Stories about nebulae

[klimkovsky]

Hello! I warmly greet all forum participants and would like to briefly introduce myself.

My name is Andrey Klimkovsky. I am a musician, though I once studied to become an astronomer—a path I didn’t ultimately pursue. However, my passion for the cosmos has inspired me to write a lot of music about stars, distant worlds, and mysterious life still unknown to science. Alongside my musical endeavors, I regularly write educational articles on astronomy, striving to be accurate and adhere to strict scientific principles. That said, I occasionally let my imagination run free, but I always warn readers in advance (if I don’t forget)! I’ve created several series of stories about various celestial bodies and space objects. For a long time, I shared them on my personal blog, and now I’ve decided to bring these stories here. Honestly, I’m not sure why I didn’t think of this sooner.

That’s enough about me. I’ll now dive into stories about nebulae—both the well-known favorites of astronomy enthusiasts and the lesser-known ones. I hope you’ll find them interesting!

 

[klimkovsky]

Carina Nebula​

The term "Carina Nebula" is sometimes translated as "Nebula of Carina," evoking the image of a beautiful female name. However, this is a misinterpretation. "Carina" is Latin for "keel," referring to the keel of a ship—not just any ship, but the Argo, depicted on ancient star maps. Over time, the Argo constellation was divided into several modern constellations: Carina, Puppis, Vela, and Pyxis (Compass). The stars of the Argo are invisible from mid-northern latitudes. Even in the best seasons (winter and spring), Carina, Puppis, and Vela remain below the horizon. They can be observed from the northern tropics and farther south. However, in ancient times, when Greek astronomers imagined the Argo in the sky, the Earth's rotational axis was positioned differently due to precession. This allowed the Argo to be visible from Mediterranean shores. Precession, a gradual shift in the Earth's axis, completes a full cycle every 26,000 years. Over three millennia, the stars of the Argo gradually disappeared from the northern sky.

Carina is the southernmost constellation in this group. When Renaissance astronomers studied the heavens, they could not observe this remarkable nebula until the Age of Great Geographical Discoveries brought explorers to the Southern Hemisphere. The Carina Nebula was discovered in 1752 by Nicolas-Louis de Lacaille, a French astronomer, surveyor, and abbot, from the Cape of Good Hope at the southern tip of Africa.

The Carina Nebula is one of the brightest nebulae in the sky, possibly the brightest. Its integrated brightness is equivalent to a first-magnitude star, outshining the Andromeda Galaxy (formerly known as the Andromeda Nebula), the Orion Nebula, and even the Pleiades star cluster. Remarkably, the Carina Nebula lies approximately 8,500 light-years away—six times farther than the Orion Nebula. How does it achieve such brilliance?

The gas within the nebula, primarily hydrogen, does not glow on its own. It is energized by stars born within the nebula from the same gas. The Carina Nebula hosts numerous supermassive, extremely hot stars. Their ultraviolet radiation excites hydrogen atoms, ionizing them by breaking the bond between the proton and electron. In this process, the original photon is absorbed, and two lower-energy photons are emitted, contributing to the nebula's glow. Over time, a free electron and proton in the ionized gas recombine to form a neutral hydrogen atom, releasing another photon. However, ultraviolet radiation from nearby stars soon re-ionizes the atom, perpetuating the cycle. Thus, emission nebulae like Carina glow as long as bright, hot stars illuminate them. The Carina Nebula is particularly radiant due to its abundance of such stars.

Dust nebulae, by contrast, glow differently. They reflect light that reaches them or absorb light if positioned between an observer and a bright emission nebula, appearing as dark filaments against a luminous background. The Carina Nebula contains dust clouds that create its distinctive "relief" and intricate details, which astronomers have categorized into smaller regions: the Keyhole, the Defiant Finger, the Homunculus, and Mystic Mountain, among others. The nebula spans more than 4 square degrees in the sky—equivalent to 25 full Moon disks—and extends over 500 light-years in space. Throughout this vast region, new giant stars are born, and several bright, multi-star open clusters reside within it.

The most remarkable star in this region is Eta Carinae, a hypergiant. In astronomy, the brightest and most massive stars are called supergiants, but for Eta Carinae, even "super" is an understatement. Compared to other supergiants, it is unparalleled, with a mass 150 times that of the Sun and a luminosity 4 million times greater. Previously, astronomers believed such stars could not exist. However, several hypergiants have now been identified. These stars have short lifespans, rapidly burning out and culminating in a supernova. Eta Carinae is nearing the end of its life, with a supernova expected within the next few hundred thousand years.

The Carina Nebula is a favorite subject for astrophotographers, with countless stunning images available online. One of the finest amateur photographs was recently captured by Australian astronomy enthusiast Dylan O'Donnell. The video illustration for this article is based on his astrophotograph, accompanied by my music from the album «Asteroid Belt». While not directly inspired by the nebula, the track complements the visual imagery beautifully.

Original image​

 

[klimkovsky]

Rosette Nebula​

The large but sparsely populated constellation Monoceros, barely visible to the naked eye, can take pride in hosting an extraordinary treasure: the Rosette Nebula. Monoceros is a relatively recent addition to the star map. Lacking bright stars, astronomers of the pre-telescope era deemed this region unworthy of a constellation. After all, how could a constellation exist without luminous stars? A few 4th-magnitude stars hardly suffice to form a recognizable figure. Consequently, old star maps depicted nothing within the Winter Triangle — formed by Betelgeuse, Sirius, and Procyon (between the constellations Orion, Canis Major, and Canis Minor. Only with the telescope’s invention did it become clear that this region contained notable objects, necessitating a name. Johannes Hevelius, creator of a stunning star atlas, coined the name in the early 18th century. Thus, astronomers gradually accepted a mythical, horse-like beast with a sharp horn — located where the third eye might be — among the winter constellations.

Through this nearly starless constellation runs the broadest and brightest part of the winter Milky Way. Where the Milky Way flows, fascinating objects abound: open star clusters (plentiful in Monoceros), double and multiple stars, variable stars, and, of course, nebulae. Nebulae become visible only when illuminated by bright, hot stars with intense ultraviolet radiation. The Rosette Nebula owes its visibility to the young, hot open star cluster NGC 2244, nestled within a vast, dense hydrogen cloud. This cluster, also known as the “Satellite Cluster,” likely formed from this cloud about 5 million years ago.

The cluster boasts several Class O giant stars, each with a mass 50–60 times that of the Sun and a luminosity 500,000 times greater — an almost unimaginable power. These stars generate a stellar wind so intense that it ionizes the surrounding hydrogen clouds, causing them to glow and rapidly disperse, heating to 6 million degrees Kelvin. This accounts for the Rosette Nebula’s concentric shape, somewhat resembling a planetary nebula, with similar expansive dynamics. However, its scale and nature differ fundamentally. Planetary nebulae are the shed layers of dying stars, whereas the Rosette is a stellar nursery. Star formation is particularly active where the shockwave of escaping gases meets dormant hydrogen clouds, creating dense regions that collapse under gravity to form new stars. The visible Rosette Nebula is merely a portion of a larger hydrogen cloud, heated by blue giants and stretching along this arm of the Milky Way.

The visible portion of the Rosette Nebula lies 5,000 light-years from Earth, with a diameter of approximately 150 light-years. Dense hydrogen clouds extend far beyond its central region. The glowing material, vividly captured in colorful astrophotographs, has a mass equivalent to about 10,000 Suns, capable of birthing a similar number of stars for our Galaxy.

Despite its beauty and photogenic allure, the Rosette Nebula is challenging to observe visually. Astronomers discovered it piecemeal, with its fragments cataloged separately in the New General Catalogue as NGC 2237, NGC 2238, NGC 2239, and others. No one has likely seen through a telescope this nebula with the vivid details revealed in photographs, including those by amateurs. The nebula’s integrated stellar magnitude is only 9m — relatively faint — and its light is spread across an area of 1.5 x 1 degree, equivalent to six lunar disks. This vast expanse may not fit within a telescope’s field of view. Astrophotographers capture the Rosette by accumulating its light over hours or days, using narrow-band filters to isolate emissions from specific elements. As hydrogen dominates there, the nebula’s natural color is red. However, using filters for oxygen (present in smaller amounts) renders it in turquoise hues.

The astrophotograph inspiring the video illustration for this article was captured by Australian amateur astronomer Dylan O’Donnell, using filters highlighting hydrogen, oxygen, and sulfur emissions.

Musical accompaniment: The album «Asteroid Belt».

Original Image​

 

[klimkovsky]

Horsehead Nebula​

The whimsical image of a chess knight in profile among the stars is perhaps the most recognizable among deep space objects. It can be said that the Horsehead Nebula tops the recognition rankings among nebulae and galaxies. Perhaps the Andromeda and Orion Nebulae resonate more with the general public, but only specialists and advanced amateurs know what they look like. Even among them, there are often cases when the famous Andromeda Galaxy is confused with another galaxy, even by experienced popularizers of astronomy. The Orion Nebula, too, can look different in pictures taken with various filters. Yet, the profile of the chess knight allows every inhabitant of Earth to recognize that in front of them is the one-of-a-kind and completely unique Horsehead Nebula.

Let's begin by noting that when we talk about the Horsehead Nebula, we refer to two fundamentally different formations in this region of our Galaxy. Only together do they create this memorable visual image. Moreover, what we see—the glowing diffuse background—is not the Horsehead Nebula. It is a dark silhouette against a light background—a bizarrely shaped dust cloud opaque to the visible radiation of stars and nebulae. If there were no relatively bright emission nebula behind it, we might not even know about any dark gas-dust cosmic horse.

The background for the recognizable horse profile is created by the hydrogen nebula IC 434, discovered by William Herschel in the late 18th century. However, Herschel did not notice any amusing details in the outline of this nebula, although he was an excellent observer—much more keen-sighted and attentive than most of his followers. There are also objective reasons for this—telescopes in Herschel's era were imperfect, and their dark metal mirrors lost from 50% to 80% of the light that entered them.

A hundred years later, the dark silhouette of the Horsehead was discovered on a photographic plate made at the Harvard College Observatory by Williamina Fleming—a woman of unique destiny and one of the brightest personalities in astronomy. Without having a special education, she did a lot in astronomy that immortalized her name. The discovery of the Horsehead is perhaps a curious episode in her scientific biography, rather than something serious. After all, Williamina created the very first system of classifying stellar spectra and personally examined more than 10,000 stars within the framework of this system, creating a method of data processing and manual calculations in astronomy so effective that it worked faster than the first computers (however, she did not live to see them and died quite early—unable to cope with pneumonia).

Williamina Paton Stevens Fleming — pioneering Scottish astronomer​

Williamina discovered dozens of new nebulae, but the publication of these discoveries was done by her scientific adviser, William Henry Pickering, who did not even mention his colleague's name. The irony of the situation developed in such a way that John Ludwig Dreyer described the new nebula in his catalog without indicating the initials of the formal discoverer—he indicated only the surname—Pickering, which gave rise to confusion, and the discovery began to be attributed to William Henry's brother—Edward Charles Pickering—also a famous astronomer of the 19th-20th centuries.

Against the backdrop of the Horsehead Nebula, Edward Emerson Barnard managed to shine, including it in his catalog under number 33. But the name of the discoverer, Williamina Fleming, was not listed there either.

If it were not for the enormous resonance that photographs of the nebula began to cause in the press, and the growing interest in the details around this universal (but first of all, cultural) phenomenon, the name of Williamina Fleming would have remained in the shadows. But journalists raced to find new secrets around the nebula, were interested in who exactly discovered this outlandish horse's head in space, and got to the bottom of the truth—the name of the discoverer became known to the World.

It must be said that for astronomers, the resemblance to a horse did not make the nebula more attractive. But for the public far from science, this turned out to be the main trigger for activating attention—just like the illusory face of the Sphinx on Mars or other artifacts that do not need a scientific explanation, the essence of which lies only in a fleeting external resemblance.

Nevertheless, the Horsehead Nebula still looks at us from every book on astronomy, from every scientific or pseudo-scientific website more than a century later. And the culprit for all this is simply a cloud of light-absorbing dark cosmic dust, covering part of the light nebula located slightly behind.

All together—both the light and dark parts of the Horsehead image—constitute a fragment of a massive nebula complex in the constellation Orion, which includes many other nebulae: the Great and Small Orion Nebulae, and the Flame Nebula (which is literally adjacent to the Horsehead). It is believed that the distance to all these nebulae is approximately the same—about 1,200 to 1,500 light years. While distance estimates vary, it is difficult to accurately determine the distance to objects that lack clear boundaries. Nebulae are visible only to the extent that they are illuminated by other stars (as in reflection nebulae, such as the Flame Nebula), or to the extent that the ultraviolet radiation from nearby stars is strong enough to ionize the hydrogen within these nebulae. Only for dark dust nebulae, which have clear outlines (visible against the background of light nebulae), is there some specificity in terms of size and boundaries. However, even these estimates are conditional, as they are based on data from a more distant light nebula, and this data can be quite approximate.

Given all of the above, it remains unclear how much closer the dark silhouette of the Horsehead Nebula is compared to the emission nebula IC 434. The distance difference could range from 30 to 300 light years.

According to various rough estimates, the size of the dark cloud is about 4 light years. However, this refers to the size of the “head” of the nebula, not the entire dust cloud, which extends in various directions beneath the emission nebula IC 434, at distances tens of times greater. (Astronomers still do not know for sure whether this is one large dust cloud, or several that simply overlap each other when observed from Earth.)

In any case, we are dealing with a vast reservoir of material that could form planets and third-generation stars. Several thousand stars could form from the hydrogen clouds in the Orion complex. However, a wide range of chemical elements is necessary to form planets. All of these elements are found in dust nebulae. In the Horsehead Nebula, many heavy chemical elements have been discovered, as well as a significant variety of chemical compounds, including organic ones. In fact, the Universe is synthesizing substances in interstellar space that will later participate in the emergence of life. Ultraviolet radiation, which is destructive to all living things, acts as an effective catalyst for many important chemical reactions that are crucial for the origin of life. The only remaining step is to form planets where the substances already produced by the cosmic environment can give rise to life.

Interestingly, it was in the "neck" area of this cosmic horse that astronomers discovered the active formation of small-mass stars, comparable to our Sun. These stars are now considered the most likely candidates for hosting planetary systems that could support life.

The Horsehead Nebula is extremely popular among astronomy enthusiasts. Taking a photo of this nebula with modern amateur equipment is not difficult—almost every novice astrophotographer tries this as their first target. However, only a few are able to detect the nebula visually—extreme observers who have developed their night vision adaptation to far beyond the average human capacity. The difficulties in such observations are compounded by two closely located bright stars in Orion’s belt: Zeta Orionis (Alnitak) and Sigma Orionis (an extremely interesting multiple star, known since ancient times but curiously not given its own name). These stars can “blind” the observer, preventing them from seeing the faint glow of the emission nebula IC 434 and the dark silhouette of the Horsehead against its background.

Interestingly, in the infrared spectrum—studied by the James Webb Space Telescope—the silhouette of the Horsehead appears bright. This is because interstellar dust, heated to only a few degrees Kelvin, begins to re-radiate the energy received from stars in the form of thermal radiation.

Astronomers have used NASA's Hubble Space Telescope to photograph the iconic Horsehead Nebula in a new infrared light​

Stellar winds sweeping through the vast Orion nebula over time modify the shape of the dust nebulae, eventually leading to their complete dissipation (except for the material that will form dense protoplanetary disks). However, it is these stellar winds that create density waves that push dust particles together, ultimately forming rocky planets. Our distant descendants will most likely no longer see the whimsical image of a horse’s head in the sky, but they will undoubtedly find something just as captivating.

The video illustration for this article was created based on astrophotography by American astrophotographer Chuck Ayoub.

A music track from my album «Oort Cloud» was used in the video.