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List of NGC objects
List of NGC objects
List of NGC objects
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The following is a list of NGC objects, that is objects listed in the New General Catalogue (NGC). It is one of the largest comprehensive astronomical catalogues for deep sky objects such as star clusters, nebulae, and galaxies.

Stars

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Main article: List of stars in the New General Catalogue

Some objects originally thought to be deep sky objects and listed in the NGC have been subsequently shown to be ordinary stars, so their inclusion in the catalog is now considered erroneous.[1] This list of stars is based on the "NGC 2000.0" version of the catalog, which lists the stars in its errata,[1] supplemented with data on each individual star from the VizieR database.[2][full citation needed]

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

List of NGC objects

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The (NGC) is an astronomical catalogue comprising 7,840 deep-sky objects, including galaxies, nebulae, star clusters, and other non-stellar phenomena, compiled by Danish-Irish astronomer John Louis Emil Dreyer and published in 1888. This catalogue, formally titled A New General Catalogue of Nebulae and Clusters of Stars, systematically enumerates these objects with their celestial coordinates, magnitudes, sizes, and brief descriptions, serving as a foundational reference for . The list of NGC objects represents the complete inventory from Dreyer's original work, excluding later supplements like the Index Catalogues (IC), and remains widely used for identifying and studying extragalactic and galactic features visible primarily with telescopes. Dreyer, who served as assistant to Lord Rosse at Parsonstown Observatory, undertook the compilation to update and consolidate earlier nebular catalogues, drawing heavily on the observations of (1738–1822), his son (1792–1871), and contemporaries like Lord Rosse (1800–1867). The NGC expanded upon John Herschel's General Catalogue of Nebulae and Clusters (1864), which itself built on William Herschel's foundational sweeps of the sky in the late , incorporating over 5,000 objects while adding thousands more from 19th-century surveys. Objects in the catalogue are assigned sequential NGC numbers from 1 to 7,840, ordered roughly by , though the list includes some duplicates, errors, and misidentifications due to the era's observational limitations—issues later addressed in revisions like the Revised New General Catalogue (RNGC) of 1973. The NGC's enduring significance lies in its role as a bridge between early visual astronomy and modern , enabling the cross-referencing of objects in databases such as the (SDSS), where over 590 NGC entries have been spectroscopically analyzed. Notable examples include the (NGC 224), the (NGC 1976), and the (NGC 5194), which highlight the catalogue's coverage of iconic deep-sky targets accessible to amateur and professional astronomers alike. While subsequent catalogues like the Messier (1781) focus on brighter objects, the NGC provides a broader, more systematic enumeration, influencing contemporary tools for object classification and research into cosmic structures.

Background

Catalogue Overview

The (NGC) is an astronomical catalogue that compiles 7,840 deep-sky objects, observed using telescopes available in the 18th and 19th centuries from locations in both the Northern and Southern Hemispheres. Key statistics on its composition reveal approximately 76% galaxies, 3% nebulae, 6% star clusters, 8% or other stellar phenomena, and 7% unclassified or errors, reflecting a broad range of non-stellar astronomical entities beyond the Solar System; note that many objects originally described as nebulae have since been identified as galaxies through 20th-century observations. Compiled by Danish-Irish astronomer John Louis Emil Dreyer, the NGC was published in 1888 in the Memoirs of the Royal Astronomical Society, synthesizing observations from earlier surveys, including those by and other contributors. In contrast to predecessor catalogues like Charles Messier's 1781 list of 110 brighter, more prominent objects intended to avoid confusion during comet searches, the NGC established a more exhaustive and enduring standard reference for deep-sky observations in both amateur and professional astronomy.

Historical Development

The foundations of the (NGC) trace back to the late with the pioneering work of , a German-born British astronomer, who systematically observed and catalogued deep-sky objects using his 6.2-inch reflector telescope at , . In 1786, Herschel published his Catalogue of One Thousand New Nebulae and Clusters of Stars in the Philosophical Transactions of the Royal Society, detailing 1,000 previously unknown non-stellar objects based on sweeps of the conducted between 1783 and 1785. This initial effort marked the first comprehensive attempt to enumerate and describe nebulae and star clusters beyond the handful known from earlier observers like . Building on his father's legacy, John Frederick William Herschel, William's son, extended these observations during his southern hemisphere expedition from 1834 to 1838 using a larger 20-foot reflector at the . In , John published the General Catalogue of Nebulae and Clusters of Stars in the Philosophical Transactions of the Royal Society, expanding the list to 5,000 objects by incorporating his father's northern discoveries with his own southern ones and cross-referencing additional reports from contemporaries. This catalogue organized entries by for the epoch 1860.0 and included detailed positional and descriptive notes, but it still suffered from inconsistencies due to varying observational accuracies and unverified duplicates across sources. The NGC emerged from the efforts of John Louis Emil Dreyer, a Danish-born who served as director of the Armagh Observatory in Ireland from 1882. Tasked by a of the Royal Astronomical in 1878, Dreyer undertook the monumental task of compiling and reconciling observations from approximately 50 distinct sources, spanning over a century of astronomical records. Published in 1888 as A of Nebulae and Clusters of Stars in Volume 49 of the Memoirs of the Royal Astronomical , the NGC consolidated these into 7,840 unique entries, numbered sequentially from NGC 1 to NGC 7840 in order of increasing for the 1860.0. Dreyer addressed key challenges by meticulously resolving duplicates—estimated at up to 20% in prior lists—correcting positional errors through weighted averaging of reliable measurements, and standardizing descriptions while noting historical references and uncertainties. Recognizing ongoing discoveries, Dreyer issued supplements to extend the NGC's coverage. The first, the Index Catalogue of Nebulae Found in the Years 1888 to 1894 (IC I), appeared in 1895 in Volume 51 of the Memoirs of the Royal Astronomical Society and added 1,520 new objects with similar formatting and numbering from IC 1 to IC 1520. This was followed by the Second Index Catalogue of Nebulae and Clusters of Stars (IC II) in 1908, published in Volume 59 of the same series, which incorporated 3,866 additional entries (IC 1521 to IC 5386) based on observations up to 1907. These supplements maintained the NGC's unified approach, providing a foundational reference for deep-sky astronomy that prioritized accuracy over exhaustive listing.

Primary Object Types

Galaxies

The (NGC) encompasses 6,022 galaxies among its 7,840 total entries, representing approximately 77% of the catalog according to the Revised New General Catalogue (RNGC). These objects are almost entirely extragalactic, appearing to 19th-century observers as faint, diffuse patches of light indistinguishable from true nebulae due to the era's telescopic limitations. In J.L.E. Dreyer's compilation, galaxies were cataloged without recognition of their true nature, often described with qualifiers like "extremely faint" (eF), "faint" (F), or "pretty faint" (pF), alongside notes on their small size and irregular shapes. Morphological classifications of NGC galaxies follow adaptations of the , dividing them into ellipticals (E0–E7, characterized by smooth, featureless envelopes of older stars), spirals (Sa–Sd, with central bulges and winding arms of gas, , and young stars), barred spirals (SBa–SBd, featuring a central bar structure channeling material to the nucleus), and irregulars (Irr, lacking defined symmetry and often showing chaotic ). For example, serves as a prototypical edge-on Sb spiral, displaying a prominent dust lane bisecting its disk and a bright central bulge, which highlights the sequence's emphasis on arm tightness and bulge-to-disk ratios. Similarly, NGC 3379 exemplifies an E1 elliptical, with a slightly elongated profile and minimal gas content, typical of early-type galaxies in the catalog. These classifications, refined post-Hubble, reveal the diversity within NGC entries, from smooth ellipticals to structured spirals. Key characteristics of NGC galaxies include apparent visual magnitudes typically ranging from 10 to 14, allowing visibility in moderate amateur telescopes, and low redshifts (z ≲ 0.01) indicating distances generally under 100 Mpc. Their angular sizes span a few to tens of arcminutes, reflecting proximity rather than intrinsic scale. Modern observations with telescopes like Hubble have uncovered active galactic nuclei in objects such as and merger remnants in pairs like NGC 4038/4039, providing insights into evolution beyond static descriptions. NGC galaxies are predominantly distributed in nearby structures such as the , where over 1,300 members (many NGC-designated) form a dense concentration at about 16 Mpc, influencing their observed properties through environmental interactions. The catalog's numerical sequencing, ordered by rather than distance or morphology, results in no systematic correlation between NGC numbers and galactic traits or proximity—early numbers like NGC 1 (in Pisces) may lie far beyond later ones in Virgo. This arrangement reflects the 19th-century survey methodology, prioritizing sky position over physical grouping.

Nebulae

The (NGC) encompasses approximately 241 nebulae, the majority of which are distributed along the disk of the and become visible through mechanisms such as gas or dust-reflected . These objects range in apparent size from a few arcminutes to several degrees across the sky and typically exhibit brightness levels between magnitudes 6 and 12, making many accessible to telescopes under . Often embedded in or adjacent to regions of active , these nebulae provide key insights into dynamics and processes. Nebulae within the NGC are categorized into distinct subtypes based on their emission or absorption characteristics. Emission nebulae, also termed H II regions, represent ionized hydrogen clouds illuminated by ultraviolet radiation from nearby hot O- and B-type stars, resulting in prominent spectral emission lines such as H-alpha; a prominent example is NGC 1976, the , which spans about 1 degree and glows brightly due to excitation from the embedded . Planetary nebulae, such as NGC 6543 (the ), arise from the ejected outer envelopes of low- to intermediate-mass stars in their late evolutionary stages, forming compact, often asymmetric shells ionized by the central remnant, with sizes typically under 1 arcminute and intricate structures revealed in high-resolution imaging. Reflection nebulae, exemplified by NGC 7023 (the Iris Nebula), consist of interstellar dust grains that scatter and reflect visible from embedded or nearby stars, producing a bluish hue without significant intrinsic emission; these structures highlight dust distribution in molecular clouds and can extend over several arcminutes. Dark nebulae manifest as absorption features, where dense dust clouds obscure background starlight, creating silhouettes against brighter emissions or the galactic backdrop; they are integral to star-forming complexes but lack dedicated NGC entries as standalone objects, instead appearing as dark lanes within brighter nebulae like those in the Orion region. In the NGC's historical compilation, the broad designation "" frequently encompassed unresolved distant galaxies, many of which were later reclassified through resolved imaging and , refining our understanding of these interstellar phenomena.

Star Clusters

Star clusters in the New General Catalogue (NGC) represent bound stellar aggregates, distinct from isolated stars or diffuse nebulae, and encompass both open and globular subtypes that provide key insights into galactic structure and stellar evolution. Approximately 788 such clusters are cataloged, including 673 open clusters primarily within the Milky Way's disk and 115 globular clusters distributed in the halo. Open clusters are relatively loose, young groupings typically containing 100 to 1,000 stars, formed from the gravitational collapse of molecular clouds. A representative example is NGC 2264, the Christmas Tree Cluster in Monoceros, which exemplifies these loose associations embedded in regions of recent star formation. In contrast, globular clusters are densely packed, ancient systems harboring 10^5 to 10^6 stars, often exhibiting spherical symmetry and high central concentrations. NGC 104, also known as 47 Tucanae, stands as a prominent globular cluster, showcasing the dense stellar populations characteristic of this subtype. These clusters differ markedly in their physical properties and evolutionary histories. Open clusters generally span ages of 10710^7 to 10910^9 years, with typical diameters of 5 to 20 parsecs, making them vulnerable to disruption by tidal forces from the galactic disk and nearby giant molecular clouds. Globular clusters, however, are far older, with ages exceeding 101010^{10} years, and larger diameters ranging from 50 to 150 parsecs, allowing them to withstand tidal interactions over cosmic timescales due to their deeper gravitational potentials. Open clusters are further classified using the Trumpler system, which denotes density (I for detached, II for not well detached, III for irregular), richness (1 for poor, 2 for moderately rich, 3 for rich), and stellar content (p for poor in bright stars, m for moderately rich, g for rich in bright stars). Historically, many NGC star clusters were first identified by William and in the late , whose observations formed the foundation for John Herschel's General Catalogue and, ultimately, J.L.E. Dreyer's NGC compilation in 1888. These discoveries enabled early mappings of the Milky Way's structure, revealing the distribution of young open clusters tracing spiral arms and ancient globulars outlining the halo.

Secondary Object Types

Stars

The New General Catalogue (NGC) primarily documents non-stellar deep-sky objects, but incorporates a small number of individual that were observed as appearing nebulous or associated with nebulosity or clusters during its compilation in the late . Of the 7,840 NGC entries, approximately 43 are single and 49 are double or multiple . These inclusions occurred because early visual observations with refracting telescopes often produced halos around bright , mimicking the appearance of faint nebulae, or because the were embedded in or illuminating gaseous structures. Only meeting these criteria were catalogued, resulting in their rare representation among the NGC entries, as the catalogue's focus was on extended objects like galaxies, nebulae, and star clusters. The types of stars catalogued in the NGC include bright main-sequence stars with magnitudes less than 6, variable stars, and emission-line stars, spanning spectral classes from hot O and B types—capable of ionizing surrounding material—to cooler carbon-rich giants. Hot O and B stars, for instance, are often associated with emission lines due to their high temperatures (over 10,000 K) and strong ultraviolet radiation, which can excite nearby gas to produce nebular-like glows. Variable stars in the NGC may exhibit pulsations or eruptions that contribute to their nebulous appearance, while carbon stars represent evolved, low-mass giants with atmospheres rich in , sometimes surrounded by circumstellar dust shells. Observational history reveals that many NGC stars were initially misclassified as nebulae due to the limitations of 19th-century instrumentation, such as small-aperture telescopes that could not resolve point sources from diffuse glows. , for example, suspected NGC 771 (50 Cassiopeiae, a magnitude 4.0 A-type ) to be a during his 1831 sweep, but subsequent observations confirmed its stellar nature. Modern reclassifications rely on high-resolution imaging and astrometric data from missions like , which provide precise proper motions and parallaxes to distinguish isolated stars from clustered or extended objects, often revealing distances of hundreds to thousands of light-years and confirming their foreground or field status relative to deeper structures. A notable example is NGC 40, a in Cepheus whose central star is a carbon-rich Wolf-Rayet star of spectral type [WC8], with a surface of about 71,000 and strong emission lines from ionized carbon and oxygen. This star, an evolved post-asymptotic giant branch object, ejects material that forms the nebula's bow-tie shape, explaining its inclusion in the NGC despite the catalogue's emphasis on extended features; its nebulous envelope made it appear as a non-stellar object to early observers like in 1785. Another case is the star powering NGC 2261 (Hubble's Variable Nebula) in , the irregular variable R Monocerotis (spectral type B8e, magnitude varying from 9.5 to 13), a young whose light scatters off surrounding dust, creating variable fan-shaped reflections that led to the NGC entry in 1784 by . These examples highlight how stellar entries in the NGC bridge individual stars and deep-sky phenomena, often involving hot, luminous objects that influence their environments.

Double and Multiple Stars

The New General Catalogue (NGC) includes approximately 100 entries classified as double or multiple stars, primarily those that appeared visually double or were associated with nebulous companions during 19th-century observations, leading to their inclusion among nebulae and clusters. These objects were catalogued if they presented an extended or misty appearance through telescopes of the era, such as NGC 5067 in Virgo, a double star noted for its faint, small components observed by Albert Marth and included by John Louis Emil Dreyer in the NGC (1888). Such entries highlight the catalogue's focus on deep-sky phenomena, where stellar pairs mimicking nebulosity were inadvertently documented alongside true non-stellar objects. Double and multiple stars in the NGC are categorized by observation method and complexity, with visual doubles forming the majority—pairs resolvable by eye or based on angular separation, ranging from a few arcseconds for close systems to several degrees for wide pairs. Spectroscopic binaries, identified through periodic Doppler shifts in lines indicating orbital motion, are less common in the visual NGC but include some entries later confirmed as such; multiple systems encompass triples and higher-order configurations, often with hierarchical orbits. These types emphasize the binary nature of the systems, where gravitational binding distinguishes physical pairs from chance alignments. Key properties of NGC double and multiple stars include orbital periods for visual binaries typically spanning years to centuries, derived from repeated position angle and separation measurements over time. Mass ratios, calculated from Keplerian , reveal insights into , with many systems showing comparable masses indicative of co-formation; physical binaries are confirmed by common , contrasting with optical doubles that lack shared velocity vectors. Evolutionary aspects, such as in close pairs, further underscore their dynamics, though NGC entries often represent wider, stable systems. Historical observations of these stars were pioneered by William and , who employed wire micrometers on their reflectors to measure angular separations and position angles, enabling early detection of orbital changes in over 700 doubles. Modern refinements incorporate techniques, such as speckle and long-baseline methods, which resolve sub-arcsecond separations and refine orbits for precise mass determinations, updating many NGC visual binaries with high-resolution data.

Organization and Revisions

Numerical Sequencing

The (NGC), compiled by John Louis Emil Dreyer and published in 1888, assigns sequential numbers to its 7,840 deep-sky objects based on their order of increasing , using coordinates referenced to the 1860.0 epoch. This positional ordering begins with NGC 1, a in the constellation , and concludes with NGC 7840, an unbarred in Pisces. The scheme integrates data from earlier catalogs, such as those by and his son John, but prioritizes a systematic sweep across the sky starting from the vernal equinox. The numbering exhibits gaps and irregularities, as it lacks fixed increments and reflects the compilation process rather than a uniform progression. Gaps arise from omitted entries, erroneous observations, or objects later deemed non-existent, with approximately 2.3% of NGC entries (about 180 objects) unverified or absent in modern surveys. Duplicates occur when the same object received multiple designations due to independent observations; for example, NGC 3497, NGC 3525, and NGC 3528 all describe the same in , later redesignated as IC 2624 in the supplements. The sequence shows no correlation with an object's , morphological type, or distance, emphasizing its role as a positional index rather than a ranked list. In practice, this numerical sequencing supports efficient identification and lookup in star atlases, observational logs, and digital databases, enabling astronomers to navigate the catalog methodically by number rather than searching by coordinates alone. It also provides a foundation for cross-referencing with the Index Catalogues (IC I and IC II), which extend the NGC with 5,386 additional objects numbered IC 1 through IC 5386 for discoveries made between 1888 and 1908. For locating objects, the original NGC supplies equatorial coordinates ( and ) in the 1860 , but contemporary applications require corrections to align with modern epochs such as J2000.0, ensuring accurate pointing for telescopes and imaging.

Modern Updates and Supplements

Subsequent to the original (NGC), J. L. E. Dreyer published two supplements known as the Index Catalogues (IC I in 1895 and IC II in 1908), which added 1,520 and 3,866 new deep-sky objects, respectively, for a total of 5,386 entries extending the NGC's coverage. These supplements addressed discoveries made after the NGC's 1888 publication, maintaining the same descriptive format while incorporating observations from additional astronomers. In 1988, Roger W. Sinnott compiled NGC 2000.0, a comprehensive modernization of the NGC and IC that converted all positions to the J2000.0 and , improving coordinate precision to approximately 1 arcminute for and 0.1 minutes of time for . This edition also integrated errata and cross-identifications from prior corrections, resulting in a unified list of 13,226 objects without altering the original numbering. The Revised New General Catalogue (RNGC) of 1973, authored by Jack W. Sulentic and William G. Tifft, provided a systematic revision of the NGC by correcting hundreds of positional, descriptive, and identification errors, while updating coordinates to the 1975.0 epoch based on contemporaneous astrometry. This work emphasized nonstellar objects, resolving ambiguities such as misidentified stars and duplicate entries, and served as a foundational reference for subsequent enhancements. Initiated in 1993, the NGC/IC Project involved professional and amateur astronomers in a collaborative effort to verify all entries through historical literature review and modern , leading to extensive corrections including the identification of missing objects and the resolution of duplicates where single astrophysical entities received multiple designations. Building on this, Wolfgang Steinicke's Revised NGC/IC, first released in 2009 and updated as of 2024, incorporates high-resolution data from telescopes like the (HST) and the (SDSS) to refine positions to 0.1 arcminute accuracy or better, reclassify object types (for instance, reidentifying some historical "nebulae" as quasars via spectroscopic analysis), and add 731 previously unlisted objects, yielding a total of 13,957 entries in the unified NGC/IC system. These revisions have significantly reduced errors in the original NGC's positions and identifications due to unverified source data. Contemporary access to the updated catalogues is facilitated through online resources such as the astronomical database, which cross-references NGC/IC data with multi-wavelength observations, and the service, offering queryable tables from Steinicke's and other authoritative compilations.

References

  1. https://www.oxfordreference.com/display/10.1093/oi/authority.20110803100231461
  2. https://skyserver.sdss.org/dr13/en/tools/places/ngc.aspx
  3. https://archive.org/details/newgeneralcatalo00dreyrich
  4. https://heasarc.gsfc.nasa.gov/w3browse/all/ngc2000.html
  5. https://adsabs.harvard.edu/full/1965ASPL....9..289L
  6. https://ned.ipac.caltech.edu/level5/March02/Nilson/Nilson6.html
  7. https://astronomy.swin.edu.au/cosmos/N/NGC
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  9. https://heasarc.gsfc.nasa.gov/W3Browse/all/ngc2000.html
  10. https://spider.seds.org/ngc/ngc.html
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  23. http://stars.astro.illinois.edu/sow/n6543.html
  24. https://www.nasa.gov/image-article/reflection-nebula/
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  26. https://history.aip.org/exhibits/cosmology/ideas/nebulae-classification.htm
  27. https://science.nasa.gov/universe/star-clusters-inside-the-universes-stellar-collections/
  28. https://astrophysicsspectator.org/topics/milkyway/OpenClusters.html
  29. https://courses.ems.psu.edu/astro801/content/l7_p5.html
  30. https://www.astronomy.com/observing/an-ngc-primer/
  31. http://spider.seds.org/ngc/ngc.cgi?771
  32. https://www.aanda.org/articles/aa/full_html/2018/01/aa32188-17/aa32188-17.html
  33. https://science.nasa.gov/asset/hubble/hubbles-variable-nebula-ngc-2261/
  34. http://spider.seds.org/ngc/ngc.cgi?CatalogNumber=5067
  35. https://www.aanda.org/articles/aa/full_html/2020/10/aa39138-20/aa39138-20.html
  36. https://www.opticalmechanics.com/double-stars-science-orbits-and-observing-guide/
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  40. http://ui.adsabs.harvard.edu/abs/1997yCat.7118....0S/abstract
  41. http://ui.adsabs.harvard.edu/abs/1999yCat.7001....0S/abstract
  42. https://ntrs.nasa.gov/api/citations/19830011383/downloads/19830011383.pdf
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  44. https://www.webbdeepsky.com/news/
  45. https://vizier.cds.unistra.fr/viz-bin/VizieR
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