atacama Cosmology Telescope (ACT) project was led by principal investigator Mark C. Devlin of the from 2007 to 2013, a period that encompassed , commissioning, and the initiation of observations. From 2013 to 2022, Jo Dunkley of served as principal investigator, guiding the project's advanced instrumentation upgrades, extended data collection campaigns, and comprehensive analysis efforts leading to major scientific releases. Project management and coordination were handled by the Cosmology Initiative, which oversaw collaboration logistics, resource allocation, and integration across participating institutions. Funding for the ACT was primarily secured through grants from the U.S. (NSF), including the initial construction grant AST-0408698 awarded in 2003, as well as subsequent awards AST-0965625 and AST-1440226, which together provided over $20 million across the project's nearly two-decade span. Supplementary support came from the U.S. Department of Energy (grants DE-SC0007907 and DE-SC0015941), (including grant HST-AR-16199.01-A and grant GO2-23151X), and international sources such as the Science and Technology Facilities Council (grant ST/S000437/1). These funds sustained operations until the telescope's final data collection in 2022 and decommissioning thereafter.

Member Organizations

The Atacama Cosmology Telescope (ACT) collaboration is led by and comprises scientists from 22 institutions across the and internationally. oversees telescope operations at the site in Chile's . Core U.S. member organizations include , , the , , the National Institute of Standards and Technology (NIST), NASA Goddard Space Flight Center, , the , , and the (supported by the ). NIST played a key role in detector fabrication, developing superconducting sensors and electronics for multiple generations of ACT instruments, including the first multi-color camera for measurements. International member organizations include (), the (), (), (), (), (United States, with international components), and others such as institutions in and . The collaboration is structured around working groups focused on development, , and theoretical modeling to support ACT's cosmological objectives.

References

  1. [1]
    Atacama Cosmology Telescope (ACT) Overview - Nasa Lambda
    The Atacama Cosmology Telescope (ACT) is a six-meter diameter telescope on Cerro Toco in the Atacama Desert of northern Chile (image above by Jon Ward).
  2. [2]
    Atacama Cosmology Telescope | NIST
    Sep 30, 2021 · Located at an altitude of 5,190 meters (17,030 feet), ACT is one of the highest permanent, ground-based telescopes in the world. The arid, high- ...
  3. [3]
    Introduction - Atacama Cosmology Telescope - Princeton University
    The goals of the ACT project are to study how the universe began, what it is made of, and how it evolved to its current state.
  4. [4]
    Atacama Cosmology Telescope
    The Atacama Cosmology Telescope​​ The goals of the ACT project are to study how the universe began, what it is made of, and how it evolved to its current state. ...Introduction · Publications · ACTPol · Experimental
  5. [5]
    New high-definition images released of the baby universe
    Mar 18, 2025 · Observations by the Princeton-led Atacama Cosmology Telescope suggest that the universe is 13.8 billion years old. A group of five galaxies. New ...
  6. [6]
    Clearest images yet of 380,000-year-old baby universe released
    Mar 19, 2025 · The new results confirm a simple model of the universe and have ruled out a majority of competing alternatives, says the research team.
  7. [7]
    [PDF] The Atacama Cosmology Telescope - arXiv
    Initial planning was supported by NSF award PHY00-99493 to Lyman Page at Princeton and NSF award AST97-32960 to Mark Devlin at the University of Pennsylvania ...Missing: inception | Show results with:inception
  8. [8]
    None
    ### Summary of Atacama Cosmology Telescope Details
  9. [9]
    THE ATACAMA COSMOLOGY TELESCOPE - IOP Science
    Many have contributed to the project since its inception. We ... Funding was also provided by Princeton University and the University of Pennsylvania.
  10. [10]
    THE POLARIZATION-SENSITIVE ACTPol INSTRUMENT - IOPscience
    The Atacama Cosmology Telescope (ACT) makes high angular resolution measurements of anisotropies in the Cosmic Microwave Background (CMB) at millimeter ...Missing: phases AdvACT
  11. [11]
    The polarization-sensitive ACTPol instrument - arXiv
    May 21, 2016 · ACTPol comprises three arrays with separate cryogenic optics: two arrays at a central frequency of 148 GHz and one array operating ...
  12. [12]
    [1711.02594] Advanced ACTPol Low Frequency Array - arXiv
    Nov 7, 2017 · Advanced ACTPol (AdvACT) is a third generation polarization upgrade to the Atacama Cosmology Telescope, designed to observe the cosmic microwave ...
  13. [13]
    [PDF] The Advanced ACTPol 27/39 GHz Array
    May 21, 2018 · AdvACT is an upgraded camera for the Atacama Cosmology Telescope that will measure the CMB in both temperature and polarization over a wide ...Missing: operational | Show results with:operational
  14. [14]
    Advanced ACTPol Cryogenic Detector Arrays and Readout - arXiv
    Oct 9, 2015 · Advanced ACTPol is a polarization-sensitive upgrade for the 6 m aperture Atacama Cosmology Telescope (ACT), adding new frequencies and increasing sensitivity.
  15. [15]
    The Atacama Cosmology Telescope: Modeling bulk atmospheric ...
    Feb 17, 2022 · This paper considers around 15,000 hours of observation by ACT from between May 2017 and January 2021.
  16. [16]
    New findings that map the universe's cosmic growth support ...
    May 2, 2023 · ... decommissioned in September 2022. Nevertheless, more ... The Atacama Cosmology Telescope: DR6 Gravitational Lensing Map and Cosmological ...
  17. [17]
    New cosmic 'baby pictures' reveal our universe taking its 1st ... - Space
    Mar 18, 2025 · The new images come from the now-retired Atacama Cosmology Telescope which shuttered its cosmic eye in 2022. Comments (0) ( 1 ).
  18. [18]
    All about the Vatican Observatory's Adjunct Scholars program
    Jan 31, 2025 · The Atacama Cosmology Telescope in Chile (now decommissioned). 1 ... The ACT was decommissioned in 2022 to make way for newer telescopes.
  19. [19]
    The Atacama Cosmology Telescope: CMB Polarization at $200<\ell ...
    May 21, 2014 · We report on measurements of the cosmic microwave background (CMB) and celestial polarization at 146 GHz made with the Atacama Cosmology Telescope Polarimeter ...Missing: legacy | Show results with:legacy
  20. [20]
    [PDF] The Atacama Cosmology Telescope: A measurement of the Cosmic ...
    Jul 14, 2020 · Funding was also provided by Princeton Uni- versity, the University of Pennsylvania, and a Canada. Foundation for Innovation (CFI) award to UBC.<|control11|><|separator|>
  21. [21]
    Simons Observatory - Simons Foundation
    This collaboration is the first attempt at merging two CMB teams, from the Atacama Cosmology Telescope and the Polar Bear/Simons Array experiments, now working ...
  22. [22]
    CMB—Stage 4
    The South Pole telescopes will conduct an ultra-deep survey of 3% of the sky, while the Atacama telescopes will conduct a complementary ultra-wide and deep ...
  23. [23]
    Atacama Cosmology Telescope Publishes Final Major Data Release
    Mar 18, 2025 · The latest data from the Atacama Cosmology Telescope collaboration includes the clearest and most precise measurements yet of the universe's earliest light.<|control11|><|separator|>
  24. [24]
    Specifications - Atacama Cosmology Telescope - Princeton University
    ACT observes simultaneously in three frequency bands centered on 148 GHz, 218 GHz, and 277 GHz. ... This measurement includes neutral density filters in each band ...
  25. [25]
    [PDF] The Atacama Cosmology Telescope Daniel S. Swetz
    The effects of the mechanical performance and alignment of the Atacama Cosmology Telescope on the sensitivity of microwave observations. Millimeter and ...
  26. [26]
    Detecting Life in the Ultra-dry Atacama Desert
    Apr 20, 2017 · Chile's Atacama Desert is the driest non-polar desert on Earth -- and a ready analog for Mars' rugged, arid terrain. Credit: NASA/JPL-Caltech.
  27. [27]
    The Atacama Cosmology Telescope - ScienceDirect.com
    Initial planning was supported by NSF award PHY00-99493 to Lyman Page at Princeton and NSF award AST97-32960 to Mark Devlin at the University of ...Missing: inception | Show results with:inception
  28. [28]
    [PDF] From Data to Maps with the Atacama Cosmology Telescope
    The understanding of cosmology has been boosted by the study of the Cosmic Mi- crowave Background (CMB). After the full sky survey done by WMAP, which set-.
  29. [29]
    Twenty years of precipitable water vapor measurements in the ...
    Cerro Chajnantor, located next to the plateau, has a summit altitude of 5640 m and has averages of 518 mbar in atmospheric pressure and 268 K in temperature.
  30. [30]
    The ALMA Site — ALMA Science Portal at NRAO
    This image shows that during more that 50 % of the time between April and December, the PWV is below 1 mm (green quartile), and during the 5 best months (May- ...
  31. [31]
    https://ar5iv.labs.arxiv.org/html/astro-ph/0402234
  32. [32]
    [astro-ph/0402234] The Atacama Cosmology Telescope - ar5iv - arXiv
    While the South Pole has a lower yearly-averaged atmospheric opacity than the ACT site, well-understood annual and diurnal fluctuations at the Chile site bias ...
  33. [33]
    OVERVIEW OF THE ATACAMA COSMOLOGY TELESCOPE
    The telescope was commissioned at its site in late 2007, at which time the 148 GHz channel was installed in MBAC. The remaining two frequencies were ...Missing: October | Show results with:October
  34. [34]
    Optical Design of the Atacama Cosmology Telescope and the ... - arXiv
    Dec 31, 2006 · The Atacama Cosmology Telescope is a 6-meter telescope designed to map the Cosmic Microwave Background simultaneously at 145 GHz, 215 GHz, and 280 GHz with ...Missing: system | Show results with:system
  35. [35]
    None
    ### Summary of Cryogenic Receiver for ACTPol/AdvACT
  36. [36]
    [PDF] THE ATACAMA COSi'vl0LOGY TELESCOPE: THE RECEIVER AND ...
    The telescope was commissioned at its site in late 2007, at which time the 148 GHz channel was installed in MBAC. The remaining two frequencies were installed ...
  37. [37]
    https://act.princeton.edu/sites/g/files/toruqf1171/files/thesis_marriage_tobias.pdf
  38. [38]
    [PDF] Detectors for the Atacama Cosmology Telescope
    This chapter is a review of TES detector fabrication, emphasizing the key attributes required for ACT detector characterization. The overall process ...
  39. [39]
    The First Multichroic Polarimeter Array on the Atacama Cosmology ...
    Mar 15, 2016 · Fabricated at NIST, this dichroic array consists of 255 pixels, with a total of 1020 polarization sensitive bolometers and is coupled to the ...
  40. [40]
    [PDF] Measuring two-millimeter radiation with a prototype multiplexed TES ...
    The Atacama Cosmology Telescope (ACT) will study the Cosmic Microwave Background (CMB), the oldest light in the universe, on 1.4 to one degree scales. 1, 2. The ...Missing: phase | Show results with:phase
  41. [41]
    The Atacama Cosmology Telescope: Systematic Transient Search of ...
    Oct 13, 2023 · ACT covers 40% of the sky at three bands spanning from 77–277 GHz. Analysis of 3 day mean-subtracted sky maps, which were match filtered for ...
  42. [42]
    Survey strategy optimization for the Atacama Cosmology Telescope
    Jul 7, 2016 · We describe the optimization and implementation of the ACTPol and AdvACT surveys. The selection of the observed fields is driven mainly by the ...Missing: MBAC | Show results with:MBAC
  43. [43]
    [1208.0050] The Atacama Cosmology Telescope: Data ... - arXiv
    Jul 31, 2012 · In 2008 we observed for 136 days, producing a total of 1423 hours of data (11 TB for the 148 GHz band only), with a daily average of 10.5 hours ...
  44. [44]
    [2307.01258] The Atacama Cosmology Telescope: High-resolution ...
    Jul 3, 2023 · ... frequencies of roughly 93, 148, and 225 GHz, together with data from the \textit{Planck} satellite at frequencies between 30 GHz and 545 GHz.Missing: MBAC | Show results with:MBAC
  45. [45]
    The Atacama Cosmology Telescope: Machine-learning-driven Tools ...
    We present a new pipeline utilizing machine learning for classifying short-duration features in raw time-ordered data (TOD) of cosmic microwave background ...
  46. [46]
    THE ATACAMA COSMOLOGY TELESCOPE: CALIBRATION WITH ...
    Oct 3, 2011 · We present a new calibration method based on cross-correlations with the Wilkinson Microwave Anisotropy Probe (WMAP) and apply it to data from ...Missing: loads dips
  47. [47]
    The Atacama Cosmology Telescope - Calibration with WMAP - arXiv
    Sep 3, 2010 · We present a new calibration method based on cross-correlations with WMAP and apply it to data from the Atacama Cosmology Telescope (ACT).Missing: receiver internal loads
  48. [48]
    [PDF] THE ATACAMA COSMOLOGY TELESCOPE: DR4 MAPS AND ...
    Jul 14, 2020 · ACT has a blind pointing accuracy of about 10 for the nighttime ... After applying these pointing correc- tions we measure a residual per-map ...
  49. [49]
    DR6 Power Spectra, Likelihoods and $Λ$CDM Parameters - arXiv
    Mar 18, 2025 · These cover 19,000 deg^2 of sky in bands centered at 98, 150 and 220 GHz, with white noise levels three times lower than Planck in polarization.
  50. [50]
    [2103.03154] The Atacama Cosmology Telescope: Summary of DR4 ...
    Mar 4, 2021 · Two recent large data releases for the Atacama Cosmology Telescope (ACT), called DR4 and DR5, are available for public access.
  51. [51]
    The Atacama Cosmology Telescope: Summary of DR4 and DR5 ...
    Two recent large data releases for the Atacama Cosmology Telescope (ACT), called DR4 and DR5, are available for public access.Missing: DR1 DR6
  52. [52]
    [1007.0290] The Atacama Cosmology Telescope: The Receiver and ...
    Jul 2, 2010 · The Atacama Cosmology Telescope was designed to measure small-scale anisotropies in the Cosmic Microwave Background and detect galaxy clusters.
  53. [53]
    ACTPol: A polarization-sensitive receiver for the Atacama ... - arXiv
    Jun 25, 2010 · The six-meter Atacama Cosmology Telescope (ACT) in Chile was built to measure the cosmic microwave background (CMB) at arcminute angular scales.
  54. [54]
    https://arxiv.org/abs/1006.5049
  55. [55]
    Atacama Cosmology Telescope: Combined kinematic and thermal ...
    Mar 15, 2021 · Being independent of redshift, these SZ effects are uniquely well suited for studying high redshift galaxies and clusters. Since the kSZ signal ...Missing: kinetic | Show results with:kinetic
  56. [56]
    THE ATACAMA COSMOLOGY TELESCOPE: A MEASUREMENT OF ...
    Feb 9, 2011 · THE ATACAMA COSMOLOGY TELESCOPE: A MEASUREMENT OF THE COSMIC MICROWAVE BACKGROUND POWER SPECTRUM AT 148 AND 218 GHz FROM THE 2008 SOUTHERN ...Missing: inception | Show results with:inception
  57. [57]
    SUNYAEV–ZEL'DOVICH-SELECTED GALAXY CLUSTERS AT 148 ...
    Aug 4, 2011 · ... Atacama Cosmology Telescope 2008 observing season. All SZ detections ... Funding was also provided by Princeton University and the University of ...
  58. [58]
    THE ATACAMA COSMOLOGY TELESCOPE: ACT-CL J0102−4915 ...
    We present a detailed analysis from new multi-wavelength observations of the exceptional galaxy cluster ACT-CL J0102−4915.
  59. [59]
    [PDF] ACT DR6: Testing structure growth with new CMB lensing ...
    With AdvACT we have powerful new lensing maps, giving state-of-the- art S8 + neutrino masses this year! • Lensing and galaxy surveys can measure Hubble constant ...<|separator|>
  60. [60]
    [1811.07636] Understanding the neutrino mass constraints ... - arXiv
    Nov 19, 2018 · Understanding the neutrino mass constraints achievable by combining CMB lensing and spectroscopic galaxy surveys. Authors:Aoife Boyle.Missing: AdvACT | Show results with:AdvACT
  61. [61]
    [PDF] DR6 Constraints on Extended Cosmological Models ABSTRACT We ...
    Mar 18, 2025 · ABSTRACT. We use new cosmic microwave background (CMB) primary temperature and polarization anisotropy measurements from the Atacama ...
  62. [62]
    A Catalog of > 4000 Sunyaev-Zel'dovich Galaxy Clusters - arXiv
    Sep 23, 2020 · We present a catalog of 4195 optically confirmed Sunyaev-Zel'dovich (SZ) selected galaxy clusters detected with signal-to-noise > 4 in 13,211 ...Missing: growth function fσ8
  63. [63]
    [2503.14454] The Atacama Cosmology Telescope: DR6 Constraints ...
    Mar 18, 2025 · We derive constraints from the ACT DR6 power spectra alone, as well as in combination with legacy data from Planck. To break geometric ...
  64. [64]
    Mark Devlin and Colleagues Awarded NSF Grant to Upgrade ...
    May 9, 2023 · The $52.66 million grant will fund a major infrastructure upgrade to the Simons Observatory (SO). Located in the high Atacama Desert in Northern Chile.Missing: 2000s Lyman
  65. [65]
    Jo Dunkley, Suzanne Staggs and colleagues awarded $53M to ...
    May 18, 2023 · The National Science Foundation has awarded a $52.66 million grant to fund a major infrastructure upgrade to the Simons Observatory in the Atacama Desert of ...Missing: inception | Show results with:inception
  66. [66]
    Atacama Cosmology Telescope
    ### Summary of Atmospheric Conditions, PWV, Weather, and Advantages for Observations
  67. [67]
    The Atacama Cosmology Telescope: A Search for Planet 9
    The mission of the AAS is to enhance and share humanity's scientific understanding of the universe. ... The only current CMB survey telescopes with a high enough ...
  68. [68]
    The Atacama Cosmology Telescope project: A progress report
    The Atacama Cosmology Telescope is a project to map the microwave background radiation at arcminute angular resolution and high sensitivity in three ...
  69. [69]
    Our Partners | Atacama Cosmology Telescope - Princeton University
    Our Partners · Berkeley · Chile · Cornell University · JHU · NIST · UPenn · Sapienza University of Rome.Missing: institutions | Show results with:institutions