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Local Interstellar Cloud
Local Interstellar Cloud
Local Interstellar Cloud
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Local Interstellar Cloud
Interstellar cloud
Diagram of surrounding stars and artist's conception of the Local Interstellar Cloud
Observation data
ConstellationNone, Solar System is inside the nebula[1]
Physical characteristics
Dimensions30 ly (9.2 pc)
DesignationsLocal Cloud, LIC
See also: Lists of nebulae
Map showing the Sun located near the edge of the Local Interstellar Cloud and Alpha Centauri about 4 light-years away in the neighboring G-Cloud complex

The Local Interstellar Cloud (LIC), also known as the Local Fluff, is an interstellar cloud roughly 30 light-years (9.2 pc) across, through which the Solar System is moving. This feature overlaps with a region around the Sun referred to as the solar neighborhood.[2] It is unknown whether the Sun is embedded in the Local Interstellar Cloud, or is in the region where the Local Interstellar Cloud is interacting with the neighboring G-Cloud.[3] Like the G-Cloud and others, the LIC is part of the Very Local Interstellar Medium which begins where the heliosphere and interplanetary medium end,[4] the furthest that probes have traveled.

Structure

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The Solar System is located within a structure called the Local Bubble, a low-density region of the galactic interstellar medium.[5] Within this region is the Local Interstellar Cloud (LIC), an area of slightly higher hydrogen density. It is estimated that the Solar System entered the LIC within the past 10,000 years.[6] It is uncertain whether the Sun is still inside of the LIC or has already entered a transition zone between the LIC and the G cloud.[3][6][7] A recent analysis estimates the Sun will completely exit the LIC in no more than 1,900 years.[8]

The cloud has a temperature of about 7,000 K (7,000 °C; 12,000 °F),[9] about the same temperature as the surface of the Sun. However, its specific heat capacity is very low because it is not very dense, with 0.3 atoms per cubic centimetre (5/cu in). This is less dense than the average for the interstellar medium in the Milky Way (0.5/cm3 or 8/cu in), though six times denser than the gas in the hot, low-density Local Bubble (0.05/cm3 or 0.8/cu in) which surrounds the local cloud.[5][10] In comparison, Earth's atmosphere at the edge of space (i.e. 100 km above sea level) has around 1.2×1013 molecules per cubic centimeter, dropping to around 50 million (5.0×107) at 450 km (280 mi).[11]

The cloud is flowing outwards from the Scorpius–Centaurus association, a stellar association that is a star-forming region,[12][13] roughly perpendicular to the Sun's own direction.

In 2019, researchers found interstellar iron-60 (60Fe) in Antarctica, which they relate to the Local Interstellar Cloud.[14]

Interaction with solar magnetic field

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The Solar System within the interstellar medium, with the different regions and their distances on a logarithmic scale (object sizes not to scale)

In 2009, Voyager 2 data suggested that the magnetic strength of the local interstellar medium was much stronger than expected (370 to 550 picoteslas (pT), against previous estimates of 180 to 250 pT). The fact that the Local Interstellar Cloud is strongly magnetized could explain its continued existence despite the pressures exerted upon it by the winds that blew out the Local Bubble.[15]

The Local Interstellar Cloud's potential effects on Earth are greatly diminished by the solar wind and the Sun's magnetic field.[9] This interaction with the heliosphere is under study by the Interstellar Boundary Explorer (IBEX), a NASA satellite mapping the boundary between the Solar System and interstellar space.

See also

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References

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Further reading

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Local Interstellar Cloud

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from Grokipedia
The Local Interstellar Cloud (LIC), also known as the Local Fluff, is a diffuse, partially ionized of gas and dust that envelops the Solar System, forming the immediate local through which the Sun and its are currently passing. This cloud is characterized by a low density of approximately 0.1 neutral atoms per cubic centimeter, a temperature of around 6,700 , and a composition dominated by about 90% and 10% , with trace amounts of heavier elements and dust comprising roughly 1% of the total mass. Extending roughly 30 light-years (about 9 parsecs) across, the LIC surrounds the Sun in all directions, with the Sun located near the edge of the cloud. The LIC is part of a larger complex known as the Cluster of Local Interstellar Clouds (CLIC), which includes at least 15 distinct but coherently moving warm clouds within about 15 parsecs of the Sun, all residing inside the expansive Local Bubble—a low-density cavity spanning roughly 100 parsecs sculpted by multiple supernovae over the past 10–15 million years. Observations of ultraviolet absorption lines from nearby stars, particularly of species like hydrogen, helium, magnesium II, and iron II, have revealed the cloud's structure, showing it as a single, monolithic entity rather than fragmented pieces, though with subtle variations in velocity and depletion patterns due to interactions with the interstellar magnetic field and grain formation. The cloud's material flows toward the Solar System at about 26 km/s relative to the Sun, originating from the Scorpius-Centaurus stellar association, and it modulates the influx of galactic cosmic rays into the heliosphere while influencing the shape and dynamics of the heliopause. Recent models suggest the LIC and CLIC formed from the compression and cooling of ambient gas by shock waves from a in the Upper subgroup approximately 1.2 million years ago, rather than from ionization fronts around hot stars, highlighting the dynamic interplay between stellar activity and the local interstellar environment. As the Solar System traverses this region at roughly 23 km/s toward the constellation , it is expected to remain within the LIC for another 3,000–10,000 years before entering a denser , potentially altering the heliosphere's configuration and shielding. Missions like and 2 have provided measurements confirming the cloud's plasma properties, including densities around 0.05 cm⁻³ and neutral flows, underscoring the LIC's role in shaping the boundary between the solar and interstellar domains.

Overview

Definition and Characteristics

The Local Interstellar Cloud (LIC), also known as the Local Fluff, is a low-density approximately 30 light-years (9.2 parsecs) across that currently envelops the Solar System. This cloud represents a small-scale structure within the broader , through which our solar system is passing as it orbits the . The LIC is predominantly composed of neutral hydrogen and gas, with partial ionization (hydrogen ionization fraction ~0.2), accompanied by microscopic grains that constitute about 1% of its total mass. Its overall low opacity permits visible to traverse it with minimal absorption or , distinguishing it from denser interstellar regions. As the immediate interstellar environment surrounding the , the LIC modulates the flux of cosmic rays entering the Solar System and influences long-term planetary evolution by shaping interactions between the and external material. Conceptually, it functions as a transient "cloudlet" embedded within a larger low-density cavity in the , highlighting the dynamic and patchy nature of nearby galactic gas distributions. The cloud resides within the Local Bubble, a vast region of hot, tenuous plasma sculpted by ancient supernovae.

Location and Extent

The Local Interstellar Cloud (LIC) occupies a position in the galactic disk centered on the Solar System, with its upwind direction oriented at galactic coordinates approximately l=15l = 15^\circ, b=20b = 20^\circ, toward the Scorpius-Centaurus association. This positioning places the cloud within the local , where the relative motion of the gas defines its orientation relative to the Sun's trajectory through the . The cloud exhibits an elongated, irregular shape, extending roughly 30 light-years (about 9 parsecs) across, though its boundaries vary significantly in different directions. The Solar System resides near one edge of this structure, positioned approximately 0.3 parsecs from the downwind boundary, placing it close to the interface with surrounding regions. This off-center location implies that the Sun entered the LIC relatively recently, on the order of tens of thousands of years ago. The LIC's boundaries lack sharp demarcations, instead characterized by gradual density gradients that transition into neighboring interstellar structures, such as the G-Cloud toward the galactic center and the Ursa Major cloud in the opposite hemisphere. These transitions are marked by ionization fronts where neutral gas gives way to more ionized material, reflecting the dynamic interactions within the local medium. In three-dimensional mappings of the local interstellar medium, the LIC is depicted as a filamentary or sheet-like feature, irregularly enveloping the heliosphere and embedded within the expansive Local Bubble—a low-density cavity spanning hundreds of parsecs. These visualizations highlight the cloud's asymmetry and its role as part of a cluster of smaller cloudlets. Traveling approximately 5 light-years from the Sun in directions other than toward the Alpha Centauri system, one would encounter only the sparse interstellar medium of the Local Interstellar Cloud, consisting of rarefied gas and dust, with no stars, and possibly rare interstellar objects such as rogue comets.

Discovery and History

Early Observations

The recognition of the Local Interstellar Cloud (LIC) in the 1970s stemmed from ultraviolet absorption lines detected in the spectra of nearby stars, primarily through early space-based observations that complemented ground-based optical data. Pivotal were observations from the Copernicus satellite, which surveyed UV absorption in nearby stars, revealing the low column densities characteristic of the . Astronomers identified low column densities of neutral and ionized species, suggesting the Sun resides within a diffuse, low-density rather than a complete vacuum. These findings highlighted the LIC as a partially ionized structure with densities approximately 0.1 neutral atoms per cm³ (with measurements ranging from 0.03 to 0.1 cm⁻³), distinct from denser interstellar regions. Key evidence included anomalous low extinction toward nearby stars, where the interstellar reddening was unexpectedly minimal compared to galactic averages, implying a local region depleted of dust and gas. This low , measured through photometric surveys of stars within 100 pc, supported the idea of a local cavity containing residual cloud material like the LIC. Ground-based of optical lines, such as Ca II H and K, further revealed absorption components at low velocities, mapping the of this local gas. The soft background provided crucial supporting evidence for the broader context, with detections indicating a hot (∼10^6 K), low-density cavity—the Local Bubble—encompassing the LIC. First observed in experiments, this isotropic emission in the 0.1–0.25 keV band suggested local hot gas from supernova heating, with cooler embedded clouds accounting for the neutral absorption features. Theoretical models from the 1960s and 1970s framed the LIC within the Local Bubble as an embedded structure formed by the evaporation and compression of gas in supernova-driven cavities. Seminal work demonstrated that multiple could carve out hot bubbles spanning hundreds of parsecs, leaving behind low-density neutral clouds consistent with the observed local properties. A milestone was the 1974 analysis by Jenkins and Meloy of O VI absorption lines, which traced hot gas interfaces potentially bordering the LIC, though neutral hydrogen features toward stars like Sirius were later confirmed in complementary studies.

Key Missions and Measurements

The Ulysses mission, launched in 1990, provided the first in-situ measurements of interstellar neutral inflow through its Gas experiment (GAS) instrument, which detected helium atoms by ionizing them upon interaction with a conversion surface. These observations, conducted during the , established the velocity vector of the neutral helium flow at approximately 26 km/s relative to the Sun, directed toward the galactic south, and confirmed a high neutral fraction of helium in the Local (LIC), with densities around 0.015 cm⁻³ indicating minimal ionization. The and 2 spacecraft, having crossed the heliopause in 2012 and 2018 respectively, delivered direct in-situ measurements of plasma and magnetic fields in the very local , revealing a plasma density increase to about 0.06 cm⁻³ beyond the heliopause and evidence of neutral through pickup signatures. These ongoing observations, extending into 2025, have refined understanding of the LIC's plasma environment and its transition from the heliosheath. Launched in 2008, the Interstellar Boundary Explorer (IBEX) mission produced all-sky maps of energetic neutral atoms (ENAs) from the heliosphere's interaction with the LIC, delineating its boundaries and confirming the interstellar flow velocity at ~26 km/s toward the upwind direction in the galactic coordinate frame (l ≈ 255°, b ≈ 10°). IBEX's ENA imaging, spanning multiple solar cycles through 2025, highlighted asymmetries in the LIC's structure and neutral atom fluxes, with peak ENA energies around 1-2 keV providing indirect constraints on the cloud's outer edges. Ultraviolet spectroscopy from the Hubble Space Telescope's Space Telescope Imaging Spectrograph (STIS) and earlier Goddard High Resolution Spectrograph (GHRS) has measured absorption lines of neutral hydrogen (Lyα at 1216 Å) and deuterium along sightlines through the LIC toward nearby stars, yielding column densities of N(H I) ≈ 10¹⁸ cm⁻² and D/H ratios around 1.5 × 10⁻⁵. Complementary far-ultraviolet observations from the () grism surveys contributed broadband UV flux mappings that contextualize these absorption features in the LIC's diffuse emission. These datasets, analyzed up to 2025, underscore the LIC's warm neutral medium properties without resolving finer structures. Recent integrations of Data Release 3 (DR3, released 2022) with spectroscopic radial velocities have enabled 3D velocity field reconstructions of the LIC and adjacent clouds, revealing coherent flows at ~10-20 km/s relative to the local standard of rest and kinematic links to the broader . By 2025, these analyses incorporated updated for over 100 young stellar objects and molecular clouds within 35 pc, enhancing models of the LIC's dynamical extent. The (IMAP), launched in September 2025, previews enhanced mapping of the LIC's magnetic field through its suite of 10 instruments, including ENA imagers and a to resolve interstellar field strengths around 3-5 μG and their draping over the . Early mission previews emphasize IMAP's role in combining ENA all-sky surveys with in-situ particle data for comprehensive LIC boundary delineation.

Physical Properties

Composition and Density

The Local Interstellar Cloud (LIC) is primarily composed of neutral hydrogen (H I), which constitutes approximately 90% of its mass, with (He) making up about 10%, consistent with the abundances observed in the solar system and typical for diffuse interstellar clouds. Trace amounts of heavier elements, such as carbon (C), oxygen (O), and iron (Fe), are present predominantly in ionized forms (e.g., C II, O I, Fe II) due to partial ionization from (EUV) radiation. grains account for roughly 1% of the total mass, comprising silicates, carbonaceous particles, and other refractory materials that contribute to the cloud's opacity and properties. The average neutral density in the LIC is approximately 0.1–0.2 atoms cm⁻³, with variations observed along different sightlines reflecting the cloud's inhomogeneous structure. Recent analyses of nearby sightlines suggest a lower average of about 0.10 cm⁻³, while measurements closer to the indicate values up to 0.20 cm⁻³, possibly due to mixing with adjacent clouds. The ionization fraction of is around 20%, driven by EUV photons from nearby hot stars, resulting in a partially ionized plasma where electrons and protons balance the neutral component. Neutral density is lower, at about 0.015 cm⁻³, reflecting its higher first ionization potential. These properties are derived primarily from ultraviolet (UV) absorption spectroscopy, which measures column densities of species like H I via the Lyman-α (Lyα) line at 1216 Å, allowing inference of volume densities through modeling of sightline paths: NH=nHdsN_{\rm H} = \int n_{\rm H} \, ds, where NHN_{\rm H} is the column density and dsds is the path length along the line of sight. Complementary in situ measurements come from interstellar pickup ions detected by spacecraft instruments, such as the Solar Wind Ion Composition Spectrometer on Ulysses, which sample neutral atoms ionized by charge exchange and provide direct constraints on bulk densities and compositions. Heavy elements in the LIC exhibit significant depletion onto dust grains compared to solar abundances, with factors ranging from 10 to 100 depending on the species and local conditions. For instance, iron is depleted by a factor of approximately 20 (logarithmic depletion ≈ -1.3), while carbon and oxygen show milder depletions of about 2 (logarithmic ≈ -0.3), indicating selective adsorption and processes in the diffuse medium. These patterns are quantified through comparisons of gas-phase abundances from UV lines (e.g., Fe II at 2382 ) with total (gas + ) solar values, highlighting the role of in sequestering refractories.

Temperature and Dynamics

The Local Interstellar Cloud (LIC) resides in the warm neutral medium of the interstellar space, characterized by temperatures primarily in the range of 6000–7000 K, as determined from the Doppler broadening of absorption lines in ultraviolet spectra of nearby stars. This thermal regime reflects a partially ionized plasma where neutral hydrogen dominates, but ionized components exhibit slightly higher temperatures up to approximately 10,000 K, inferred from line widths of heavier ions like Fe II and Mg II compared to lighter ones such as H I. These measurements, obtained via high-resolution spectroscopy from instruments like the Hubble Space Telescope's Space Telescope Imaging Spectrograph, reveal an average temperature of about 6500 K across multiple sight lines through the cloud, underscoring its thermal homogeneity on large scales despite local variations. Dynamically, the LIC exhibits a bulk motion of approximately 23–26 km s⁻¹ relative to the Sun, approaching from the direction of the constellation , as traced by the velocity vectors of interstellar absorption components. This coherent flow, part of the broader Cluster of Local Interstellar Clouds, drives the interstellar wind impinging on the . Superimposed on this bulk motion is with characteristic velocities of 1–3 km s⁻¹, manifesting on spatial scales of 0.1–1 pc, as quantified from nonthermal broadening in spectral lines across diverse atomic species. The magnetic field within the LIC provides crucial support against , contributing to the cloud's stability alongside turbulent pressures that prevent fragmentation on these scales. The LIC maintains stability through approximate pressure equilibrium with the surrounding hot gas in the Local Bubble, where the thermal pressure balances the higher pressures of the million-Kelvin plasma outside. This equilibrium is described by the , P=nkTP = n k T, with nn the total particle , kk Boltzmann's constant, and TT the temperature; for typical LIC values of n0.3n \approx 0.3 cm⁻³ and T7000T \approx 7000 K, P3×1013P \approx 3 \times 10^{-13} dyn cm⁻², comparable to the nonthermal contributions that sustain the cloud's diffuse structure. The low precludes active , as the cloud lacks the mass and compression needed to trigger gravitational instabilities, remaining a quiescent filamentary structure within the Local Bubble.

Galactic Context

Relation to the Local Bubble

The Local Bubble is a low-density cavity in the , approximately 300 parsecs (about 1,000 light-years) in diameter, sculpted by multiple explosions occurring roughly 10–15 million years ago, and filled with hot, tenuous plasma at temperatures around 10^6 K. This structure, also known as the Local Cavity, encompasses the solar neighborhood and is characterized by its ionized gas, which contrasts sharply with the denser surrounding . The Local Interstellar Cloud (LIC) resides as one of several small cloudlets within the cooler, partially ionized interior of the Local Bubble, collectively known as the Cluster of Local Interstellar Clouds (CLIC). These cloudlets occupy less than 1% of the Bubble's volume but play a crucial role in modulating the local environment, including shielding the Solar System from direct exposure to the Bubble's high-temperature gas by providing a denser, warmer barrier at about 7000 K. The LIC, spanning roughly 30 light-years, is embedded amid this sparse hot phase, highlighting the Bubble's heterogeneous structure. Recent models suggest the Local Bubble is part of a larger "Local Chimney" structure extending toward the galactic plane. The formation of the LIC is linked to the Local Bubble's evolution, likely arising from the condensation of cooling gas within the cavity or the compression of pre-existing material by supernova-driven shock waves. Recent 2025 models suggest these clouds originated from interactions involving ionization fronts and variations tied to the adjacent Loop I superbubble dynamics, which influenced the Bubble's expansion and internal cloud formation. Evolutionarily, the Solar System entered the broader around 5–10 million years ago, with more recent passage into the specific LIC occurring approximately 100,000 years ago; projections indicate the system will exit the LIC in about 10,000 years, transitioning to neighboring cloud structures.

Nearby Interstellar Structures

The Cluster of Local Interstellar Clouds (CLIC) comprises approximately 15 low-density, warm, partially ionized clouds situated within about 15 pc of the Sun, forming the immediate interstellar environment around the Solar System. Prominent members include the Local Interstellar Cloud (LIC), the , the Auriga Cloud, and the Platycodon Cloud, which collectively occupy a small fraction of the Local Bubble's volume while exhibiting distinct kinematic structures. Key neighboring structures to the LIC within the CLIC include the , a denser cloud with a hydrogen nH0.5cm3n_\mathrm{H} \approx 0.5 \, \mathrm{cm^{-3}}, located approximately 5° angularly from the Sun's position. In 2025, astronomers discovered the Eos dark at a distance of 94 pc, a CO-dark, low-density feature revealed through H₂ far-ultraviolet fluorescent emission, marking it as one of the closest known molecular clouds to the Solar System and providing insights into cloud formation in the Local Bubble. Recent modeling attributes the formation of the CLIC to the expansion of a from an event in the Upper Centaurus Lupus subgroup of the Scorpius-Centaurus association approximately 1.2 million years ago, which compressed ambient interstellar material into these discrete clouds through shockwave propagation. The clouds exhibit coherent bulk motion relative to the local standard of rest at velocities of roughly 20–30 km s⁻¹, differing from the more turbulent dynamics of denser molecular clouds in other galactic regions.

Interactions with the Solar System

Boundary with the Heliosphere

The marks the boundary between the (LIC) and the , situated at approximately 120 AU from the Sun, where the outward pressure of the equilibrates with the exerted by the inflowing LIC plasma. This dynamic interface results in a comet-like shape for the , with the upstream side compressed into a blunt "" directed opposite to the Sun's motion through the LIC at a of about 26 km/s. The from this inflow dominates the interaction, shaping the boundary without forming a traditional due to the influence of the interstellar , though models predict a hypothetical standoff distance on the order of 10^4 km for any shock-like structure in the neutral component. At this boundary, key interaction processes involve charge exchange between solar wind ions and neutral atoms from the LIC, primarily , which generates energetic neutral atoms (ENAs) that propagate inward and provide remote diagnostics of the outer . crossed the heliopause in August 2012 at ~122 AU, and followed in November 2018 at ~119 AU, directly detecting abrupt changes in plasma density, low-energy particle fluxes, and orientation indicative of these charge exchange processes and the transition to . These crossings revealed a ~10-fold increase in galactic intensities beyond the heliopause, implying that the filters approximately 90% of incoming cosmic rays through diffusion, convection, and magnetic shielding within its boundaries. The Interstellar Mapping and Acceleration Probe (IMAP), launched on September 24, 2025, is expected to refine models of boundary asymmetry, highlighting how the Sun's position near the edge of the LIC contributes to an irregular heliopause shape and uneven plasma exchanges.

Magnetic Field Effects

The interstellar magnetic field (ISMF) within the Local Interstellar Cloud (LIC) has a strength of approximately 3–5 μG, as inferred from models incorporating Voyager spacecraft measurements of the magnetic field just beyond the heliopause. This field is oriented at an angle of about 30° to the galactic plane, with its direction determined through analyses of starlight polarization, which traces the alignment of interstellar dust grains along magnetic field lines, and Zeeman splitting in spectral lines from nearby stars, providing constraints on the line-of-sight component of the field. The ISMF interacts with the heliosphere by draping over its boundary, the heliopause, due to the opposing pressures from the solar wind and the interstellar medium. This draping compresses the heliosphere on the upwind side and elongates it into a magnetotail on the downwind side, where the magnetic field lines are stretched and reconnected. The equilibrium at the boundary is governed by the balance between the interstellar magnetic pressure, given by B2/(8π)B^2 / (8\pi), and the dynamic pressure of the interstellar flow, ρv2\rho v^2, where BB is the magnetic field strength, ρ\rho is the plasma density, and vv is the flow velocity. Voyager 1 and 2 data indicate that the magnetic field in the inner heliosheath near the heliopause is compressed by a factor of 2–3 relative to the undisturbed ISMF value farther out. These magnetic interactions modulate the (HCS), the large-scale structure separating regions of opposite solar magnetic polarity, by tilting and warping it at heliospheric distances beyond 100 AU, influenced by the ISMF orientation. Additionally, the draped ISMF enhances cosmic ray anisotropy, as high-energy particles are scattered preferentially by the structured field, leading to observable directional asymmetries in cosmic ray fluxes detected at . Over longer timescales, as the Sun moves through the LIC at approximately 26 km/s, fluctuations in the local ISMF could alter heliospheric configuration on millennial scales, potentially influencing geomagnetic activity through modulated cosmic ray ingress and associated atmospheric effects.

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