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Bubble Nebula
Bubble Nebula
Bubble Nebula
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NGC 7635
Emission nebula
H II region
Wide field image of NGC 7635 as captured by the Hubble Space Telescope
Observation data: J2000 epoch
Right ascension23h 20m 48.3s[1]
Declination+61° 12′ 06″[1]
Distance7100[2] to 11000[3][4] ly   (3,400 pc)
Apparent magnitude (V)10[5]
Apparent dimensions (V)15 × 8[6]
ConstellationCassiopeia
Physical characteristics
Radius3[2] to 5[7][4] ly
Notable featuresShell around SAO 20575[1]
DesignationsBubble Nebula[1]
Sharpless 162 (Sh2-162)
Caldwell 11
See also: Lists of nebulae

NGC 7635, also known as the Bubble Nebula, Sharpless 162, or Caldwell 11, is an H II region[1] emission nebula in the constellation Cassiopeia. It lies close to the open cluster Messier 52. The "bubble" is created by the stellar wind from a massive hot, 8.7[1] magnitude young central star, SAO 20575 (BD+60°2522).[7] The nebula is near a giant molecular cloud which contains the expansion of the bubble nebula while itself being excited by the hot central star, causing it to glow.[7] It was discovered in November 1787 by William Herschel.[5] The star BD+60°2522 is thought to have a mass of about 44 M.

Amateur observation

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NGC 7635 and its environs imaged through an 8-inch amateur telescope

With an 8-or-10-inch (200 or 250 mm) telescope, the nebula is visible as an extremely faint and large shell around the star.[6][1] The nearby 7th magnitude star on the west hinders observation, but one can view the nebula using averted vision.[6] Using a 16-to-18-inch (410 to 460 mm) scope, one can see that the faint nebula is irregular, being elongated in the north south direction.[6]

See also

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Notes

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Bubble Nebula

View on Grokipedia
from Grokipedia
The Bubble Nebula, designated NGC 7635, is a striking in the constellation Cassiopeia, situated approximately 7,100 light-years from Earth and spanning about 7 light-years across. This glowing shell of ionized gas and dust forms a distinctive bubble-like structure, sculpted by the powerful stellar winds from its central , BD +60°2522, which is roughly 45 times more massive than the Sun and emits winds exceeding 4 million miles per hour. Discovered in 1787 by astronomer , the nebula's asymmetrical shape arises from interactions between the star's outflow and surrounding dense interstellar material, creating pillars of cool hydrogen gas reminiscent of the famous . The nebula's vivid colors—blues from oxygen, greens from , and reds from —result from the of gases by the central star's intense radiation, making it a prime target for astronomical imaging. Observations, particularly from the , reveal intricate details of within the nebula's denser regions, where light triggers the birth of new stars amid the turbulent environment. As part of a larger complex of gaseous shells and young stellar clusters, the Bubble Nebula exemplifies the dynamic processes of massive and feedback in the .

Overview

Designations and coordinates

The Bubble Nebula is cataloged under several designations, including NGC 7635, Sharpless 2-162 (Sh 2-162), and , reflecting its identification in major astronomical surveys such as the , the Sharpless Catalogue of H II regions, and Patrick Moore's of deep-sky objects. For precise sky positioning, the nebula's equatorial coordinates in the J2000 epoch are 23h 20m 48.3s and +61° 12′ 06″. It is situated in the constellation Cassiopeia, in close angular proximity to the (NGC 7654), approximately 0.5 degrees to the southwest, allowing both objects to be observed within the same wide-field view. The nebula exhibits an integrated apparent visual magnitude of 10, making it a challenging target for amateur telescopes under dark skies.

Distance and size

The Bubble Nebula (NGC 7635) lies at an estimated distance of 7,100 to 11,000 light-years (2,200 to 3,400 parsecs) from , with recent Gaia DR3 measurements for the central star placing it at about 8,500 light-years; this range reflects uncertainties in measurement techniques applied to its associated stellar components. Specific estimates include 7,100 light-years derived from observations of the central region's dynamics and 8,000 light-years from broad-field imaging surveys. Variations stem from methods like spectroscopic , which infers distance by analyzing the spectrum and apparent brightness of the ionizing O-star BD +60° 2522 to place it on the Hertzsprung-Russell diagram. Physically, the nebula features a prominent bubble with a radius of 3 to 5 light-years, expanding from the of its central source, while the overall structure, including surrounding filaments, extends approximately 7 to 10 light-years across. These dimensions position the Bubble Nebula as a mid-scale wind-blown shell within the of Cassiopeia, comparable to the span between our Sun and nearby stars like Alpha Centauri. From , the subtends an apparent angular size of 15′ × 8′ in visible wavelengths, making it a challenging but rewarding target for mid-sized telescopes under . This angular extent, combined with the distance estimates, allows astronomers to compute the physical scale and track expansion rates over time.

Discovery and history

Initial discovery

The Bubble was first discovered on November 3, 1787, by the German-born British astronomer during his systematic sweeps of the night sky. Using his 7-foot Newtonian reflector telescope, which featured a 6.3-inch speculum mirror, Herschel observed the object from his observatory in , . Herschel cataloged the nebula as the 52nd entry in his fourth class of objects (H IV.52), noting it as a faint and diffuse feature. His description captured it as "a star of 9th magnitude with very faint nebulosity of small extent about it, but little brighter in the middle," highlighting its subtle appearance even under his instrument's capabilities. This initial observation marked it as an ill-defined patch of nebulosity surrounding a visible star, without recognition of its distinctive bubble-like structure. The object received its formal designation as NGC 7635 in the of Nebulae and Clusters of Stars, compiled by Danish astronomer John Louis Emil Dreyer and published in 1888. Dreyer's catalog integrated Herschel's findings with observations from other astronomers, standardizing the entry based on positional data from Herschel's sweeps.

Subsequent observations and imaging

Following its initial discovery, the Bubble Nebula was cataloged in the Sharpless Catalogue of H II regions as Sh2-162 in 1959, recognizing it as an in the . Later, in 1995, it was included in the as C11, compiled by to provide amateur astronomers with additional deep-sky targets beyond the Messier list. Early spectroscopic studies of the nebula utilized the Hubble Space Telescope's Space Telescope Imaging Spectrograph (STIS), with observations conducted in 1997 to capture ultraviolet-optical spectra of the ionized gas and test for abundance gradients in the Perseus Arm. These spectra provided the first accurate carbon-to-hydrogen abundance ratios in the region, revealing insights into the nebula's chemical composition without prior reliance on ground-based data alone. Ground-based radio and far-infrared observations advanced mapping efforts in the early 1980s, including a 1982 study that partially mapped the nebula at 1 arcminute resolution in the far-infrared using the and fully mapped it at 2.2 arcminutes in 115-GHz CO emission with the 14-meter telescope at the Five College Radio Astronomy Observatory. These measurements detected molecular gas envelopes and far-infrared continuum emission, delineating the 's structure at resolutions finer than previous optical surveys. The contributed iconic imaging in 2016, releasing a high-resolution composite image for its 26th anniversary that vividly revealed the nebula's intricate bubble structure, spanning about 7 light-years across and sculpted by the central star's winds. This observation combined , visible, and near-infrared filters to highlight the glowing shell's edges and surrounding dust lanes, enhancing public and scientific appreciation of its morphology. More recent multiwavelength surveys have incorporated the Bubble Nebula into broader datasets, such as the 2015 EPIC X-ray observations that set upper limits on any faint extended emission from hot gas within the bubble (under 3 million K if present), consistent with low-density wind-blown models. Similarly, archival infrared data at wavelengths of 3.6 to 24 micrometers from the GLIMPSE and MIPSGAL surveys revealed the nebula's dust distribution and embedded young stellar objects, complementing optical views by tracing cooler components of the .

Physical characteristics

Morphology and structure

The Bubble Nebula, designated NGC 7635, is classified as an , characterized by its glowing ionized gas excited by radiation from a central massive star. Its overall shape forms an elongated north-south shell, resembling a due to the thin, symmetrical arc that dominates its appearance, spanning approximately 7 light-years in physical diameter. This structure is embedded within the larger Sharpless 162 emission complex in the constellation Cassiopeia. The nebula's primary feature is a thin ionized shell of gas, primarily , that outlines the bubble's boundary where stellar winds interact with the surrounding , creating a bright rim particularly prominent on the northern side. This shell surrounds a darker foreground , which includes dark globules with bright rims, obscuring parts of the and contributing to its striking contrast in optical images. The ionized regions emit strongly in light, highlighting the shell's arc-like morphology against the denser, cooler molecular material. Kinematic studies reveal additional complexity, with the Bubble Nebula composed of multiple nested shells, some exhibiting blister-like structures that suggest localized instabilities in the expanding gas. These nested features, observed through spectroscopic mapping, indicate a layered architecture within the overall bubble, enhancing its dynamic structural profile without altering the dominant spherical .

Central ionizing star

The central ionizing star of the Bubble Nebula is SAO 20575, also designated BD+60°2522, a massive with a type of O6.5 III((f))p. This reflects its early-type characteristics, including prominent emission lines indicative of a strong . SAO 20575 has an apparent visual magnitude of 8.7, making it visible in medium-sized telescopes under . Its physical parameters include a mass of 27 ± 7 M⊙, a surface of 35,000 ± 500 K, and a radius of about 15 R⊙. These properties place it among the hottest and most luminous stars, with a bolometric of log(L/L⊙) = 5.4 ± 0.1. As a young O-type star in its main-sequence phase, SAO 20575 undergoes rapid mass loss at a rate of log(Ṁ/M⊙ yr⁻¹) = -5.9 ± 0.1, driven by its intense ultraviolet radiation and powerful stellar winds reaching terminal velocities of 2,000 ± 100 km s⁻¹. This energy output ionizes the surrounding interstellar medium, creating the glowing H II region observed as the nebula. The star's position near the edge of the molecular cloud centers the bubble's asymmetric structure.

Formation and dynamics

Stellar wind mechanism

The Bubble Nebula's distinctive bubble structure arises from the wind-blown bubble model, wherein powerful stellar winds from the central massive O6.5 IIIf star BD +60° 2522 sweep up the surrounding interstellar medium to form a low-density interior cavity and a compressed outer shell. These winds achieve terminal velocities of approximately 2000 km s⁻¹ and carry a mass-loss rate of about 1.3 × 10⁻⁶ M⊙ yr⁻¹, exerting ram pressure that pushes ambient gas outward like a stellar snowplow. The winds collide with denser regions of the , particularly a to the north with densities around 310 cm⁻³, compressing the gas into the ionized shell and contributing to the nebula's asymmetry, with the star offset from the geometric center. Ultraviolet radiation from the hot central star ( ~35 kK) ionizes in this shell, producing prominent Hα emission lines that highlight the structure in optical images. The bubble's expansion is powered by the ongoing input from these , estimated at levels sufficient to sustain the observed morphology over a dynamical timescale of roughly 14,000 to 43,000 years, derived from the shell's size and expansion .

Kinematics and evolution

The Bubble Nebula exhibits complex kinematic features characterized by nested ionized shells expanding at velocities ranging from 15 to 25 km/s, with photoevaporative flows from blister-like structures reaching up to 40 km/s along the . These nested shells, observed through spectroscopic mapping, indicate a multi-layered morphology where inner shells expand at approximately 15 km/s and outer structures at around 14.5 km/s relative to the local standard of rest. Blister structures, particularly prominent in the southern extension, suggest asymmetric outflows driven by interactions with denser , resulting in disrupted bubble-like cavities up to 1.45 pc in size and an overall elongation toward the . The evolutionary history of the nebula reflects multiple episodes of star formation spanning at least two distinct phases, as evidenced by photometric analysis of stars in the field. Color-magnitude diagrams reveal a break in the main-sequence population at V ≈ 18.5 mag, separating younger bluer stars from older redder ones, with pre-main-sequence stars concentrated along the bubble's rim. This distribution implies that the expansion of the central shell has compressed surrounding molecular gas, triggering the formation of new stars at the periphery through radiative and mechanical feedback from the ionizing O6.5 IIIf star BD +60° 2522. The bubble itself is relatively young, estimated at 4 × 10⁴ years, while the central star has an age of approximately 3.4 × 10⁶ years, consistent with sequential bursts in the broader S162 complex. Looking ahead, the nebula will persist in its expansion phase, accumulating swept-up mass in an energy-conserving snowplow regime, until the central star exhausts its core and evolves toward core collapse. Given the star's initial mass of about 45 M⊙ and current evolutionary stage, this terminal phase, culminating in a explosion, is projected to occur within 1–2 million years, ultimately dispersing the nebula's structure into the .

Observation and study

Professional telescopes and data

Multiwavelength observations of the Bubble Nebula (NGC 7635) have utilized advanced professional telescopes to probe its structure and physical conditions. data from the observatory, obtained in 2015 with exposure times of approximately 40-59 ks across its EPIC instruments, failed to detect diffuse emission indicative of hot gas within the bubble interior, placing upper limits on the soft flux at Fsoft,X<1×1014F_{\text{soft},X} < 1 \times 10^{-14} erg ⁻² s⁻¹ (for kT=0.22kT = 0.22 keV) and hard flux at Fhard,X<6×1015F_{\text{hard},X} < 6 \times 10^{-15} erg ⁻² s⁻¹ (for kT=2.16kT = 2.16 keV), corresponding to luminosities below 9×10309 \times 10^{30} erg s⁻¹ and 5×10305 \times 10^{30} erg s⁻¹, respectively. These non-detections imply electron densities in the interior of ne<0.07n_e < 0.07 ⁻³ (soft) and ne<0.04n_e < 0.04 ⁻³ (hard), suggesting limited hot gas mixing or hydrodynamical instabilities. Infrared observations from the , particularly at 24 μm using the MIPS instrument (program ID 20726, observed in 2005), reveal the distribution of warm dust associated with the nebula's and shell. The emission peaks at the northern apex with surface brightnesses around 103.510^{3.5} MJy sr⁻¹, tracing dense ambient medium interactions and photoevaporation flows, while the overall structure spans a diameter of about 3 arcmin (corresponding to ~2.3 pc at an assumed distance of 2.7 kpc, per the study), consistent with dust heated by the central star's radiation and winds. Earlier far-infrared mapping at 1 arcmin resolution further supports this by showing extended emission aligned with the bubble's morphology. Spectroscopic studies using the Hubble Space Telescope's Space Telescope Imaging Spectrograph (STIS) have analyzed emission lines to determine shell properties. In the rim and shell, [S II] line ratios yield electron densities of approximately 1,130 cm⁻³, while [Cl III] indicates 1,330 cm⁻³, with higher values up to 7,560 cm⁻³ in nearby knots, spanning the range 10310^310410^4 cm⁻³ overall. Electron temperatures derived from [O III] and [N II] lines are around 8,180 and 7,950 in the rim, respectively, and 8,560 in knots, approximating ~10,000 and reflecting ionization conditions near the central O star. Radio observations at 115 GHz have mapped (CO) emissions to outline the parent . Conducted at 2.2 arcmin resolution, these reveal weak CO emission with low column densities (~10^{15} cm⁻²), consistent with minimal obscuration, and trace a partial envelope around the H II region, indicating the nebula's embedding in a low-density molecular environment. Notable imaging includes the 2016 Hubble Space Telescope Heritage Project release, enhancing views of the nebula's structure. As of 2025, no observations have been reported.

Amateur viewing tips

Observing the Bubble Nebula visually presents significant challenges due to its low , which causes it to appear as a faint, ghostly arc rather than a distinct bubble shape without optical aids. A nearby 7th-magnitude star to the west can interfere with dark adaptation, making the nebula harder to detect in direct vision. Amateur astronomers typically require a telescope with at least an 8- to 10-inch to detect the faint shell under , while instruments of 16- to 18-inch reveal more of its irregular structure. H-alpha filters are essential for enhancing contrast against the background , as they isolate the nebula's primary emission line and block unwanted . The nebula's apparent size of about 15 by 8 arcminutes necessitates low-power eyepieces to fit the entire object in the field of view. For optimal viewing from the , target the nebula in autumn, particularly November, when Cassiopeia reaches a high altitude to minimize atmospheric distortion. Employ techniques to overcome the interference from the nearby star and to tease out subtle details in the faint nebulosity. Start by locating the open cluster , then scan about 0.5 degrees southwest to center on the target area.

Scientific importance

Research contributions

A seminal study utilizing (HST) observations provided high-resolution imagery and of the Bubble Nebula, confirming the interaction between the fast from the central O6.5 IIIf star BD +60° 2522 and the surrounding dense . The images revealed a well-defined thin shell of ionized gas approximately 1.5 pc in diameter, along with cometary-shaped globules and photoevaporative flows, consistent with the wind-blown bubble paradigm where the wind sweeps up ambient material into a thin shell. This work established the dynamical age of the bubble at roughly 0.3–0.5 Myr based on expansion estimates. Subsequent kinematic in a multiwavelength investigation tested the wind-blown bubble theory more rigorously, employing long-slit spectroscopy to map radial velocities across the nebula. The study identified a series of nested shells with blister-like protrusions, expanding at velocities of ~15 km/s for the inner shell and ~14.5 km/s for the outer shell, centered at systemic velocities of V_LSR ≈ -32 km/s and -19 km/s, respectively. These findings suggest that the observed morphology arises partly from projection effects and the ~36 km/s space motion of the central star through the , rather than a purely spherical expansion, while still supporting the overall wind-driven mechanism. serve as supporting data for theory validation without contradicting core predictions. Deep spectroscopic observations have elucidated the of the Bubble Nebula, revealing it to be dominated by ionized (H II) forming the primary constituent of the ionized gas, with as the next most abundant element at He/H ≈ 0.11 by number. Trace elements include oxygen (O/H ≈ 2–8 × 10^{-4}), (N/H ≈ 2–7 × 10^{-5}), and (S/H ≈ 1–5 × 10^{-5}), with abundances showing mild spatial variations across the nebula due to inhomogeneities in and . Electron densities, derived from the ratio of the [S II] λλ6716/6731 forbidden lines, vary significantly from <100 cm^{-3} in low-density regions to ~2140 cm^{-3} in denser condensations, reflecting the clumpy structure of the shell. Infrared observations of the shell have uncovered evidence of triggered star formation, where the expanding bubble compresses ambient gas to initiate collapse. Young stellar objects (YSOs) are detected through mid-infrared excesses indicative of protoplanetary disks and ongoing accretion, with several candidates identified in the shell's periphery via Spitzer Space Telescope data, suggesting that the bubble's dynamics have stimulated a new generation of low- to intermediate-mass stars.

Role in stellar astrophysics

The Bubble Nebula (NGC 7635) exemplifies a wind-blown bubble formed by the interaction of a massive O-type star's fast with the surrounding ionized , serving as a key for testing theoretical models of such structures. Its central star, BD+60°2522, with a of approximately 2000 km s⁻¹ and mass-loss rate of 1.3 × 10⁻⁶ M⊙ yr⁻¹, enables direct validation of predictions on massive star mass ejection and the resultant sculpting of the into thin, expanding shells. Observations of its nested shell morphology and limited mixing—evidenced by the absence of diffuse emission—challenge standard hydrodynamical models that expect greater instability-driven , highlighting the role of stratified or clumpy ambient gas in bubble formation. Positioned within the Arm of the at a distance of about 2.5 kpc, the provides broader insights into the evolution of H II regions and feedback processes in active star-forming environments. The expansion of its shell, driven by the star's balancing against photoevaporative flows from embedded knots, illustrates how single massive stars disrupt and reorganize nearby molecular clouds, influencing the overall dynamics of galactic spiral arms like . This feedback mechanism transfers kinetic energy into the , sustaining its hot phase and altering the conditions for subsequent across the region. The Bubble Nebula's configuration underscores the significance of O-type stars as regulators of rates in molecular clouds, as BD+60°2522's outflows sweep up and ionize ambient material, potentially suppressing or triggering new stellar births by controlling gas density and availability. Recent modeling estimates the central star's mass at 27 ± 7 M⊙, indicating a relatively young evolutionary stage; the system offers a natural laboratory for studying supernova precursors, revealing how pre-explosion mass loss shapes the circumstellar environment and eventual remnant.

References

  1. https://science.nasa.gov/asset/hubble/bubble-nebula-ngc-7635/
  2. https://academic.oup.com/mnras/article/495/3/3041/5821283
  3. https://noirlab.edu/public/images/noao-bubble/
  4. https://simbad.cds.unistra.fr/simbad/sim-id?Ident=NGC+7635
  5. https://science.nasa.gov/mission/hubble/science/explore-the-night-sky/hubble-caldwell-catalog/caldwell-11/
  6. https://adsabs.harvard.edu/full/2010JRASC.104...23G
  7. https://esahubble.org/images/heic1608a/
  8. https://noirlab.edu/public/images/noao0702a/
  9. https://www.deepskycorner.ch/obj/ngc7635.en.php
  10. https://www.rmg.co.uk/collections/objects/rmgc-object-11122
  11. https://cseligman.com/text/atlas/ngc76.htm
  12. https://www.go-astronomy.com/herschel-object.php?h=2475
  13. https://www.constellation-guide.com/bubble-nebula-ngc-7635/
  14. https://ui.adsabs.harvard.edu/abs/1982MNRAS.201..429T/abstract
  15. https://esahubble.org/news/heic1608/
  16. https://arxiv.org/pdf/2204.11913
  17. https://adsabs.harvard.edu/full/1983ApJ...274..650L
  18. https://arxiv.org/pdf/1003.2567
  19. https://arxiv.org/abs/2003.06371
  20. https://simbad.cds.unistra.fr/simbad/sim-id?Ident=SAO+20575
  21. https://ui.adsabs.harvard.edu/abs/2012BKAS...37Q..79L/abstract
  22. https://www.researchgate.net/publication/310897889_Evolution_effect_of_BD602522_to_Bubble_Nebula_NGC_7635
  23. https://www.aanda.org/articles/aa/full_html/2019/05/aa34832-18/aa34832-18.html
  24. https://academic.oup.com/mnras/article/201/2/429/1024265
  25. https://iopscience.iop.org/article/10.1086/344596
  26. https://www.astronomy.com/observing/101-must-see-cosmic-objects-the-bubble-nebula/
  27. https://www.astrobackyard.com/ngc-7635-the-bubble-nebula/
  28. https://doi.org/10.1093/mnras/staa752
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