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Intergalactic dust

Intergalactic dust consists of microscopic solid particles dispersed within the intergalactic medium (IGM), the low-density plasma that fills the voids between galaxies across the universe.^[1] These grains, typically ranging in size from about 10 Å to 1 μm, are primarily composed of carbonaceous materials such as graphite and silicates, similar to those found in interstellar dust, and are thought to originate from metals produced in stars and ejected into intergalactic space via galactic winds and supernova explosions.^[1] Their presence is inferred from observations of extinction and reddening in the light of distant quasars and Type Ia supernovae, where the dust selectively absorbs shorter (bluer) wavelengths, causing a measurable dimming and color shift that extends well beyond the edges of host galaxies.^[2] The density of intergalactic dust is extremely low, increasing from approximately 10^{-34} g cm^{-3} at redshift z ≈ 0 (present day) to about 10^{-33} g cm^{-3} at z ≈ 1, reflecting the evolving metal enrichment of the IGM over cosmic time.^[1] Constraints on its abundance come from the limited observed extinction (≤ 0.1 mag) and reddening (≤ 0.03 mag) toward distant supernovae at z ≈ 0.5, as well as consistency with the thermal history of the IGM, placing an upper limit on the dust-to-metal mass ratio of roughly 0.1 for typical grain sizes.^[1] Despite its sparsity, intergalactic dust plays a significant role in the thermodynamics of the IGM by facilitating photoelectric heating—where UV photons eject electrons from grains, warming the surrounding gas—and radiative cooling processes that influence structure formation in the early universe.^[3] Detection of intergalactic dust has been bolstered by large-scale surveys like the Sloan Digital Sky Survey (SDSS), which analyzed the colors of over 100,000 quasars aligned behind millions of foreground galaxies, revealing dust correlations that extend to scales of several megaparsecs and imply a diffuse dusty component in the cosmic web.^[2] This dust can complicate cosmological measurements, such as those of dark energy via supernova distances, by introducing systematic biases in luminosity and color interpretations, though its effects are generally small compared to Galactic foregrounds.^[2] Ongoing observations with facilities like the James Webb Space Telescope may further refine our understanding by probing infrared emissions from heated grains in the distant universe.

Definition and Properties

Definition

Intergalactic dust consists of microscopic solid particles, typically ranging in size from 0.001 to 1 micrometer, that are dispersed throughout the intergalactic space between galaxies.^[1] These grains form a minor component of the intergalactic medium (IGM), the diffuse plasma filling the vast regions of the universe outside galactic structures, and constitute less than 1% of the IGM's total mass.^[4] Unlike more prominent forms of cosmic dust, intergalactic dust is characterized by its extreme sparsity, reflecting the overall low baryonic density of the IGM with gas number densities on the order of 10^{-6} cm^{-3} in typical cosmic voids, while dust grain number densities are much lower (~10^{-15} cm^{-3}).^[5] This dust is distinctly located in the expansive voids, filaments, and clusters of the cosmic web, far beyond the disks and halos of individual galaxies, where it resides in environments outside the influence of stellar or galactic processes.^[4] In contrast, interstellar dust occupies the denser interiors of galaxies, with typical densities around 1 atom per cubic centimeter; circumstellar dust surrounds individual stars in their immediate envelopes; and zodiacal dust is confined to the solar system, originating from cometary and asteroidal activity. The rarity of intergalactic dust arises from its dilution across immense volumes and susceptibility to destruction in the hot, ionized IGM, resulting in dust-to-gas mass ratios that are orders of magnitude lower than those in galactic environments.^[6]

Physical Properties

Intergalactic dust grains typically range in size from 0.001 to 1 μm, following a power-law distribution akin to that of interstellar dust, though dilution in the intergalactic medium may result in a more uniform profile due to reduced grain-grain interactions.^[7]^[8] This distribution, often modeled as N(a) \propto a^{-3.5} da where a is the grain radius, arises from processes like supernova ejecta and subsequent growth, with small grains dominating the population in simulations of cosmic dust evolution.^[7] The temperature of intergalactic dust grains generally falls between 10 and 50 K, primarily maintained by heating from the cosmic microwave background (CMB) and faint starlight from distant galaxies.^[7] In equilibrium, typical values hover around 20 K in low-density regions, with small grains experiencing stochastic fluctuations up to ~1000 K due to intermittent photon absorption, leading to thermal re-emission predominantly in the far-infrared.^[7] This temperature regime contrasts with hotter interstellar environments, reflecting the sparse radiation field in intergalactic space. Dust density in the intergalactic medium remains extremely low, with volume densities on the order of $10^{-34} g cm⁻³ at low redshift (z ≈ 0), increasing to ~$10^{-33} g cm⁻³ at z ≈ 1, though it clumps into clouds reaching masses up to $10^5 solar masses, particularly along cosmic web structures such as filaments.^[1]^[9] These clumps correlate with electronic density variations, yielding n_e \approx 10^{-6} to $10^{-3} cm⁻³ in the broader IGM and intracluster medium, respectively.^[7]^[8] Optically, intergalactic dust exhibits high extinction efficiency in the ultraviolet and optical wavelengths, with total visual extinction limited to A_V ≤ 0.1 mag toward distant supernovae at z ≈ 0.5, primarily causing reddening of background light.^[1] This efficiency, governed by absorption cross-sections Q_{\rm abs}(\nu, a), is enhanced for grains around 0.1–1 μm, producing a relatively flat or grey extinction curve that minimally affects color gradients over cosmic distances.^[7]

Composition

Intergalactic dust grains are primarily composed of amorphous silicate minerals, such as olivine (Mg₂SiO₄) and pyroxene (MgSiO₃), which constitute approximately 40–50% of the total dust mass based on models extrapolated from interstellar dust populations.^[10] Carbonaceous materials, including amorphous carbon and graphite, account for 20–30% of the mass, while polycyclic aromatic hydrocarbons (PAHs) contribute around 10%, serving as carriers of infrared emission features observed in extragalactic contexts.^[11] These components reflect the refractory nature of the grains, dominated by elements like silicon, magnesium, iron, and carbon, which are produced through stellar nucleosynthesis and ejected into the intergalactic medium (IGM).^[12] The overall elemental abundances in intergalactic dust are enriched in these refractory species relative to the gas phase, with the metallicity of the IGM in the local universe (z < 1) scaling to approximately 0.01–0.1 times solar values, as inferred from absorption-line studies of quasars and galaxy outskirts.^[13] The composition of intergalactic dust evolves over cosmic time due to interactions with the hot IGM plasma, where non-thermal sputtering dominates grain erosion for velocities exceeding 100 km s⁻¹, preferentially destroying smaller particles and leading to a population dominated by submicron-sized grains.^[12] This process reduces the total dust mass while altering the relative fractions of silicates and carbonaceous components, as carbon-rich grains may be more resilient than silicates under certain conditions.^[12] Recent James Webb Space Telescope observations, as of 2025, have detected dust particles surviving ejection into intergalactic space from early galaxies, supporting models of refractory grain persistence in the IGM.^[14]

Formation and Sources

Stellar Origins

Stellar origins represent the primary mechanism for the initial production of dust grains that serve as seed material for intergalactic dust, originating from the outflows and explosive ejecta of evolved stars and their remnants. These processes occur within galaxies, where dust forms through condensation in cooling envelopes or expanding supernova remnants, primarily composed of silicates, carbon, and other refractory elements. In mature galaxies like the Milky Way or the Large Magellanic Cloud (LMC), asymptotic giant branch (AGB) stars dominate dust production, contributing approximately 70% of the total stardust input through their mass-loss episodes.^[15] AGB stars, typically of initial masses 1–8 M_\odot, undergo thermal pulses in their late evolutionary stages, driving strong outflows from cool, extended envelopes where dust grains nucleate efficiently. These outflows produce carbonaceous dust in carbon-rich AGB stars and silicate grains (such as forsterite and enstatite) in oxygen-rich ones, with typical dust yields ranging from 0.001 to 0.01 M_\odot per star, depending on initial mass and metallicity. For instance, at metallicities around Z = 0.008, more massive AGB stars (∼4–7 M_\odot) yield up to ∼0.01 M_\odot of dust, while lower-mass counterparts produce about an order of magnitude less. This production is metallicity-sensitive, with lower yields at subsolar metallicities (Z ≤ 0.001) due to reduced availability of seed nuclei for grain growth.^[16]^[15] Core-collapse supernovae (Type II), arising from massive stars (≥8 M_\odot), provide another major source of dust through rapid condensation in their expanding ejecta, forming grains as the gas cools post-explosion. These events can produce 0.1–1 M_\odot of dust per supernova, including amorphous silicates (e.g., Mg_2SiO_4 and SiO_2), carbon (such as amorphous carbon or fullerenes), and metallic oxides or sulfides like FeS. Observations of remnants like Cassiopeia A and SN 1987A confirm dust masses in this range after several years, with formation beginning around 200–500 days post-explosion in clumpy ejecta regions. This high yield makes core-collapse supernovae efficient dust factories, particularly in star-forming environments.^[17]^[18] Type Ia supernovae, resulting from thermonuclear explosions of white dwarfs in binary systems, were previously considered minor contributors to dust production, with theoretical models yielding approximately 0.001 M_\odot per event, primarily in the form of carbon grains and minor silicates. Theoretical models, such as the W7 carbon-deflagration scenario, predict low dust masses (∼3 × 10^{-4}–0.02 M_\odot) due to the hot, low-density ejecta, which limits grain growth despite available carbon and silicon. However, recent observations of interacting Type Ia-CSM events like SN 2018evt reveal newly formed dust masses up to ∼0.01 M_\odot in the cold, dense shell behind the ejecta–circumstellar medium interaction, suggesting a potentially significant role in the cosmic dust budget, particularly in environments with low star formation. Recent observations suggest additional dust formation in interacting shells with circumstellar material, but overall, Type Ia events add less to the stellar dust budget compared to AGB stars and core-collapse supernovae.^[19]^[20] In the early universe (z > 6, <200 Myr after the Big Bang), dust production was dominated by core-collapse supernovae, as the lack of time for lower-mass stars to evolve into AGB phases delayed their contributions. Recent models confirm supernova yields of 0.03–2 M_\odot per event (with 10–30% survival post-reverse shock), enabling enrichment of proto-galaxies with 10^6–10^8 M_\odot of dust within the first 100–200 Myr, providing the initial seeds observed in high-redshift quasars before AGB stars became significant; grain growth in the metal-enriched IGM may further contribute. This supernova-driven enrichment is crucial for understanding the rapid buildup of intergalactic dust in the nascent cosmic web.^[21]^[22]

Galactic Expulsion Mechanisms

Galactic winds represent a primary mechanism for expelling dust from galaxies into intergalactic space, driven primarily by the energetic feedback from starburst supernovae and active galactic nuclei (AGN). In star-forming galaxies, these outflows are powered by multiple supernovae explosions that heat and accelerate interstellar gas, entraining dust grains along with it. Observed velocities in such winds often exceed 1000 km/s, enabling material to escape galactic gravitational potentials and reach intergalactic distances.^[23] Mass outflow rates can reach 10–100 M_{\odot} yr^{-1} in vigorously star-forming systems, with dust comprising a fraction comparable to the interstellar medium's dust-to-gas ratio of approximately 1/100–1/200.^[24] AGN-driven winds, fueled by radiation pressure on dust and accretion disk outflows, similarly contribute, particularly in quasars and Seyfert galaxies, where they can sustain high ejection efficiencies over extended periods. Ram-pressure stripping provides another key pathway for dust expulsion, particularly in dense environments like galaxy clusters. As galaxies infall or orbit within clusters, their interstellar medium encounters the hot, tenuous intracluster medium (ICM) at relative velocities of hundreds to thousands of km/s, resulting in hydrodynamic drag that strips outer disk material. This process preferentially removes dust-rich gas from the outskirts of infalling spirals and irregulars, with the efficiency increasing for galaxies on highly radial orbits or during cluster mergers. In such scenarios, dust grains are ablated and dispersed into the ICM, contributing to the observed diffuse dust population in cluster outskirts, though the exact stripping threshold depends on galaxy mass and ICM density. Tidal interactions during galaxy mergers disrupt stellar and gaseous disks, flinging dust-laden material into extended bridges and tails that extend into intergalactic space. In close encounters, differential gravitational forces strip loosely bound interstellar matter, including dust, from the interacting galaxies, often forming structures tens of kiloparsecs long. A prominent example is the Antennae Galaxies (NGC 4038/4039), where merger-induced tidal tails exhibit significant dust emission, as traced by mid-infrared observations, indicating ejection of interstellar dust into the intergalactic medium. These tails can persist for hundreds of millions of years, gradually dispersing their dust content through dynamical mixing. The survival of ejected dust in the intergalactic medium is limited by thermal sputtering and heating in the hot, low-density environment, with rates varying by grain size. Small grains (<0.01 μm) are rapidly destroyed upon exposure to temperatures exceeding 10^6 K, while larger grains (0.1 μm) exhibit higher resilience, with survival fractions of approximately 50–60% in multiphase outflows.^[25] Overall, 10–50% of the initial ejected dust mass may endure long-term exposure to intergalactic conditions, depending on the grain size distribution and shielding by entrained cool gas clouds during transit.^[25] This selective destruction favors silicate and carbonaceous grains of intermediate sizes, altering the composition of surviving intergalactic dust.

Alternative Formation Processes

In addition to dust transported from galaxies, alternative formation processes for intergalactic dust are thought to occur directly in the intergalactic medium (IGM), though these mechanisms are minor and largely theoretical due to the diffuse and hot nature of the IGM, which limits efficiency compared to stellar sources. These processes include grain growth via accretion, shock-induced formation in dynamically active regions, and the primordial dust hypothesis from the early universe. However, destruction processes, such as sputtering by cosmic rays and hot plasma, impose short lifetimes on any formed dust, balancing potential accumulation. Grain growth in the IGM primarily occurs through the accretion of gas-phase metals onto pre-existing seed grains in the denser regions of the cosmic web, such as filaments, where local gas densities are higher than the average IGM value of ~10^{-4} cm^{-3}. This process is analogous to interstellar grain growth but proceeds more slowly due to lower metallicities and temperatures in the IGM, with models indicating that grain sizes could double over timescales of several Gyr in these environments, contributing modestly to the overall dust budget.^[26] Shock-induced formation represents another potential mechanism, where dust grains condense in collisionally heated IGM regions, such as those generated during galaxy cluster mergers. These shocks, with velocities of ~1000-3000 km s^{-1}, can drive gas cooling and grain nucleation similar to supernova shocks in galactic environments, but at lower efficiencies due to the lower densities and metallicities, yielding approximately 0.01 M_⊙ of dust per event. Such processes are expected to be rare and localized, primarily in massive cluster environments.^[27] The primordial dust hypothesis posits that dust formed in the early universe from the ejecta of the first stars (Population III) via core-collapse supernovae, distributed uniformly into the IGM via supernova-driven winds at redshifts z ~10-30. This dust, primarily carbonaceous or silicate grains with masses around 0.3 M_⊙ per supernova assuming ~10% condensation efficiency, could imprint on the cosmic microwave background through Compton scattering (y-parameter ~10^{-5}) and provide opacity to high-z infrared sources (τ_dust ~0.1-1). However, observational evidence is limited, with upper limits on dust mass in the high-z IGM at <10^{-5} M_⊙ per typical volume, constrained by the lack of strong extinction in quasar spectra and CMB distortions.^[28]^[22] Destruction processes significantly limit the accumulation of intergalactic dust from these alternative mechanisms. Sputtering by cosmic rays and thermal interactions with hot plasma (T ~10^6 K) erode grain surfaces, with lifetimes estimated at 10^8-10^9 years for refractory grains, depending on grain size and composition; ice mantles are destroyed more rapidly (~2 × 10^8 years). These timescales are comparable to or longer than in galactic ISM due to lower collision rates in the IGM, but still prevent substantial buildup over cosmic history.^[29]

Detection and Observation

Historical Evidence

Early theoretical proposals for the existence of intergalactic dust emerged in the 1930s, with contributions from Dufay (1933) and Zwicky (1937), based on anomalies in galaxy counts and unexpected reddening patterns in distant galaxies, predating any confirmed detections.^[30] During the 1960s, intergalactic dust clouds were identified through optical extinction effects, often linked to anomalies in the Zwicky catalog of galaxies and clusters. The first such cloud was noted in 1961, with subsequent discoveries including those reported by Hoffmeister in 1962 and Okroy in 1965, marking initial evidence for localized dust structures beyond galactic confines.^[30] Advancements in the 1980s confirmed the presence of at least four intergalactic dust clouds within approximately 5 Mpc of the Milky Way, leveraging improved photometric data to distinguish them from foreground interstellar material. A prominent example is the Okroy Cloud, discovered in 1965 but further characterized in this era with an estimated visual extinction of A<sub>V</sub> ≈ 0.5 mag, indicating moderate obscuration capable of affecting background galaxy observations.^[30] In the late 20th century, infrared surveys such as the Infrared Astronomical Satellite (IRAS) provided the first direct evidence of dust emission from these structures, with preliminary detections of far-infrared flux from the Okroy Cloud region confirming thermal re-emission and solidifying the reality of intergalactic dust populations.^[30]

Observational Techniques

Extinction mapping provides a primary means to detect intergalactic dust by quantifying the dimming and reddening of light from distant background sources, such as quasars and galaxies, across UV and optical wavelengths. This technique measures the wavelength-dependent attenuation caused by dust absorption and scattering along sightlines, allowing inferences about dust distribution in the intergalactic medium (IGM). Observations with the Hubble Space Telescope (HST) have been instrumental in resolving UV/optical absorption features in high-redshift quasar spectra, enabling mapping of extinction in diffuse intergalactic structures. For instance, statistical analyses of quasar colors reveal upper limits on intergalactic dust abundance, with typical visual extinctions estimated at less than 0.1 mag toward z ≈ 3, consistent with low dust levels in the IGM.^[31]^[32] Infrared emission observations target the thermal re-radiation from intergalactic dust grains heated by ambient radiation fields, primarily in the far-IR and submillimeter regimes where the emission peaks. Telescopes like Spitzer, Herschel, and the Atacama Large Millimeter/submillimeter Array (ALMA) excel at detecting this faint glow, often through stacking techniques to overcome low surface brightness. Statistical detections of excess far-IR emission toward galaxy clusters, for example, indicate diffuse dust components in the intracluster medium, with luminosities suggesting dust masses on the order of 10^7–10^9 solar masses per cluster. Herschel's high sensitivity has resolved extended emission halos around galaxies, attributing part to expelled intergalactic dust.^[33] Absorption spectroscopy in the ultraviolet directly probes intergalactic dust through characteristic features imprinted on spectra of high-redshift background sources, particularly quasars. The prominent 2175 Å extinction bump, attributed to carbonaceous grains like graphite or polycyclic aromatic hydrocarbons, serves as a diagnostic for dust composition in the IGM. High-z sightlines (z > 1) reveal this bump in intervening Mg II absorbers, with detections in quasar spectra indicating metal-enriched, dusty gas in the intergalactic web; for example, over 40 such systems have been identified at z ≈ 1–2, showing bump strengths comparable to 20–50% of the Milky Way value. These observations, often from ground-based surveys like SDSS supplemented by HST UV spectroscopy, link dust to heavy element enrichment in the IGM. Polarimetry exploits the alignment of elongated dust grains with intergalactic magnetic fields to detect linearly polarized light from background sources, revealing grain orientation and field morphology. This method measures polarization in optical/UV or far-IR emission/absorption, where aligned grains preferentially transmit or emit polarized radiation perpendicular to the field direction. While direct detections remain challenging due to low dust densities, polarimetric studies of quasar light suggest weak signals from IGM-aligned grains, consistent with turbulent magnetic fields on megaparsec scales.^[34]

Known Intergalactic Dust Features

One of the earliest confirmed examples of intergalactic dust is the Okroy Cloud, located approximately 1 Mpc from the Milky Way. This cloud was detected through far-infrared emission at 100 μm using data from the Infrared Astronomical Satellite (IRAS), revealing an enhancement consistent with thermal dust radiation.^[35] The cloud exhibits an estimated mass of about 10^4 solar masses and causes a visual extinction of A_V ≈ 0.5 mag, indicating a compact structure capable of obscuring background light.^[35] In the Virgo Cluster, diffuse intergalactic dust is present in the intracluster medium, manifesting as filamentary clouds with a total estimated mass of approximately 2.5 × 10^9 solar masses (as of 2020). These features have been observed via X-ray absorption using the Chandra X-ray Observatory, particularly near the galaxy M86, where an absorption feature with a column density of 2–3 × 10^{21} cm^{-2} suggests dust grains attenuating soft X-rays from the hot intracluster gas. This detection highlights the clumpy nature of dust in cluster environments, distributed over scales of tens of kiloparsecs.^[36] At high redshifts (z > 2), intergalactic dust has been identified in Lyman-alpha absorbers, which trace gas in cosmic filaments. Recent James Webb Space Telescope (JWST) spectra of galaxies at z ≈ 8–11 reveal strong damped Lyman-alpha absorption lines associated with dusty environments, implying clumped dust distributions within these absorbers that obscure ultraviolet light and contribute to metal enrichment in the intergalactic medium.^[37] As of 2025, JWST continues to reveal dusty damped Lyman-α systems at z > 10, enhancing evidence for rapid dust formation in the early universe. These observations indicate that dust persists in filamentary structures even in the early universe, with detections pointing to ongoing star formation and dust production in protogalactic halos. Within the Local Group, the Magellanic Stream provides a prominent example of intergalactic dust stripped from satellite galaxies, such as the Large and Small Magellanic Clouds. This elongated structure exhibits infrared signatures detected by the Planck satellite, showing thermal emission from cold dust grains aligned with the neutral hydrogen distribution, confirming a dust-to-gas ratio lower than in galactic disks due to tidal stripping processes. The dust in the Stream, observed across far-infrared wavelengths, underscores the role of dynamical interactions in dispersing intergalactic material.

Role and Implications

Impact on Electromagnetic Radiation

Intergalactic dust exerts a profound influence on the propagation of electromagnetic radiation through absorption and scattering processes, primarily affecting ultraviolet and optical light from distant sources. This extinction preferentially removes shorter wavelengths, resulting in reddening of high-redshift objects such as Type Ia supernovae, where the color excess can reach E(B-V) ≈ 0.01–0.05 mag along typical sightlines to z ≈ 1. The absorbed energy is re-emitted as thermal infrared radiation by heated dust grains, contributing to the diffuse cosmic infrared background observed at wavelengths beyond 10 μm. Simulations of dust distribution in the intergalactic medium indicate that roughly half of this reddening originates from dust located more than 100 h⁻¹ kpc from the nearest massive galaxies, highlighting the diffuse nature of the effect.^[38] The cumulative impact of intergalactic dust manifests as a small but non-negligible dimming of distant sources, with upper limits on dimming from grey dust constrained to Δm ≤ 0.2 mag (corresponding to ≈17–20% flux reduction), while for standard colored dust the limit is Δm ≤ 0.03 mag, based on analyses of quasar colors that rule out significant "grey" dust contributions. The integrated optical depth τ through the universe from z = 0 to z = ∞ is estimated at ≈0.01–0.05 in the optical band, varying with the assumed dust-to-gas ratio (typically 0.2–0.4 times the Galactic value) and intergalactic metallicity evolution; higher values up to τ ≈ 0.03 at λ_obs = 2 μm are possible for elevated dust production at early epochs. This optical depth arises predominantly from small-scale structures in the cosmic web, with the total extinction scaling as the line-of-sight path length and dust density.^[39]^[40]^[38] Polarization effects emerge from the alignment of elongated dust grains with intergalactic magnetic fields, inducing linear polarization in transmitted light from background quasars. Proposed levels of 1–5% polarization fraction have been invoked to explain observed large-scale coherences in quasar optical polarization vectors spanning hundreds of megaparsecs, though Galactic foreground contamination complicates direct attribution to intergalactic dust.^[41]^[38] The wavelength dependence of extinction is pronounced, with stronger attenuation at λ < 1 μm following an approximate power-law A_λ ∝ λ^{-1.2} akin to Small Magellanic Cloud-type dust, while effects diminish at longer wavelengths and are negligible in the radio regime where grain sizes exceed the photon wavelength.^[38]

Interactions with Intergalactic Medium

Intergalactic dust grains couple dynamically with the intergalactic medium (IGM) primarily through collisions with hydrogen and helium atoms, which transfer kinetic energy from the hot gas to the grains. This thermal coupling enables the dust to radiate the absorbed energy as infrared emission, contributing to the cooling of the IGM, particularly in dense structures like the intracluster medium where dust IR emission can dominate the cooling process for gas temperatures exceeding 10^7 K.^[3] In lower-density regions, this dust-mediated cooling supplements gas-phase processes, with rates typically on the order of 10^{-3} times the intrinsic gas cooling under standard IGM conditions, though exact contributions vary with grain abundance and temperature.^[3] In the hot phases of the IGM, reaching temperatures around 10^6 K, dust grains undergo sputtering and destruction via impacts from energetic ions and atoms. Non-thermal sputtering erodes grain surfaces as they traverse the low-density plasma at high velocities (>100 km/s), leading to significant mass loss over cosmic timescales.^[42] Simulations indicate that grain sizes can reduce by 10–50% per gigayear in these environments, with larger grains (initially >0.1 μm) surviving longer travels of hundreds of kiloparsecs before substantial erosion, while smaller grains halt more quickly within tens of kiloparsecs.^[42] This destruction process not only limits dust longevity in the IGM but also releases constituent metals back into the gas phase. Dust grains also serve as catalytic surfaces for chemical reactions in the IGM, particularly in filamentary structures where they facilitate the formation of molecular hydrogen (H_2) through recombination of atomic hydrogen. At low metallicities typical of high-redshift IGM (~10^{-3} Z_\sun), even trace amounts of dust enhance H_2 production rates by providing sites for physisorption and reaction, which is crucial for shielding against ionization and enabling the cooling necessary for the formation of the first stars.^[43] Grain composition, such as carbonaceous or silicate materials, influences reactivity, with carbonaceous grains showing higher efficiency for H_2 formation, particularly at elevated temperatures.^[43] Through ejection from galaxies via outflows and subsequent sputtering, intergalactic dust acts as a vector for metal enrichment of the IGM, gradually increasing its overall metallicity over cosmic time. This feedback mechanism disperses heavy elements from stellar nucleosynthesis into the diffuse gas, raising the mean IGM metallicity from approximately 10^{-3} Z_\sun at redshift z ≈ 10 to about 10^{-2} Z_\sun in the present-day universe.^[44] The process is inhomogeneous, with enrichment peaking in overdense regions (overdensity δ = 10–100), where sputtering contributes up to observed levels of ~10^{-3} to 10^{-2} solar metallicity without requiring complete grain destruction.^[42]

Cosmological Significance

Intergalactic dust introduces systematic biases in cosmological distance measurements, particularly through extinction that can mimic the effects of dark energy acceleration in supernova observations. In type Ia supernova surveys, uncorrected intergalactic dust extinction along sightlines can alter apparent luminosities, leading to overestimations of cosmic expansion rates and errors in the Hubble constant of approximately 5–10% if ignored. These biases arise because dust absorption and scattering dim distant sources in a redshift-dependent manner, potentially skewing inferences about the dark energy equation of state parameter w by up to 0.3–0.5 in various extinction scenarios. Accurate modeling of this extinction is thus essential for refining the cosmic distance ladder and resolving tensions in Hubble constant determinations. In the early universe, intergalactic dust contributes to the overall opacity during the reionization era, influencing the propagation of ultraviolet radiation from the first galaxies. Theoretical models of the extragalactic background light predict a peak in dust density around redshifts z \approx 6–8, driven by rapid metal production and ejection from these early star-forming systems, which enhances scattering and absorption in the intergalactic medium. This dust budget, though sparse compared to galactic reservoirs, plays a role in modulating the ionizing photon escape fraction and the timing of reionization, with carbonaceous grains detected in spectra of high-redshift quasars providing evidence of early dust production in galaxies, which contributes to the intergalactic dust budget through ejection. Recent JWST observations have detected significant dust content in galaxies at z > 10, supporting theoretical models of early dust production and its role in IGM enrichment.^[45] The distribution of intergalactic dust serves as a tracer of metal ejection processes in galaxy formation, offering insights into feedback mechanisms that regulate cosmic structure growth. By following the transport of dust-bound metals from supernovae and stellar winds into the intergalactic medium, simulations reveal how these ejections shape the enrichment of the cosmic web and inform subgrid models of galactic outflows. In the IllustrisTNG suite of hydrodynamical simulations, intergalactic dust patterns align with metal feedback from active galactic nuclei and starbursts, highlighting its utility in calibrating models of galaxy evolution and the buildup of cosmic metals over time. Ongoing observations with the James Webb Space Telescope (JWST) and upcoming observations with the Extremely Large Telescope (ELT) promise to map intergalactic dust distributions across the cosmic web, enabling tests of \LambdaCDM predictions on large-scale structure and early universe enrichment. JWST's infrared capabilities will detect dust absorption features in high-redshift galaxy clusters and filaments, while ELT's high-resolution spectroscopy can resolve metal-line signatures in diffuse intergalactic gas, potentially constraining dust-driven feedback and reionization models. These efforts will clarify how dust influences the baryon cycle and validate simulation-based forecasts of cosmic evolution.

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[19]
Dust in Supernovae and Supernova Remnants I: Formation Scenarios
Mar 27, 2018 · This review summarises our current knowledge of dust formation in supernova ejecta and tries to quantify the role of supernovae as dust producers in a galaxy.<|separator|>
[20]
Dust grains from the heart of supernovae - Astronomy & Astrophysics
The measured mass of dust associated with the ejecta will therefore not be entirely released into the ISM, but will be partly destroyed. It has been possible to ...
[21]
FORMATION OF DUST IN THE EJECTA OF TYPE Ia SUPERNOVAE
We investigate the formation of dust grains in the ejecta of Type Ia supernovae (SNe Ia), adopting the carbon-deflagration W7 model. In the calculations of ...INTRODUCTION · CALCULATION OF DUST... · RESULTS OF DUST...
[22]
Genesis and evolution of dust in galaxies in the early Universe
SNe are primarily responsible for a significant enrichment with dust at early epochs (<200 Myr). Dust production with a dominant contribution by AGB stars is ...Missing: lack | Show results with:lack
[23]
High-velocity outflows persist up to 1 Gyr after a starburst in recently ...
We find evidence for high-velocity outflows in the star-forming progenitor population (v out ∼ 1400 ± 210 km s − 1 ⁠), for recently quenched galaxies with t ...
[24]
Galactic Winds - S. Veilleux et al.
Dust outflow rates of ~ 0.1 - 10 M odot yr-1 are inferred from the neutral-gas mass outflow rates discussed in Section 5.4, assuming the Galactic gas-to-dust ...Missing: M_sun/ | Show results with:M_sun/
[25]
[2403.03711] Dust Survival in Galactic Winds - arXiv
Mar 6, 2024 · Under most circumstances, grains smaller than 0.01 micron cannot withstand hot-phase exposure, suggesting that the small grains observed in the ...
[26]
The efficiency of grain growth in the diffuse interstellar medium
1 INTRODUCTION. The growth of dust grains by accretion of gas-phase metals is widely assumed to be an important process in the interstellar medium (ISM).Missing: intergalactic | Show results with:intergalactic<|control11|><|separator|>
[27]
Dust Formation in Astrophysical Environments: The Importance of ...
May 24, 2022 · Here, we will review the status of studies of dust formation in stellar ejecta as a guide for the latter. 2 Thermodynamics Versus Kinetics.
[28]
[PDF] arXiv:astro-ph/9704133v1 14 Apr 1997
We have quantified the imprint of intergalactic dust due to the first stars on the y–parameter of the CMB spectrum (in the COBE wavelength range), yc, and on ...
[29]
The destruction and growth of dust grains in interstellar space
Destruction rates are estimated for grains bombarded by MeV and GeV cosmic rays. It is shown that collision cascade sputtering dominates evaporative sputtering ...Missing: intergalactic | Show results with:intergalactic
[30]
Intergalactic dust | Astronomy Wiki - Fandom
By the 1980s, at least four intergalactic dust clouds have been found to exist within several megaparsecs of the Milky Way galaxy. One example is the Okroy ...
[31]
Dusty intergalactic matter | SpringerLink
Some preliminary results concerning the infrared emission from the region of Okroy's intergalactic dust cloud are given. ... Murawski, W., 1980. Acta Cosm ...
[32]
The Hubble Space Telescope Quasar Absorption Line Key Project. 10
Estimates ofGalactic Interstellar Extinction To determine the optical and ultraviolet energy distribution of a quasar requires knowledge of the optical and ...
[33]
Constraints on intergalactic dust from quasar colours - Inspire HEP
Colour measurements of quasars are used to constrain the abundance and properties of intergalactic dust and the related extinction effects on high-z sources.
[34]
Exploring the dust content of galactic winds with Herschel – II ...
The superior far-infrared sensitivity and angular resolution of Herschel have allowed detection of cold circumgalactic dust features beyond the stellar ...
[35]
Magnetic fields via polarimetry: progress on grain alignment theory
One of the most informative techniques of magnetic field studies is based on the use of starlight polarization and polarized emission arising from aligned dust.
[36]
Far-infrared emission from an intergalactic dust cloud?
We used theIRAS All Sky Maps in order to search for infrared emission in the direction of the Okroy Cloud (R.A.=12h50m, δ=22°). An enhancement of 100 μm ...
[37]
Strong damped Lyman-α absorption in young star-forming galaxies ...
May 23, 2024 · We examined previously published near-infrared James Webb Space Telescope (JWST) spectroscopy of 12 galaxies (table S1) to search for DLAs.
[38]
Intergalactic dust extinction in hydrodynamic cosmological simulations
Furthermore, the presence of intergalactic dust means that no high-redshift supernovae have zero extinction, contrary to the assumption usually made in global ...
[39]
[PDF] Constraints on intergalactic dust from quasar colours - arXiv
Sep 2, 2003 · It is expected that large dust grains will also cause some differential extinction for high-z sources (although less than for smaller dust ...
[40]
None
### Summary of Intergalactic Dust from https://arxiv.org/pdf/1510.07047.pdf
[41]
None
Nothing is retrieved...<|control11|><|separator|>
[42]
[PDF] Large-scale alignments of quasar polarization vectors :
Intergalactic dust? ○. Intergalactic dust grains aligned within large-scale (~1. Gpc) magnetic fields => small additional polarization.
[43]
[astro-ph/0501147] IGM metal enrichment through dust sputtering
Jan 10, 2005 · Abstract: We study the motion of dust grains into the Intergalactic ... dust sputtering, by Simone Bianchi and Andrea Ferrara. View PDF · TeX ...
[44]
Enhanced star formation through the high-temperature ... - Nature
Mar 2, 2023 · H2 formation is inefficient in the gas phase under typical interstellar conditions, requiring dust grain surfaces to act as catalysts. Small ...
[45]
Metal Enrichment of the Intergalactic Medium in Cosmological ...
This study develops a method of investigating the chemical enrichment of the IGM and of galaxies, using already completed cosmological simulations. To these ...