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SPHEREx

SPHEREx (Spectro-Photometer for the History of the Universe, Epoch of Reionization and Ices Explorer) is a NASA space observatory launched on March 11, 2025, aboard a SpaceX Falcon 9 rocket from Vandenberg Space Force Base in California, designed to perform an all-sky spectroscopic survey in near-infrared light (0.75–5.0 μm) over a planned two-year mission.^[1]^[2] The mission aims to collect spectra from more than 450 million galaxies and over 100 million stars in the Milky Way, providing unprecedented data on cosmic evolution.^[1] The observatory addresses three primary scientific themes: probing the origin of the universe by testing cosmic inflation through measurements of large-scale structure via the three-dimensional distribution of galaxies; tracing the history of galaxy formation by studying fluctuations in the extragalactic background light, particularly through deeper observations at the ecliptic poles; and investigating the origins of water and other biogenic molecules (such as H₂O, CO, CO₂, and CH₃OH) in molecular clouds associated with star and planet formation.^[3] These goals will enable SPHEREx to create detailed maps of the universe's infrared spectrum, revealing insights into the epoch of reionization, the distribution of cosmic water ice, and the large-scale structure of the cosmos.^[1] SPHEREx features a simple, cost-effective design with no moving parts after initial deployments of its sunshield and aperture cover, orbiting in a sun-synchronous low Earth orbit to maintain consistent solar positioning throughout the year.^[3]^[4] Its spectro-photometer instrument will observe the entire sky multiple times, acquiring at least four spectra per point on the ecliptic with greater depth than previous surveys like 2MASS.^[3] Managed by NASA's Jet Propulsion Laboratory (JPL) with principal investigator responsibilities at the California Institute of Technology (Caltech), the mission involves collaboration with partners including Ball Aerospace for spacecraft construction.^[5]^[3] As of November 2025, SPHEREx is fully operational, having begun its sky survey on May 1, 2025, and actively collecting data, including observations of the interstellar object 3I/ATLAS in August 2025.^[6]^[7]^[8] Early data releases are available through the NASA/IPAC Infrared Science Archive, supporting ongoing research into astrophysics and planetary science.^[9]

Overview

Mission concept

SPHEREx, the Spectro-Photometer for the History of the Universe, Epoch of Reionization and Ices Explorer, is a NASA mission designed to conduct the first all-sky spectroscopic survey in the near-infrared, providing low-resolution spectra for millions of celestial objects to probe fundamental questions about the universe's origins, galaxy evolution, and the conditions for life.^[5] The mission employs a wide-field telescope paired with linear variable filters to enable simultaneous broadband imaging and spectroscopy across the wavelength range of 0.75 to 5.0 micrometers, capturing 102 spectral bands with a resolution of R ≈ 35–130.^[10] This approach allows for the detection of key spectral lines, facilitating redshift measurements for distant galaxies and identification of molecular signatures such as water ice in interstellar clouds.^[11] The survey strategy involves scanning the entire sky from a low-Earth orbit, achieving full coverage with a pixel scale of 6.2 arcseconds and observing each sky position at least four times over the nominal two-year mission duration to build high-fidelity spectral data cubes.^[10] Deeper observations will target fields at the north and south ecliptic poles, enhancing sensitivity for faint sources.^[12] By utilizing passive cooling and a stable platform with no moving parts during operations (beyond initial deployments), SPHEREx ensures consistent data quality across its 11° × 3.5° field of view.^[11] This observational design targets spectra from approximately 450 million galaxies to map large-scale cosmic structures and trace the epoch of reionization, alongside data from over 100 million stars in the Milky Way to study galactic astrophysics, including the distribution of young stars and interstellar medium properties.^[5] Additionally, the mission will map the presence of water ice and other volatiles in molecular clouds, revealing the building blocks of planetary systems.^[13] The resulting legacy dataset, with its broad spectral coverage and all-sky scope, will serve as a foundational resource for diverse astronomical research long after the mission concludes.^[14]

Launch and current status

SPHEREx launched successfully on March 11, 2025, at 8:10 p.m. PDT (03:10 UTC on March 12) aboard a SpaceX Falcon 9 Block 5 rocket from Vandenberg Space Force Base in California, co-manifested with NASA's PUNCH mission consisting of four microsatellites.^[15] The spacecraft achieved successful separation approximately 42 minutes after liftoff and acquired its initial orbit without incident.^[16] The mission operates in a Sun-synchronous low Earth orbit at an altitude of 700 km, with a 97° inclination and a 90-minute orbital period, enabling consistent lighting conditions for its all-sky surveys.^[2] As of November 19, 2025, the mission has elapsed approximately eight months since launch, with first light achieved in April 2025 following initial checkout. Science operations commenced on May 1, 2025, and the spacecraft is performing nominally, capturing about 600 exposures per day—each comprising 3,600 images across its detectors—to support the prime mission's 25-month duration aimed at producing multiple all-sky spectral maps.^[6] No major anomalies have been reported, and the mission remains on track for completion of its planned surveys.^[17]

Scientific objectives

Cosmological investigations

SPHEREx's primary cosmological goal is to measure baryon acoustic oscillations (BAO) and galaxy clustering across vast volumes of the universe to constrain models of cosmic inflation and parameters governing dark energy.^[1] By mapping the large-scale structure imprinted by these phenomena, the mission aims to refine our understanding of the universe's expansion history and the physics of its earliest moments.^[18] These measurements will complement higher-redshift surveys from missions like Euclid and Roman, focusing on low-redshift regimes where SPHEREx excels due to its all-sky coverage and spectroscopic capabilities. A cornerstone of SPHEREx's cosmological program involves conducting redshift surveys of approximately 450 million galaxies, extending up to redshifts of z ≈ 1.5, with photometric redshift accuracies better than 10% for the full sample and 0.3% for a subset of about 16 million brighter sources.^[19] This unprecedented dataset provides the statistical power needed to detect primordial non-Gaussianity through the scale-dependent bias in galaxy clustering, where deviations from Gaussian initial conditions manifest as enhancements in clustering on large scales. The survey's volume, approaching the cosmic mean density limit, enables precise tomographic analyses that isolate these signals, potentially achieving constraints on the non-Gaussianity parameter f_NL at the level of Δf_NL ≈ 1 (2σ), distinguishing multi-field inflation models (where |f_NL| > 1) from single-field scenarios (where |f_NL| ≲ 10^-2).^[18] The galaxy power spectrum serves as a key observable for these investigations, modeled as

P(k) = b^2 P_m(k) + \cdots,

where P(k) is the galaxy power spectrum, b is the linear galaxy bias, P_m(k) is the matter power spectrum, and the ellipsis denotes higher-order terms including scale-dependent contributions from primordial non-Gaussianity. In the presence of local-type non-Gaussianity, the bias acquires a k-dependent correction Δb(k) ∝ f_NL/k², allowing SPHEREx to probe the amplitude of inflationary fluctuations and the energy scale of inflation through the bispectrum as well. These analyses will yield improved limits on the spectral index of scalar perturbations and the running of that index, tightening bounds on inflationary paradigms.^[18] Additionally, SPHEREx will employ line intensity mapping of emission lines from galaxies to probe the reionization history of the universe, offering insights into the reionization history of the universe by measuring the intensity fluctuations of emission lines such as [O III] and Hα, which correlate with ionizing photon production.^[1] This technique, applied over redshifts z ≈ 2–5, will constrain the timeline and sources of reionization, integrating with galaxy clustering data to model the transition from neutral to ionized intergalactic medium. Overall, these outcomes are expected to enhance constraints on dark energy's equation-of-state parameters by up to 20–30% when combined with BAO scales, providing a robust test of the ΛCDM model.

Astrophysical surveys

SPHEREx's astrophysical surveys target the Milky Way and nearby galaxies to map stellar populations and trace the history of star formation and chemical evolution across the local universe. The mission will conduct spectroscopic observations of over 100 million stars in the Milky Way, providing low-resolution spectra that enable the classification of stellar types and the measurement of metallicities through line ratios in its 102-band photometry covering 0.75 to 5 μm.^[5]^[3] This comprehensive mapping will reveal the spatial distribution of stellar ages and compositions, offering insights into the galaxy's dynamical history and the processes driving its chemical enrichment over billions of years. A key aspect of these surveys involves identifying prominent emission lines, such as Paschen-alpha from ionized hydrogen and polycyclic aromatic hydrocarbon (PAH) features at around 3.3 μm, to delineate active star-forming regions within the interstellar medium. By resolving these spectral signatures, SPHEREx will quantify dust extinction effects, which obscure optical light and influence the observed distribution of young stars and molecular clouds.^[20] In nearby galaxies, similar spectroscopic data will extend this analysis, allowing comparisons of star formation efficiencies and dust properties across different galactic environments.^[5] These observations also contribute to astrobiology by detecting organic molecules in interstellar clouds, such as precursors to complex organics that seed planetary system formation. SPHEREx's sensitivity to near-infrared absorption and emission will catalog the abundance and evolution of these molecules in star-forming environments, linking them to the broader chemical pathways in the galaxy. Water ice, as a common component in these clouds, provides contextual insight into the icy reservoirs that harbor such organics.^[21]

Detection of ices and water

SPHEREx's detection of ices and water focuses on conducting an all-sky spectroscopic survey to map the distribution of water ice and other volatile ices, such as CO and CO₂, within molecular clouds and protoplanetary disks across the Milky Way galaxy.^[21]^[22] This core objective addresses key questions about the abundance and evolution of biogenic molecules like H₂O, CO, CO₂, and CH₃OH during star and planet formation phases, providing the first comprehensive census of these materials on galactic scales.^[23] By targeting absorption features in the near-infrared spectrum, particularly the broad water ice band at approximately 3 μm, SPHEREx will observe over 9 million lines of sight toward obscured sources in the Galactic plane, enabling a statistical understanding of ice reservoirs that are largely inaccessible to previous ground-based or space telescopes.^[24]^[23] The methodology relies on low-resolution spectroscopy (R ≈ 110–130) across the 0.75–5.0 μm wavelength range, achieved through linear variable filters on six broadband detector arrays, to measure ice column densities along these sightlines.^[23]^[25] Ice detection occurs via absorption against background and embedded stars, with sensitivity to absorption depths as low as ~6% corresponding to thin ice layers of about 20 nm.^[23] This approach will allow estimation of the total water ice reservoir in the galaxy, which is predominantly locked in icy mantles on interstellar dust grains, comprising over 99% of the interstellar water content.^[26] The survey targets highly obscured regions (A_V > 2 mag) selected from 2MASS and WISE catalogs, yielding spectra for approximately 8.6 × 10⁶ objects brighter than W2 ≈ 12 mag, facilitating a >10,000-fold expansion of the existing database of ice absorption spectra.^[25]^[23] A detailed aspect of this detection involves quantifying ice features through equivalent width measurements of absorption bands, defined as

W_\lambda = \int \left(1 - \frac{F_\lambda}{F_{\rm cont}}\right) d\lambda,

where F_\lambda is the observed flux and F_{\rm cont} is the continuum flux, providing a resolution-independent metric for ice abundance.^[23] For water ice, this targets the 2.9–3.5 μm feature, while other ices like CO at 4.67 μm and CO₂ are resolved in the longer-wavelength bands (3.82–5.0 μm).^[23] These measurements will probe ice formation processes on dust grains shielded from cosmic rays in dense molecular clouds, as well as their incorporation into protoplanetary disks around young stars.^[22] The science impact of these observations lies in revealing how ices contribute to planetary habitability by tracing their delivery mechanisms to forming worlds, ultimately informing the origins of liquid water oceans and potential prebiotic chemistry.^[21]^[24] By surveying millions of sightlines through ~10⁶ molecular clouds, SPHEREx will map variations in ice composition and abundance across diverse environments, from quiescent clouds to active star-forming regions, offering insights into the chemical evolution of volatiles essential for life.^[25] This dataset will enable studies of ice processing by radiation and shocks, linking interstellar chemistry to the building blocks of habitable planets.^[23]

Spacecraft and instruments

Telescope design

The SPHEREx telescope features an off-axis three-mirror anastigmat optical design, consisting of three reflective mirrors that collect near-infrared light without obstructions from secondary optics, thereby minimizing aberrations across a wide field of view.^[2]^[27] This all-reflective configuration eliminates chromatic aberrations inherent in refractive systems, making it ideal for broadband near-infrared observations from 0.75 to 5.0 micrometers.^[28] The primary mirror has an effective aperture diameter of 20 centimeters, enabling efficient light gathering for the mission's all-sky survey requirements.^[29] The telescope provides an instantaneous field of view of approximately 11.3° × 3.5°, allowing for rapid coverage of large sky areas during each orbit; this equates to roughly 40 square degrees, facilitating multiple scans of the entire sky over the two-year mission.^[29] To achieve the low thermal noise essential for sensitive infrared detection, the optics are passively cooled to below 80 K using a three-stage V-groove sunshield system that blocks radiative heat from the Sun and Earth, without relying on active cryocoolers.^[28] Nested conical photon shields further protect the instrument from stray light and thermal inputs, ensuring stable operation in the space environment.^[30] Constructed primarily from aluminum for its thermal stability and lightweight properties, the telescope maintains precise optical alignment through passive thermal control mechanisms that minimize expansion and contraction in varying orbital temperatures.^[30] BAE Systems, leveraging expertise from prior missions, manufactured the telescope assembly, integrating it with the spacecraft bus to form a robust, compact unit weighing 502 kilograms in total.^[31]^[32] A key engineering challenge was preserving mirror alignment under thermal gradients and launch vibrations, addressed by the all-aluminum structure's low coefficient of thermal expansion and rigorous pre-launch testing.^[33] This design feeds light directly into the spectro-photometer for spectral dispersion, enabling the mission's core science measurements.^[28]

Spectro-photometer

The SPHEREx spectro-photometer employs linear variable filters (LVFs) to enable low-resolution near-infrared spectrophotometry without moving parts, feeding dispersed light from the telescope's focal plane into six 2048×2048 pixel HAWAII-2RG mercury cadmium telluride (HgCdTe) detector arrays (three optimized for 2.5 μm cutoff and three for 5.3 μm cutoff).^[11] This configuration allows simultaneous imaging and spectrophotometry across a wide field, with the short-wavelength arrays handling 0.75–3.8 μm and the long-wavelength arrays covering up to 5.0 μm.^[11] The system's simplicity enhances reliability for the mission's all-sky survey requirements.^[11] Spectral coverage spans 0.75 to 5.0 μm, segmented into 102 bands that provide spectrophotometric data for each observed point source.^[34] The resolving power varies from R ≈ 35–41 in the shorter wavelength bands (0.75–3.8 μm), enabling detailed line diagnostics in the near-infrared, while the longer wavelength bands deliver higher resolution of R ≈ 110–130 beyond 3.8 μm to capture continuum features efficiently.^[11] This banded approach balances sensitivity and spectral detail, supporting analyses of galaxy redshifts and molecular ices.^[11] The HAWAII-2RG detectors are fabricated from arsenic-doped silicon to achieve high near-infrared sensitivity, minimizing dark current and enabling operation at cryogenic temperatures below 55 K for long-wavelength arrays and below 80 K for short-wavelength arrays.^[11] Readout electronics, including custom sideloaded CMOS multiplexers, support rapid acquisition of up to 600 frames per day per array, facilitating the high-cadence observations needed for the mission's 102 monthly all-sky maps.^[34] Performance is characterized by a noise equivalent flux density of approximately $10^{-17} W m^{-2} μm^{-1} (√Hz)^{-1}, which ensures detection of faint extragalactic sources down to AB magnitudes of 19 in broadband filters.^[34] Quantum efficiency exceeds 70% across the operational band, optimizing photon collection for the survey's depth.^[34] These metrics position the spectro-photometer as a sensitive tool for probing cosmic evolution and interstellar chemistry.^[34]

Orbit and mission operations

SPHEREx operates in a polar, sun-synchronous low-Earth orbit at an altitude of approximately 650 km, positioned along Earth's day-night terminator to maintain consistent solar illumination conditions across observations.^[35] This orbital configuration, with an inclination near 98 degrees, enables the spacecraft to complete about 14.5 orbits per day, facilitating repeated all-sky coverage without significant variations in lighting angles.^[35] The mission does not require active orbit maintenance propulsion, relying instead on the natural stability of the sun-synchronous path, which eliminates the need for thrusters or chemical propellants. The spacecraft employs three-axis stabilization for precise pointing and scanning, utilizing gyroscopes, reaction wheels, magnetic torque rods, and a dual-headed star tracker system for attitude determination and control.^[36] Operations follow a step-and-stare scanning mode, where the observatory performs large slews between target groups and small slews within groups to acquire exposures along ecliptic latitude rings, ensuring overlapping coverage for complete spectral mapping.^[36] Pointing accuracy achieves sub-arcsecond precision, with root-mean-square error less than 1 arcsecond, refined through fine astrometry using the Gaia DR3 star catalog.^[36] The telescope points at least 91 degrees away from both Earth and the Sun during observations, protected by photon shields to minimize thermal interference.^[35] Power is provided by a single deployable solar panel measuring 8.75 feet by 3.4 feet, generating approximately 750 watts, supplemented by a battery for eclipse periods.^[35] Thermal management relies on passive cooling systems, including multi-layer insulation, v-groove radiators, and photon shields, which maintain the detectors and optics at around -350°F (-210°C) without active cryocoolers or consumable coolants.^[35] Data is downlinked via three S-band and two Ka-band antennas, with approximately five ground station passes per day, to the Jet Propulsion Laboratory's operations center for processing and archiving at Caltech's IPAC.^[35] The 25-month primary survey phase, following a one-month checkout, divides operations into four complete all-sky mappings, each covering the full celestial sphere in near-infrared spectra across 102 bands.^[35] The spacecraft acquires roughly 600 exposures daily, accumulating data on over 450 million galaxies and 100 million stars, with enhanced redundancy in deep fields near the north and south ecliptic poles for higher sensitivity.^[35] This cadence ensures the entire sky is resurveyed approximately every six months, enabling time-domain studies of variability.^[35]

Development and history

Proposal and selection

The SPHEREx mission concept was initially proposed under NASA's Small Explorers (SMEX) program in December 2014, led by principal investigator James Bock of the California Institute of Technology (Caltech), but it was not selected for development. The team subsequently refined and resubmitted an enhanced version as a Medium-Class Explorers (MIDEX) proposal in early 2017, following NASA's call for Astrophysics Explorers missions issued in September 2016; this effort involved nine competing proposals focused on advancing key questions in cosmology, galaxy formation, and astrobiology.^[16]^[37] On August 10, 2017, NASA announced the selection of SPHEREx as one of two mission concepts for Phase A concept studies, chosen from the nine submissions based on preliminary assessments of scientific merit, technical feasibility, and alignment with program goals. This initial selection provided approximately $2 million in funding for a nine-month study to further define the mission design, instrumentation, and operations within the MIDEX cost guidelines. The choice highlighted SPHEREx's promise to deliver broad spectroscopic data across the entire sky, addressing gaps in existing surveys while staying under the program's cost constraints.^[38]^[39] After completing Phase A and undergoing rigorous peer review by NASA and external experts, SPHEREx was downselected as the sole MIDEX mission on February 13, 2019, from the two Phase A candidates. The final approval allocated $242 million for development (excluding launch costs), reflecting its balanced approach to achieving high-impact science returns—such as probing cosmic inflation and mapping water ices—while adhering to a total mission cost cap of around $425 million, a key factor in the competitive evaluation. This decision directly supported priorities outlined in the 2010 National Research Council Decadal Survey New Worlds, New Horizons in Astronomy and Astrophysics, which emphasized all-sky infrared surveys for insights into the universe's early evolution and the building blocks of habitable worlds.^[37]^[40] Early team formation positioned NASA's Jet Propulsion Laboratory (JPL) to lead project management and systems engineering, with Caltech overseeing science operations and payload development, enabling seamless integration from the proposal stage onward.^[37]

Construction and testing

Following selection in 2017, SPHEREx entered Phase A/B for mission concept and preliminary design studies from approximately 2018 to 2020, during which the overall architecture, including the telescope and spectrophotometers, was refined at NASA's Jet Propulsion Laboratory (JPL).^[41] Fabrication of key components, such as the telescope mirrors and detector arrays, began in 2020 and continued through 2023, led by industry partners under JPL oversight.^[42] A major milestone was the Critical Design Review (CDR) completed in February 2022, which approved the final engineering designs and transitioned the project to full fabrication and assembly. This followed separate CDRs for the spacecraft in June 2021 and the telescope in November 2021.^[43]^[44] Integration of the payload with the spacecraft bus occurred primarily from 2023 onward at facilities in Boulder, Colorado, culminating in comprehensive environmental testing in 2024. This testing included vibration and acoustic simulations to replicate launch stresses, as well as thermal vacuum (TVAC) trials in June and July 2024 to verify performance under space-like conditions of extreme cold and vacuum.^[45]^[46] Additional verification at JPL, including the Observatory Readiness Review in October 2024, confirmed compliance with mission requirements prior to shipment for launch preparations.^[47] Engineering teams addressed several technical hurdles during assembly, notably controlling the observatory's mass to approximately 502 kg (including margins) to meet launch vehicle constraints while incorporating sensitive cryogenic components.^[48] A key challenge was achieving passive cooling below 80 K through the V-groove system for optimal near-infrared sensitivity, requiring precise design and stray light management to preserve optical alignment during testing.^[11] Cryogenic performance was validated through pre- and post-vibration optical tests, ensuring the system could withstand launch dynamics without degradation.^[23] BAE Systems (incorporating former Ball Aerospace capabilities) served as the primary contractor for the telescope assembly, spectrophotometers, and spacecraft bus, handling fabrication, integration, and environmental testing at their Boulder facilities.^[31] JPL, as the mission manager, led overall systems engineering, software development, and final ground verifications to ensure seamless interface between the payload and bus.^[42]

Launch details

Following the completion of environmental testing and observatory assembly, the SPHEREx spacecraft was shipped from the Ball Aerospace facility in Boulder, Colorado, to Vandenberg Space Force Base in California, arriving on January 16, 2025, for final launch preparations.^[49] Preparations included integration with the SpaceX Falcon 9 payload adapter in February 2025, along with compatibility checks and fueling operations for the ride-share components.^[16] SPHEREx served as the primary payload on a dedicated Falcon 9 Block 5 rocket, co-launched with NASA's PUNCH mission consisting of four small suitcase-sized microsatellites designed to study the Sun's corona and heliosphere.^[50] The launch occurred from Space Launch Complex 4 East (SLC-4E) at Vandenberg Space Force Base on March 11, 2025, at 8:10 p.m. PDT (03:10 UTC on March 12), after several delays due to integration and weather issues.^[15] The ascent profile followed a southwestern trajectory to achieve a sun-synchronous polar orbit, with the Falcon 9's second stage performing a burn to reach an initial elliptical orbit of approximately 500 by 700 kilometers.^[16] SPHEREx was successfully deployed at around T+60 minutes, followed by the sequential release of the PUNCH satellites approximately 11 minutes later, with the spacecraft then using its onboard propulsion for circularization to a nominal 650-kilometer altitude.^[51] No anomalies were reported during the launch vehicle performance or payload separation.^[50] Ground support was managed from NASA's Jet Propulsion Laboratory (JPL) in Pasadena, California, where the mission operations team monitored telemetry in real-time via the Deep Space Network and coordinated with SpaceX launch control at Vandenberg.^[5]

Post-launch activities

Commissioning phase

Following its successful launch on March 11, 2025, aboard a SpaceX Falcon 9 rocket from Vandenberg Space Force Base, the SPHEREx spacecraft entered the commissioning phase, a critical period dedicated to verifying overall health and performance in orbit.^[15] This phase spanned March to April 2025, during which the spacecraft was raised from its initial low-Earth orbit insertion to a final near-polar, Sun-synchronous orbit at approximately 700 kilometers altitude to optimize observation conditions.^[52] Key activities included the activation and checkout of essential subsystems. The power system, comprising solar arrays and batteries, was fully deployed and tested to ensure stable energy supply under varying thermal conditions. Thermal control mechanisms were initialized to maintain spacecraft stability, while communication links with ground stations were established and validated for reliable data downlink.^[35] These steps confirmed nominal operation of the core bus systems, with no major disruptions reported. Instrument commissioning focused on the spectro-photometer, beginning with the cooldown of its detectors using a closed-cycle cryocooler to reach operating temperatures around -210°C. Initial calibrations were performed by observing bright reference stars to align the optical system and verify pointing accuracy. In early April 2025, SPHEREx achieved first light, capturing test images that successfully demonstrated functionality across its 102 near-infrared spectral bands, essential for the mission's all-sky survey.^[53]^[54] By the end of April, all systems were declared nominal, paving the way for the handover to science operations on May 1, 2025.^[55] This transition marked the completion of commissioning and the start of routine sky mapping.

Data collection and analysis

Following its commissioning, SPHEREx commenced routine science operations in May 2025, acquiring approximately 3,600 infrared images per day to conduct a comprehensive all-sky spectral survey over its two-year primary mission.^[56] These observations, covering wavelengths from 0.75 to 5 microns, are expected to generate a total data archive on the petabyte scale, enabling detailed studies of galaxies, stars, and interstellar ices.^[23] High-rate science data is downlinked daily via the spacecraft's Ka-band system at rates up to 600 Mbps, transmitting around 20 GB per day to ground stations in NASA's Near-Earth Network.^[23]^[57] The raw data undergoes ground-based processing at the SPHEREx Science Data Center (SSDC) at the Infrared Processing and Analysis Center (IPAC) at Caltech, where a tiered pipeline handles reduction from Level 1 to Level 3 products.^[36] This includes initial flat-fielding to correct for detector pixel variations using zodiacal light templates and calibration sources, wavelength calibration derived from onboard lamps and stellar spectra, and spectral extraction via forced photometry on compact sources to produce resolved spectra at R=40 resolution.^[58]^[23] The pipeline also incorporates ancillary data from missions like Gaia for astrometric alignment, ensuring high-fidelity products for scientific analysis by the SPHEREx team across 10 U.S. institutions and two international partners.^[59] Early science results from the first few months of operations have already yielded significant insights. Initial data releases in summer 2025 provide early near-infrared spectral observations of portions of the sky, highlighting diffuse emission and point sources.^[14] In August 2025, SPHEREx observations of the interstellar comet 3I/ATLAS detected strong water ice absorption features, confirming H₂O-dominated ices in its nucleus.^[60] Legacy data products, including spectral images, catalogs, and maps, are made publicly available through the NASA/IPAC Infrared Science Archive (IRSA), with quick-release data appearing within 60 days of observation and weekly updates to facilitate broad community access. As of November 2025, Quick Release 2 data from October 2025 is available, featuring improved calibrations.^[36] Interactive tools at IRSA, such as visualization interfaces and spectral query capabilities, allow researchers to explore the dataset alongside complementary archives from missions like WISE and JWST.^[61]^[62] This open-access approach, aligned with NASA's open science policy, has enabled rapid follow-up studies and global collaboration on SPHEREx's empirical outputs.^[63]

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The SPHEREx Target List of Ice Sources (SPLICES) - IOPscience
Jun 2, 2023 · This work describes version 7.1 of the SPHEREx target List of ICE Sources (SPLICES) for the community. It contains 8.6 × 10 6 objects brighter than W2 ∼ 12 ...
[27]
[PDF] SPHEREx: NASA's Near-Infrared Spectroscopic All-Sky Survey
Jun 9, 2023 · Galaxies ∆z/(1+z) < 10 % > 450 million. Galaxies ∆z/(1+z) < 0.3% > 10 million. Exquisite measurements of galaxy redshifts! We simulated this ...
[28]
SPHEREx: Instrument design and implementation - NASA ADS
The 20 cm telescope is based on a wide-field off-axis three-mirror astigmat. With an instantaneous field of view of 3.5x7.0 degrees imaged by four H2RG ...
[29]
Instrument | SPHEREx
### Telescope Design Summary
[30]
Quick Facts | NASA Jet Propulsion Laboratory (JPL)
Total weight/mass: 1,107 pounds (502 kilograms). A large satellite with a ... The SPHEREx telescope has three mirrors, with an effective diameter of 7.9 ...
[31]
Meet the Spacecraft: SPHEREx - NASA Science
Mar 11, 2025 · The design of SPHEREx also contains several features proven effective on previous missions, including its 7.9-inch (20-centimeter) aluminum ...
[32]
NASA's SPHEREx Observatory launches with BAE Systems-built ...
Mar 12, 2025 · BAE Systems built the spacecraft bus and telescope for the mission, along with leading observatory integration and environmental testing.
[33]
[PDF] SPHEREx - Cloudfront.net
The SPHEREx telescope has three mirrors, an effective diameter of 7.9 inches (20 centimeters), and a field of view that is 11 by 3.5 degrees. The telescope ...Missing: square | Show results with:square
[34]
Spacecraft | NASA Jet Propulsion Laboratory (JPL)
SPHEREx has only six filters, but they detect 102 wavelengths of infrared light in total. Each filter has 17 color bands, distinct regions that look like ...
[35]
[2511.02985] The SPHEREx Satellite Mission - arXiv
Nov 4, 2025 · We describe the design of the instrument and spacecraft, which flow from the core science requirements. Finally, we present an initial ...
[36]
[PDF] Press Kit / February 2025 - Cloudfront.net
Feb 6, 2025 · SPHEREx is managed by NASA's Jet Propulsion Laboratory in Southern California for. NASA's Astrophysics Division within the Science Mission ...
[37]
[PDF] SPHEREx Explanatory Supplement
Jul 2, 2025 · Table 1: Orbital parameters of the SPHEREx spacecraft. Property. Value. Mean semi-major axis. 7,037.41 km. Eccentricity. 0.00034. Inclination.
[38]
NASA Selects New Mission to Explore Origins of Universe
Feb 13, 2019 · Nine proposals were submitted, and two mission concepts were selected for further study in August 2017. After a detailed review by a panel of ...
[39]
NASA Selects Proposals to Study Galaxies, Stars, Planets
Aug 10, 2017 · SPHEREx would perform an all-sky near-infrared spectral survey to probe the origin of the universe, explore the origin and evolution of galaxies ...
[40]
NASA Chooses SPHEREx for Phase A Study
NASA Chooses SPHEREx for Phase A Study. News Release • August 9th, 2017 ... NASA will make the final selection "by 2019." More details will be provided ...Missing: MIDEX proposal submission date
[41]
2,700 Pages Later, a Space Mission Is Born - www.caltech.edu
Apr 23, 2019 · SPHEREx was first proposed under the SMEX classification but did not get selected, so Bock and his team re-proposed the mission as a MIDEX and ...Missing: 2018 | Show results with:2018
[42]
SPHEREx: NASA's Near-Infrared Spectrophotometric All-Sky Survey
Each of the four surveys will contain Deep Fields - ∼ 100 sq degree regions near the ecliptic poles, visible on each orbit.
[43]
Construction on NASA Mission to Map 450 Million Galaxies Is Under ...
Nov 9, 2023 · Ball Aerospace built the telescope and will supply the spacecraft bus. The science analysis of the SPHEREx data will be conducted by a team ...Missing: contractor | Show results with:contractor
[44]
[PDF] NASA Astrophysics Update - National Science Foundation
Jun 6, 2022 · • SPHEREx, the next Astrophysics Medium Explorer mission, passed its critical design review (CDR) in December 2021. • In October 2021, NASA ...
[45]
BAE Systems completes environmental testing and helps advance ...
Dec 2, 2024 · The SPHEREx mission will provide scientists with new insights into the formation of the universe and the galaxies that inhabit it.
[46]
SPHEREx Prepared for Thermal Vacuum Testing
Jan 23, 2025 · NASA's SPHEREx observatory is installed in the Titan Thermal Vacuum (TVAC) test Chamber at BAE Systems in Boulder, Colorado, in June 2024.Missing: vibration | Show results with:vibration
[47]
[PDF] NASA Astrophysics Update
Jul 23, 2024 · • Observatory Thermal Vacuum (TVAC) testing completed at BAE in early July. Upcoming Milestones. • Oct. 2024: SPHEREx ORR at JPL. • Mission ...<|control11|><|separator|>
[48]
[PDF] SPHEREx: An All-‐Sky Spectral Survey - UCI Physics and Astronomy
Telescope Effective Aperture. 20 cm. Pixel Size. 6.2" x 6.2". Field of View. 2 x (3.5° x 7.0°); dichroic. Spectrometer. Linear-‐Variable Filters. Resolving ...
[49]
NASA's SPHEREx Telescope Arrives for Final Launch Preparations
Jan 16, 2025 · SPHEREx will launch aboard a SpaceX Falcon 9 rocket in late February 2025. Photo credit: USSF 30th Space Wing/Tony Vauclin. NASA's SPHEREx ...
[50]
NASA's SPHEREx Space Telescope Ready to Launch
Mar 7, 2025 · Both spacecraft will be in a Sun-synchronous low Earth orbit, where their position relative to the Sun remains the same throughout the year. ...Missing: type | Show results with:type
[51]
Falcon 9 • SPHEREx and PUNCH - Spaceflight Now
Both missions launched to a polar orbit and were deployed about 11 minutes apart. A little less than eight minutes after liftoff, the Falcon 9 first stage ...
[52]
SPHEREx launches to conduct a cosmic census
Mar 12, 2025 · The mission will help us uncover how early galaxies formed and where the building blocks of life are located in the Milky Way.Missing: total | Show results with:total
[53]
SPHEREx is Now Mapping the Entire Sky - Universe Today
May 6, 2025 · In a 90 minute sun-synchronous orbit,SPHEREx is able to scan the entire sky, one 4.5 degree wide swath at a time. This unique orbit also allows ...
[54]
NASA's SPHEREx Space Telescope Ready to Launch - Caltech
Mar 7, 2025 · The launch window opens at 7:09:56 p.m. PST on Saturday, March 8, with a target launch time of 7:10:12 p.m. PST. Additional opportunities occur ...Missing: arrival | Show results with:arrival
[55]
SPHEREx starts science observations while PUNCH commissioning ...
May 8, 2025 · Through the 25 months of its planned mission, SPHEREx is set to take 600 exposures every day, for a total of 3,600 images across all detectors. ...
[56]
NASA's SPHEREx Space Telescope Begins Capturing Entire Sky
May 1, 2025 · On May 1, the spacecraft began regular science operations, which consist of taking about 3,600 images per day for the next two years to provide ...Missing: volume | Show results with:volume
[57]
Designing the Ka-Band System Architecture for Science Data Return ...
In this paper, we will discuss the end-to-end architecture of the SPHEREx science data downlink path and summarize the unique challenges and design trades.
[58]
[PDF] SPHEREx Explanatory Supplement
Oct 13, 2025 · wavelength. Combining these 1D calibration factors with the measured flat field response yields the absolute gain matrices used to convert ...
[59]
SPHEREx science data processing and archive products - ADS
The SPHEREx Science Data Center (SSDC) at IPAC will operate a data processing pipeline for SPHEREx and produce several data products.
[60]
[PDF] SPHEREx Discovery of Strong Water Ice Absorption and an ...
The photometric measurements reported here are from the first ½ of all the August 2025 SPHEREx 3I pointings. Treatment of stellar contamination will greatly.Missing: galaxy | Show results with:galaxy
[61]
SPHEREx Mission: Mapping the Universe in Unprecedented Detail
Sep 8, 2025 · The observatory will generate spectra for approximately 400 million galaxies, providing an unprecedented window into cosmic history at a cost ...
[62]
How NASA's SPHEREx Mission Will Share Its All-Sky Map With the ...
Jul 2, 2025 · NASA's SPHEREx mission will map the entire sky in 102 different wavelengths, or colors, of infrared light.
[63]
IRSA - SPHEREx - NASA/IPAC Infrared Science Archive - Caltech
Access SPHEREx data available on AWS S3 cloud storage. SPHEREx Science Tools ... IRSA Documentation - SPHEREx Releases. Documentation, SPHEREx Explanatory ...
[64]
SPHEREx Archive at IRSA User Guide
Oct 31, 2025 · This document is to facilitate science with SPHEREx data by providing users with an overview of the SPHEREx data that are available at the NASA/IPAC Infrared ...
[65]
NASA shares SPHEREx sky survey data weekly to enable global ...
Jul 7, 2025 · NASA's SPHEREx space telescope, launched in March, has begun publicly releasing data from its infrared sky survey, offering scientists worldwide weekly access.