fbpx
Wikipedia

Interstellar medium

January 08, 2023

In astronomy, the interstellar medium is the matter and radiation that exist in the space between the star systems in a galaxy. This matter includes gas in ionic, atomic, and molecular form, as well as dust and cosmic rays. It fills interstellar space and blends smoothly into the surrounding intergalactic space. The energy that occupies the same volume, in the form of electromagnetic radiation, is the interstellar radiation field.

The distribution of ionized hydrogen (known by astronomers as H II from old spectroscopic terminology) in the parts of the Galactic interstellar medium visible from the Earth's northern hemisphere as observed with the Wisconsin Hα Mapper (Haffner et al. 2003).

The interstellar medium is composed of multiple phases distinguished by whether matter is ionic, atomic, or molecular, and the temperature and density of the matter. The interstellar medium is composed, primarily, of hydrogen, followed by helium with trace amounts of carbon, oxygen, and nitrogen.[1] The thermal pressures of these phases are in rough equilibrium with one another. Magnetic fields and turbulent motions also provide pressure in the ISM, and are typically more important, dynamically, than the thermal pressure is. In the interstellar medium, matter is primarily in molecular form, and reaches number densities of 106 molecules per cm3 (1 million molecules per cm3). In hot, diffuse regions of the ISM, matter is primarily ionized, and the density may be as low as 10−4 ions per cm3. Compare this with a number density of roughly 1019 molecules per cm3 for air at sea level, and 1010 molecules per cm3 (10 billion molecules per cm3) for a laboratory high-vacuum chamber. By mass, 99% of the ISM is gas in any form, and 1% is dust.[2] Of the gas in the ISM, by number 91% of atoms are hydrogen and 8.9% are helium, with 0.1% being atoms of elements heavier than hydrogen or helium,[3] known as "metals" in astronomical parlance. By mass this amounts to 70% hydrogen, 28% helium, and 1.5% heavier elements. The hydrogen and helium are primarily a result of primordial nucleosynthesis, while the heavier elements in the ISM are mostly a result of enrichment (due to stellar gravity and radiation pressure) in the process of stellar evolution.

The ISM plays a crucial role in astrophysics precisely because of its intermediate role between stellar and galactic scales. Stars form within the densest regions of the ISM, which ultimately contributes to molecular clouds and replenishes the ISM with matter and energy through planetary nebulae, stellar winds, and supernovae. This interplay between stars and the ISM helps determine the rate at which a galaxy depletes its gaseous content, and therefore its lifespan of active star formation.

Voyager 1 reached the ISM on August 25, 2012, making it the first artificial object from Earth to do so. Interstellar plasma and dust will be studied until the estimated mission end date of 2025. Its twin Voyager 2 entered the ISM on November 5, 2018.[4]

Voyager 1 is the first artificial object to reach the interstellar medium.

Interstellar matter

Table 1 shows a breakdown of the properties of the components of the ISM of the Milky Way.

Table 1: Components of the interstellar medium[3]
Component Fractional
volume		 Scale height
(pc)		 Temperature
(K)		 Density
(particles/cm3)		 State of hydrogen Primary observational techniques
Molecular clouds < 1% 80 10–20 102–106 molecular Radio and infrared molecular emission and absorption lines
Cold neutral medium (CNM) 1–5% 100–300 50–100 20–50 neutral atomic H I 21 cm line absorption
Warm neutral medium (WNM) 10–20% 300–400 6000–10000 0.2–0.5 neutral atomic H I 21 cm line emission
Warm ionized medium (WIM) 20–50% 1000 8000 0.2–0.5 ionized emission and pulsar dispersion
H II regions < 1% 70 8000 102–104 ionized emission and pulsar dispersion
Coronal gas
Hot ionized medium (HIM)		 30–70% 1000–3000 106–107 10−4–10−2 ionized
(metals also highly ionized)		 X-ray emission; absorption lines of highly ionized metals, primarily in the ultraviolet

The three-phase model

Field, Goldsmith & Habing (1969) put forward the static two phase equilibrium model to explain the observed properties of the ISM. Their modeled ISM included of a cold dense phase (T < 300 K), consisting of clouds of neutral and molecular hydrogen, and a warm intercloud phase (T ~ 104 K), consisting of rarefied neutral and ionized gas. McKee & Ostriker (1977) added a dynamic third phase that represented the very hot (T ~ 106 K) gas that had been shock heated by supernovae and constituted most of the volume of the ISM. These phases are the temperatures where heating and cooling can reach a stable equilibrium. Their paper formed the basis for further study over the subsequent three decades. However, the relative proportions of the phases and their subdivisions are still not well understood.[3]

The atomic hydrogen model

This model takes into account only atomic hydrogen: A temperature higher than 3000 K breaks molecules, while that lower than 50000 K leaves atoms in their ground state. It is assumed that the influence of other atoms (He ...) is negligible. The pressure is assumed to be very low, so the durations of the free paths of atoms are longer than the ~ 1 nanosecond duration of the light pulses that constitute ordinary, temporally incoherent light.

In this collisionless gas, Einstein's theory of coherent light-matter interactions applies: all the gas-light interactions are spatially coherent. Suppose that a monochromatic light is pulsed, then scattered by molecules with a quadrupole (Raman) resonance frequency. If the “length of light pulses is shorter than all involved time constants” (Lamb (1971)), an “impulsive stimulated Raman scattering (ISRS)” (Yan, Gamble & Nelson (1985)) applies: the light generated by incoherent Raman scattering at a shifted frequency has a phase independent of the phase of the exciting light, thus generating a new spectral line, and coherence between the incident and scattered light facilitates their interference into a single frequency, thus shifting the incident frequency. Assume that a star radiates a continuous light spectrum up to X-rays. Lyman frequencies are absorbed in this light and pump atoms mainly to the first excited state. In this state, the hyperfine periods are longer than 1 ns, so an ISRS “may” redshift the light frequency, populating high hyperfine levels. Another ISRS “may” transfer energy from hyperfine levels to thermal electromagnetic waves, so the redshift is permanent. The temperature of a light beam is defined by its frequency and spectral radiance with Planck's formula. As entropy must increase, “may” becomes “does”. However, where a previously absorbed line (first Lyman beta, ...) reaches the Lyman alpha frequency, the redshifting process stops, and all hydrogen lines are strongly absorbed. But this stop is not perfect if there is energy at the frequency shifted to Lyman beta frequency, which produces a slow redshift. Successive redshifts separated by Lyman absorptions generate many absorption lines, frequencies of which, deduced from absorption process, obey a law more dependable than Karlsson's formula.

The previous process excites more and more atoms because a de-excitation obeys Einstein's law of coherent interactions: Variation dI of radiance I of a light beam along a path dx is dI=BIdx, where B is Einstein amplification coefficient which depends on medium. I is the modulus of Poynting vector of field, absorption occurs for an opposed vector, which corresponds to a change of sign of B. Factor I in this formula shows that intense rays are more amplified than weak ones (competition of modes). Emission of a flare requires a sufficient radiance I provided by random zero point field. After emission of a flare, weak B increases by pumping while I remains close to zero: De-excitation by a coherent emission involves stochastic parameters of zero point field, as observed close to quasars (and in polar auroras).

Structures

 
Three-dimensional structure in Pillars of Creation.[5]
 
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 ISM is turbulent and therefore full of structure on all spatial scales. Stars are born deep inside large complexes of molecular clouds, typically a few parsecs in size. During their lives and deaths, stars interact physically with the ISM.

Stellar winds from young clusters of stars (often with giant or supergiant HII regions surrounding them) and shock waves created by supernovae inject enormous amounts of energy into their surroundings, which leads to hypersonic turbulence. The resultant structures – of varying sizes – can be observed, such as stellar wind bubbles and superbubbles of hot gas, seen by X-ray satellite telescopes or turbulent flows observed in radio telescope maps.

The Sun is currently traveling through the Local Interstellar Cloud, a denser region in the low-density Local Bubble.

In October 2020, astronomers reported a significant unexpected increase in density in the space beyond the Solar System as detected by the Voyager 1 and Voyager 2 space probes. According to the researchers, this implies that "the density gradient is a large-scale feature of the VLISM (very local interstellar medium) in the general direction of the heliospheric nose".[6][7]

Interaction with interplanetary medium

Short, narrated video about IBEX's interstellar matter observations.

The interstellar medium begins where the interplanetary medium of the Solar System ends. The solar wind slows to subsonic velocities at the termination shock, 90–100 astronomical units from the Sun. In the region beyond the termination shock, called the heliosheath, interstellar matter interacts with the solar wind. Voyager 1, the farthest human-made object from the Earth (after 1998[8]), crossed the termination shock December 16, 2004 and later entered interstellar space when it crossed the heliopause on August 25, 2012, providing the first direct probe of conditions in the ISM (Stone et al. 2005).

Interstellar extinction

The ISM is also responsible for extinction and reddening, the decreasing light intensity and shift in the dominant observable wavelengths of light from a star. These effects are caused by scattering and absorption of photons and allow the ISM to be observed with the naked eye in a dark sky. The apparent rifts that can be seen in the band of the Milky Way – a uniform disk of stars – are caused by absorption of background starlight by molecular clouds within a few thousand light years from Earth.

Far ultraviolet light is absorbed effectively by the neutral components of the ISM. For example, a typical absorption wavelength of atomic hydrogen lies at about 121.5 nanometers, the Lyman-alpha transition. Therefore, it is nearly impossible to see light emitted at that wavelength from a star farther than a few hundred light years from Earth, because most of it is absorbed during the trip to Earth by intervening neutral hydrogen.

Heating and cooling

The ISM is usually far from thermodynamic equilibrium. Collisions establish a Maxwell–Boltzmann distribution of velocities, and the 'temperature' normally used to describe interstellar gas is the 'kinetic temperature', which describes the temperature at which the particles would have the observed Maxwell–Boltzmann velocity distribution in thermodynamic equilibrium. However, the interstellar radiation field is typically much weaker than a medium in thermodynamic equilibrium; it is most often roughly that of an A star (surface temperature of ~10,000 K) highly diluted. Therefore, bound levels within an atom or molecule in the ISM are rarely populated according to the Boltzmann formula (Spitzer 1978, § 2.4).

Depending on the temperature, density, and ionization state of a portion of the ISM, different heating and cooling mechanisms determine the temperature of the gas.

Heating mechanisms

Heating by low-energy cosmic rays
The first mechanism proposed for heating the ISM was heating by low-energy cosmic rays. Cosmic rays are an efficient heating source able to penetrate in the depths of molecular clouds. Cosmic rays transfer energy to gas through both ionization and excitation and to free electrons through Coulomb interactions. Low-energy cosmic rays (a few MeV) are more important because they are far more numerous than high-energy cosmic rays.
Photoelectric heating by grains
The ultraviolet radiation emitted by hot stars can remove electrons from dust grains. The photon is absorbed by the dust grain, and some of its energy is used to overcome the potential energy barrier and remove the electron from the grain. This potential barrier is due to the binding energy of the electron (the work function) and the charge of the grain. The remainder of the photon's energy gives the ejected electron kinetic energy which heats the gas through collisions with other particles. A typical size distribution of dust grains is n(r) ∝ r−3.5, where r is the radius of the dust particle.[9] Assuming this, the projected grain surface area distribution is πr2n(r) ∝ r−1.5. This indicates that the smallest dust grains dominate this method of heating.[10]
Photoionization
When an electron is freed from an atom (typically from absorption of a UV photon) it carries kinetic energy away of the order Ephoton − Eionization. This heating mechanism dominates in H II regions, but is negligible in the diffuse ISM due to the relative lack of neutral carbon atoms.
X-ray heating
X-rays remove electrons from atoms and ions, and those photoelectrons can provoke secondary ionizations. As the intensity is often low, this heating is only efficient in warm, less dense atomic medium (as the column density is small). For example, in molecular clouds only hard x-rays can penetrate and x-ray heating can be ignored. This is assuming the region is not near an x-ray source such as a supernova remnant.
Chemical heating
Molecular hydrogen (H2) can be formed on the surface of dust grains when two H atoms (which can travel over the grain) meet. This process yields 4.48 eV of energy distributed over the rotational and vibrational modes, kinetic energy of the H2 molecule, as well as heating the dust grain. This kinetic energy, as well as the energy transferred from de-excitation of the hydrogen molecule through collisions, heats the gas.
Grain-gas heating
Collisions at high densities between gas atoms and molecules with dust grains can transfer thermal energy. This is not important in HII regions because UV radiation is more important. It is also less important in diffuse ionized medium due to the low density. In the neutral diffuse medium grains are always colder, but do not effectively cool the gas due to the low densities.

Grain heating by thermal exchange is very important in supernova remnants where densities and temperatures are very high.

Gas heating via grain-gas collisions is dominant deep in giant molecular clouds (especially at high densities). Far infrared radiation penetrates deeply due to the low optical depth. Dust grains are heated via this radiation and can transfer thermal energy during collisions with the gas. A measure of efficiency in the heating is given by the accommodation coefficient:

 
where T is the gas temperature, Td the dust temperature, and T2 the post-collision temperature of the gas atom or molecule. This coefficient was measured by (Burke & Hollenbach 1983) as α = 0.35.
Other heating mechanisms
A variety of macroscopic heating mechanisms are present including:

Cooling mechanisms

Fine structure cooling
The process of fine structure cooling is dominant in most regions of the Interstellar Medium, except regions of hot gas and regions deep in molecular clouds. It occurs most efficiently with abundant atoms having fine structure levels close to the fundamental level such as: C II and O I in the neutral medium and O II, O III, N II, N III, Ne II and Ne III in H II regions. Collisions will excite these atoms to higher levels, and they will eventually de-excite through photon emission, which will carry the energy out of the region.
Cooling by permitted lines
At lower temperatures, more levels than fine structure levels can be populated via collisions. For example, collisional excitation of the n = 2 level of hydrogen will release a Ly-α photon upon de-excitation. In molecular clouds, excitation of rotational lines of CO is important. Once a molecule is excited, it eventually returns to a lower energy state, emitting a photon which can leave the region, cooling the cloud.

Radiowave propagation

 
Atmospheric attenuation in dB/km as a function of frequency over the EHF band. Peaks in absorption at specific frequencies are a problem, due to atmosphere constituents such as water vapor (H2O) and carbon dioxide (CO2).

Radio waves from ≈10 kHz (very low frequency) to ≈300 GHz (extremely high frequency) propagate differently in interstellar space than on the Earth's surface. There are many sources of interference and signal distortion that do not exist on Earth. A great deal of radio astronomy depends on compensating for the different propagation effects to uncover the desired signal.[11][12]

Discoveries

 
The Potsdam Great Refractor, a double telescope with 80cm (31.5") and 50 cm (19.5") lenses inaugurated in 1899, used to discover interstellar calcium in 1904.

In 1864, William Huggins used spectroscopy to determine that a nebula is made of gas.[13] Huggins had a private observatory with an 8-inch telescope, with a lens by Alvin Clark; but it was equipped for spectroscopy which enabled breakthrough observations.[14]

In 1904, one of the discoveries made using the Potsdam Great Refractor telescope was of calcium in the interstellar medium.[15] The astronomer Johannes Frank Hartmann determined from spectrograph observations of the binary star Mintaka in Orion, that there was the element calcium in the intervening space.[15]

Interstellar gas was further confirmed by Slipher in 1909, and then by 1912 interstellar dust was confirmed by Slipher.[16] In this way the overall nature of the interstellar medium was confirmed in a series of discoveries and postulizations of its nature.[16]

In September 2020, evidence was presented of solid-state water in the interstellar medium, and particularly, of water ice mixed with silicate grains in cosmic dust grains.[17]

History of knowledge of interstellar space

 
Herbig–Haro object HH 110 ejects gas through interstellar space.[18]

The nature of the interstellar medium has received the attention of astronomers and scientists over the centuries and understanding of the ISM has developed. However, they first had to acknowledge the basic concept of "interstellar" space. The term appears to have been first used in print by Bacon (1626, § 354–455): "The Interstellar Skie.. hath .. so much Affinity with the Starre, that there is a Rotation of that, as well as of the Starre." Later, natural philosopher Robert Boyle (1674) discussed "The inter-stellar part of heaven, which several of the modern Epicureans would have to be empty."

Before modern electromagnetic theory, early physicists postulated that an invisible luminiferous aether existed as a medium to carry lightwaves. It was assumed that this aether extended into interstellar space, as Patterson (1862) wrote, "this efflux occasions a thrill, or vibratory motion, in the ether which fills the interstellar spaces."

The advent of deep photographic imaging allowed Edward Barnard to produce the first images of dark nebulae silhouetted against the background star field of the galaxy, while the first actual detection of cold diffuse matter in interstellar space was made by Johannes Hartmann in 1904[19] through the use of absorption line spectroscopy. In his historic study of the spectrum and orbit of Delta Orionis, Hartmann observed the light coming from this star and realized that some of this light was being absorbed before it reached the Earth. Hartmann reported that absorption from the "K" line of calcium appeared "extraordinarily weak, but almost perfectly sharp" and also reported the "quite surprising result that the calcium line at 393.4 nanometres does not share in the periodic displacements of the lines caused by the orbital motion of the spectroscopic binary star". The stationary nature of the line led Hartmann to conclude that the gas responsible for the absorption was not present in the atmosphere of Delta Orionis, but was instead located within an isolated cloud of matter residing somewhere along the line-of-sight to this star. This discovery launched the study of the Interstellar Medium.

In the series of investigations, Viktor Ambartsumian introduced the now commonly accepted notion that interstellar matter occurs in the form of clouds.[20]

Following Hartmann's identification of interstellar calcium absorption, interstellar sodium was detected by Heger (1919) through the observation of stationary absorption from the atom's "D" lines at 589.0 and 589.6 nanometres towards Delta Orionis and Beta Scorpii.

Subsequent observations of the "H" and "K" lines of calcium by Beals (1936) revealed double and asymmetric profiles in the spectra of Epsilon and Zeta Orionis. These were the first steps in the study of the very complex interstellar sightline towards Orion. Asymmetric absorption line profiles are the result of the superposition of multiple absorption lines, each corresponding to the same atomic transition (for example the "K" line of calcium), but occurring in interstellar clouds with different radial velocities. Because each cloud has a different velocity (either towards or away from the observer/Earth) the absorption lines occurring within each cloud are either blue-shifted or red-shifted (respectively) from the lines' rest wavelength, through the Doppler Effect. These observations confirming that matter is not distributed homogeneously were the first evidence of multiple discrete clouds within the ISM.

 
This light-year-long knot of interstellar gas and dust resembles a caterpillar.[21]

The growing evidence for interstellar material led Pickering (1912) to comment that "While the interstellar absorbing medium may be simply the ether, yet the character of its selective absorption, as indicated by Kapteyn, is characteristic of a gas, and free gaseous molecules are certainly there, since they are probably constantly being expelled by the Sun and stars."

The same year Victor Hess's discovery of cosmic rays, highly energetic charged particles that rain onto the Earth from space, led others to speculate whether they also pervaded interstellar space. The following year the Norwegian explorer and physicist Kristian Birkeland wrote: "It seems to be a natural consequence of our points of view to assume that the whole of space is filled with electrons and flying electric ions of all kinds. We have assumed that each stellar system in evolutions throws off electric corpuscles into space. It does not seem unreasonable therefore to think that the greater part of the material masses in the universe is found, not in the solar systems or nebulae, but in 'empty' space" (Birkeland 1913).

Thorndike (1930) noted that "it could scarcely have been believed that the enormous gaps between the stars are completely void. Terrestrial aurorae are not improbably excited by charged particles emitted by the Sun. If the millions of other stars are also ejecting ions, as is undoubtedly true, no absolute vacuum can exist within the galaxy."

In September 2012, NASA scientists reported that polycyclic aromatic hydrocarbons (PAHs), subjected to interstellar medium (ISM) conditions, are transformed, through hydrogenation, oxygenation and hydroxylation, to more complex organics – "a step along the path toward amino acids and nucleotides, the raw materials of proteins and DNA, respectively".[22][23] Further, as a result of these transformations, the PAHs lose their spectroscopic signature which could be one of the reasons "for the lack of PAH detection in interstellar ice grains, particularly the outer regions of cold, dense clouds or the upper molecular layers of protoplanetary disks."[22][23]

In February 2014, NASA announced a greatly upgraded database[24] for tracking polycyclic aromatic hydrocarbons (PAHs) in the universe. According to scientists, more than 20% of the carbon in the universe may be associated with PAHs, possible starting materials for the formation of life. PAHs seem to have been formed shortly after the Big Bang, are widespread throughout the universe, and are associated with new stars and exoplanets.[25]

In April 2019, scientists, working with the Hubble Space Telescope, reported the confirmed detection of the large and complex ionized molecules of buckminsterfullerene (C60) (also known as "buckyballs") in the interstellar medium spaces between the stars.[26][27]

See also

References

Citations

  1. ^ Herbst, Eric (1995). "Chemistry in The Interstellar Medium". Annual Review of Physical Chemistry. 46: 27–54. Bibcode:1995ARPC...46...27H. doi:10.1146/annurev.pc.46.100195.000331.
  2. ^ Boulanger, F.; Cox, P.; Jones, A. P. (2000). "Course 7: Dust in the Interstellar Medium". In F. Casoli; J. Lequeux; F. David (eds.). Infrared Space Astronomy, Today and Tomorrow. p. 251. Bibcode:2000isat.conf..251B.
  3. ^ a b c (Ferriere 2001)
  4. ^ Nelson, Jon (2020). . NASA. Archived from the original on 2017-08-25. Retrieved November 29, 2020.
  5. ^ "The Pillars of Creation Revealed in 3D". European Southern Observatory. 30 April 2015. Retrieved 14 June 2015.
  6. ^ Starr, Michelle (19 October 2020). "Voyager Spacecraft Detect an Increase in The Density of Space Outside The Solar System". ScienceAlert. Retrieved 19 October 2020.
  7. ^ Kurth, W.S.; Gurnett, D.A. (25 August 2020). "Observations of a Radial Density Gradient in the Very Local Interstellar Medium by Voyager 2". The Astrophysical Journal Letters. 900 (1): L1. Bibcode:2020ApJ...900L...1K. doi:10.3847/2041-8213/abae58. S2CID 225312823. Retrieved 19 October 2020.
  8. ^ "Voyager: Fast Facts". Jet Propulsion Laboratory.
  9. ^ Mathis, J.S.; Rumpl, W.; Nordsieck, K.H. (1977). "The size distribution of interstellar grains". Astrophysical Journal. 217: 425. Bibcode:1977ApJ...217..425M. doi:10.1086/155591.
  10. ^ Weingartner, J.C.; Draine, B.T. (2001). "Photoelectric Emission from Interstellar Dust: Grain Charging and Gas Heating". Astrophysical Journal Supplement Series. 134 (2): 263–281. arXiv:astro-ph/9907251. Bibcode:2001ApJS..134..263W. doi:10.1086/320852. S2CID 13080988.
  11. ^ Samantha Blair. "Interstellar Medium Interference (video)". SETI Talks. Archived from the original on 2021-11-14.
  12. ^ . JPL. Archived from the original on 2015-07-09.
  13. ^ "The First Planetary Nebula Spectrum". Sky & Telescope. 2014-08-14. Retrieved 2019-11-29.
  14. ^ "William Huggins (1824–1910)". www.messier.seds.org. Retrieved 2019-11-29.
  15. ^ a b Kanipe, Jeff (2011-01-27). The Cosmic Connection: How Astronomical Events Impact Life on Earth. Prometheus Books. ISBN 9781591028826.
  16. ^ a b "V. M. Slipher Papers, 1899-1965".
  17. ^ Potpov, Alexey; et al. (21 September 2020). "Dust/ice mixing in cold regions and solid-state water in the diffuse interstellar medium". Nature Astronomy. 5: 78–85. arXiv:2008.10951. Bibcode:2021NatAs...5...78P. doi:10.1038/s41550-020-01214-x. S2CID 221292937. Retrieved 26 September 2020.
  18. ^ "A geyser of hot gas flowing from a star". ESA/Hubble Press Release. Retrieved 3 July 2012.
  19. ^ Asimov, Isaac, Asimov's Biographical Encyclopedia of Science and Technology (2nd ed.)
  20. ^ S. Chandrasekhar (1989), "To Victor Ambartsumian on his 80th birthday", Journal of Astrophysics and Astronomy, 18 (1): 408–409, Bibcode:1988Ap.....29..408C, doi:10.1007/BF01005852, S2CID 122547053
  21. ^ "Hubble sees a cosmic caterpillar". Image Archive. ESA/Hubble. Retrieved 9 September 2013.
  22. ^ a b NASA Cooks Up Icy Organics to Mimic Life's Origins, Space.com, September 20, 2012, retrieved September 22, 2012
  23. ^ a b Gudipati, Murthy S.; Yang, Rui (September 1, 2012), "In-Situ Probing Of Radiation-Induced Processing Of Organics In Astrophysical Ice Analogs – Novel Laser Desorption Laser Ionization Time-Of-Flight Mass Spectroscopic Studies", The Astrophysical Journal Letters, 756 (1): L24, Bibcode:2012ApJ...756L..24G, doi:10.1088/2041-8205/756/1/L24, S2CID 5541727
  24. ^ "PAH IR Spectroscopic Database". The Astrophysics & Astrochemistry Laboratory. NASA Ames Research Center. Retrieved October 20, 2019.
  25. ^ Hoover, Rachel (February 21, 2014). "Need to Track Organic Nano-Particles Across the Universe? NASA's Got an App for That". NASA. Retrieved February 22, 2014.
  26. ^ Starr, Michelle (29 April 2019). "The Hubble Space Telescope Has Just Found Solid Evidence of Interstellar Buckyballs". ScienceAlert.com. Retrieved 29 April 2019.
  27. ^ Cordiner, M.A.; et al. (22 April 2019). "Confirming Interstellar C60 + Using the Hubble Space Telescope". The Astrophysical Journal Letters. 875 (2): L28. arXiv:1904.08821. Bibcode:2019ApJ...875L..28C. doi:10.3847/2041-8213/ab14e5. S2CID 121292704.

Sources

  • Bacon, Francis (1626), Sylva (3545 ed.)
  • Beals, C. S. (1936), "On the interpretation of interstellar lines", Monthly Notices of the Royal Astronomical Society, 96 (7): 661–678, Bibcode:1936MNRAS..96..661B, doi:10.1093/mnras/96.7.661
  • Birkeland, Kristian (1913), "Polar Magnetic Phenomena and Terrella Experiments", The Norwegian Aurora Polaris Expedition, 1902–03 (section 2), New York: Christiania (now Oslo), H. Aschelhoug & Co., p. 720
  • Boyle, Robert (1674), The Excellency of Theology Compar'd with Natural Philosophy, vol. ii. iv., p. 178
  • Burke, J. R.; Hollenbach, D.J. (1983), "The gas-grain interaction in the interstellar medium – Thermal accommodation and trapping", Astrophysical Journal, 265: 223, Bibcode:1983ApJ...265..223B, doi:10.1086/160667
  • Dyson, J. (1997), Physics of the Interstellar Medium, London: Taylor & Francis
  • Field, G. B.; Goldsmith, D. W.; Habing, H. J. (1969), "Cosmic-Ray Heating of the Interstellar Gas", Astrophysical Journal, 155: L149, Bibcode:1969ApJ...155L.149F, doi:10.1086/180324
  • Ferriere, K. (2001), "The Interstellar Environment of our Galaxy", Reviews of Modern Physics, 73 (4): 1031–1066, arXiv:astro-ph/0106359, Bibcode:2001RvMP...73.1031F, doi:10.1103/RevModPhys.73.1031, S2CID 16232084
  • Haffner, L. M.; Reynolds, R. J.; Tufte, S. L.; Madsen, G. J.; Jaehnig, K. P.; Percival, J. W. (2003), "The Wisconsin Hα Mapper Northern Sky Survey", Astrophysical Journal Supplement, 145 (2): 405, arXiv:astro-ph/0309117, Bibcode:2003ApJS..149..405H, doi:10.1086/378850, S2CID 51746099 The Wisconsin Hα Mapper is funded by the National Science Foundation.
  • Heger, Mary Lea (1919), "Stationary Sodium Lines in Spectroscopic Binaries", Publications of the Astronomical Society of the Pacific, 31 (184): 304, Bibcode:1919PASP...31..304H, doi:10.1086/122890
  • Lamb, G. L. (1971), "Analytical Descriptions of Ultrashort Optical Pulse Propagation in a Resonant Medium", Reviews of Modern Physics, 43 (2): 99–124, Bibcode:1971RvMP...43...99L, doi:10.1103/RevModPhys.43.99
  • Lequeux, James (2005), The Interstellar Medium (PDF), Astronomy and Astrophysics Library, Springer, Bibcode:2005ism..book.....L, doi:10.1007/B137959, ISBN 978-3-540-21326-0, S2CID 118429018
  • McKee, C. F.; Ostriker, J. P. (1977), "A theory of the interstellar medium – Three components regulated by supernova explosions in an inhomogeneous substrate", Astrophysical Journal, 218: 148, Bibcode:1977ApJ...218..148M, doi:10.1086/155667
  • Patterson, Robert Hogarth (1862), "Colour in nature and art", Essays in History and Art, 10. Reprinted from Blackwood's Magazine{{citation}}: CS1 maint: postscript (link)
  • Pickering, W. H. (1912), "The Motion of the Solar System relatively to the Interstellar Absorbing Medium", Monthly Notices of the Royal Astronomical Society, 72 (9): 740–743, Bibcode:1912MNRAS..72..740P, doi:10.1093/mnras/72.9.740
  • Spitzer, L. (1978), Physical Processes in the Interstellar Medium, Wiley, ISBN 978-0-471-29335-4
  • Stone, E. C.; Cummings, A. C.; McDonald, F. B.; Heikkila, B. C.; Lal, N.; Webber, W. R. (2005), "Voyager 1 Explores the Termination Shock Region and the Heliosheath Beyond", Science, 309 (5743): 2017–2020, Bibcode:2005Sci...309.2017S, doi:10.1126/science.1117684, PMID 16179468, S2CID 34517751
  • Thorndike, S. L. (1930), "Interstellar Matter", Publications of the Astronomical Society of the Pacific, 42 (246): 99, Bibcode:1930PASP...42...99T, doi:10.1086/124007
  • Yan, Yong‐Xin; Gamble, Edward B.; Nelson, Keith A. (December 1985). "Impulsive stimulated scattering: General importance in femtosecond laser pulse interactions with matter, and spectroscopic applications". The Journal of Chemical Physics. 83 (11): 5391–5399. Bibcode:1985JChPh..83.5391Y. doi:10.1063/1.449708.

External links

 
Wikimedia Commons has media related to Interstellar media.
  • Freeview Video 'Chemistry of Interstellar Space' William Klemperer, Harvard University. A Royal Institution Discourse by the Vega Science Trust.
  • The interstellar medium: an online tutorial

January 08, 2023
interstellar, medium, astronomy, interstellar, medium, matter, radiation, that, exist, space, between, star, systems, galaxy, this, matter, includes, ionic, atomic, molecular, form, well, dust, cosmic, rays, fills, interstellar, space, blends, smoothly, into, . In astronomy the interstellar medium is the matter and radiation that exist in the space between the star systems in a galaxy This matter includes gas in ionic atomic and molecular form as well as dust and cosmic rays It fills interstellar space and blends smoothly into the surrounding intergalactic space The energy that occupies the same volume in the form of electromagnetic radiation is the interstellar radiation field The distribution of ionized hydrogen known by astronomers as H II from old spectroscopic terminology in the parts of the Galactic interstellar medium visible from the Earth s northern hemisphere as observed with the Wisconsin Ha Mapper Haffner et al 2003 The interstellar medium is composed of multiple phases distinguished by whether matter is ionic atomic or molecular and the temperature and density of the matter The interstellar medium is composed primarily of hydrogen followed by helium with trace amounts of carbon oxygen and nitrogen 1 The thermal pressures of these phases are in rough equilibrium with one another Magnetic fields and turbulent motions also provide pressure in the ISM and are typically more important dynamically than the thermal pressure is In the interstellar medium matter is primarily in molecular form and reaches number densities of 106 molecules per cm3 1 million molecules per cm3 In hot diffuse regions of the ISM matter is primarily ionized and the density may be as low as 10 4 ions per cm3 Compare this with a number density of roughly 1019 molecules per cm3 for air at sea level and 1010 molecules per cm3 10 billion molecules per cm3 for a laboratory high vacuum chamber By mass 99 of the ISM is gas in any form and 1 is dust 2 Of the gas in the ISM by number 91 of atoms are hydrogen and 8 9 are helium with 0 1 being atoms of elements heavier than hydrogen or helium 3 known as metals in astronomical parlance By mass this amounts to 70 hydrogen 28 helium and 1 5 heavier elements The hydrogen and helium are primarily a result of primordial nucleosynthesis while the heavier elements in the ISM are mostly a result of enrichment due to stellar gravity and radiation pressure in the process of stellar evolution The ISM plays a crucial role in astrophysics precisely because of its intermediate role between stellar and galactic scales Stars form within the densest regions of the ISM which ultimately contributes to molecular clouds and replenishes the ISM with matter and energy through planetary nebulae stellar winds and supernovae This interplay between stars and the ISM helps determine the rate at which a galaxy depletes its gaseous content and therefore its lifespan of active star formation Voyager 1 reached the ISM on August 25 2012 making it the first artificial object from Earth to do so Interstellar plasma and dust will be studied until the estimated mission end date of 2025 Its twin Voyager 2 entered the ISM on November 5 2018 4 Voyager 1 is the first artificial object to reach the interstellar medium Contents 1 Interstellar matter 1 1 The three phase model 1 2 The atomic hydrogen model 1 3 Structures 1 4 Interaction with interplanetary medium 1 5 Interstellar extinction 2 Heating and cooling 2 1 Heating mechanisms 2 2 Cooling mechanisms 3 Radiowave propagation 4 Discoveries 5 History of knowledge of interstellar space 6 See also 7 References 7 1 Citations 7 2 Sources 8 External linksInterstellar matter EditTable 1 shows a breakdown of the properties of the components of the ISM of the Milky Way Table 1 Components of the interstellar medium 3 Component Fractional volume Scale height pc Temperature K Density particles cm3 State of hydrogen Primary observational techniquesMolecular clouds lt 1 80 10 20 102 106 molecular Radio and infrared molecular emission and absorption linesCold neutral medium CNM 1 5 100 300 50 100 20 50 neutral atomic H I 21 cm line absorptionWarm neutral medium WNM 10 20 300 400 6000 10000 0 2 0 5 neutral atomic H I 21 cm line emissionWarm ionized medium WIM 20 50 1000 8000 0 2 0 5 ionized Ha emission and pulsar dispersionH II regions lt 1 70 8000 102 104 ionized Ha emission and pulsar dispersionCoronal gasHot ionized medium HIM 30 70 1000 3000 106 107 10 4 10 2 ionized metals also highly ionized X ray emission absorption lines of highly ionized metals primarily in the ultravioletThe three phase model Edit Field Goldsmith amp Habing 1969 put forward the static two phase equilibrium model to explain the observed properties of the ISM Their modeled ISM included of a cold dense phase T lt 300 K consisting of clouds of neutral and molecular hydrogen and a warm intercloud phase T 104 K consisting of rarefied neutral and ionized gas McKee amp Ostriker 1977 added a dynamic third phase that represented the very hot T 106 K gas that had been shock heated by supernovae and constituted most of the volume of the ISM These phases are the temperatures where heating and cooling can reach a stable equilibrium Their paper formed the basis for further study over the subsequent three decades However the relative proportions of the phases and their subdivisions are still not well understood 3 The atomic hydrogen model Edit This model takes into account only atomic hydrogen A temperature higher than 3000 K breaks molecules while that lower than 50000 K leaves atoms in their ground state It is assumed that the influence of other atoms He is negligible The pressure is assumed to be very low so the durations of the free paths of atoms are longer than the 1 nanosecond duration of the light pulses that constitute ordinary temporally incoherent light In this collisionless gas Einstein s theory of coherent light matter interactions applies all the gas light interactions are spatially coherent Suppose that a monochromatic light is pulsed then scattered by molecules with a quadrupole Raman resonance frequency If the length of light pulses is shorter than all involved time constants Lamb 1971 an impulsive stimulated Raman scattering ISRS Yan Gamble amp Nelson 1985 applies the light generated by incoherent Raman scattering at a shifted frequency has a phase independent of the phase of the exciting light thus generating a new spectral line and coherence between the incident and scattered light facilitates their interference into a single frequency thus shifting the incident frequency Assume that a star radiates a continuous light spectrum up to X rays Lyman frequencies are absorbed in this light and pump atoms mainly to the first excited state In this state the hyperfine periods are longer than 1 ns so an ISRS may redshift the light frequency populating high hyperfine levels Another ISRS may transfer energy from hyperfine levels to thermal electromagnetic waves so the redshift is permanent The temperature of a light beam is defined by its frequency and spectral radiance with Planck s formula As entropy must increase may becomes does However where a previously absorbed line first Lyman beta reaches the Lyman alpha frequency the redshifting process stops and all hydrogen lines are strongly absorbed But this stop is not perfect if there is energy at the frequency shifted to Lyman beta frequency which produces a slow redshift Successive redshifts separated by Lyman absorptions generate many absorption lines frequencies of which deduced from absorption process obey a law more dependable than Karlsson s formula The previous process excites more and more atoms because a de excitation obeys Einstein s law of coherent interactions Variation dI of radiance I of a light beam along a path dx is dI BIdx where B is Einstein amplification coefficient which depends on medium I is the modulus of Poynting vector of field absorption occurs for an opposed vector which corresponds to a change of sign of B Factor I in this formula shows that intense rays are more amplified than weak ones competition of modes Emission of a flare requires a sufficient radiance I provided by random zero point field After emission of a flare weak B increases by pumping while I remains close to zero De excitation by a coherent emission involves stochastic parameters of zero point field as observed close to quasars and in polar auroras Structures Edit Three dimensional structure in Pillars of Creation 5 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 ISM is turbulent and therefore full of structure on all spatial scales Stars are born deep inside large complexes of molecular clouds typically a few parsecs in size During their lives and deaths stars interact physically with the ISM Stellar winds from young clusters of stars often with giant or supergiant HII regions surrounding them and shock waves created by supernovae inject enormous amounts of energy into their surroundings which leads to hypersonic turbulence The resultant structures of varying sizes can be observed such as stellar wind bubbles and superbubbles of hot gas seen by X ray satellite telescopes or turbulent flows observed in radio telescope maps The Sun is currently traveling through the Local Interstellar Cloud a denser region in the low density Local Bubble In October 2020 astronomers reported a significant unexpected increase in density in the space beyond the Solar System as detected by the Voyager 1 and Voyager 2 space probes According to the researchers this implies that the density gradient is a large scale feature of the VLISM very local interstellar medium in the general direction of the heliospheric nose 6 7 Interaction with interplanetary medium Edit source source source source source source source source source source source source Short narrated video about IBEX s interstellar matter observations The interstellar medium begins where the interplanetary medium of the Solar System ends The solar wind slows to subsonic velocities at the termination shock 90 100 astronomical units from the Sun In the region beyond the termination shock called the heliosheath interstellar matter interacts with the solar wind Voyager 1 the farthest human made object from the Earth after 1998 8 crossed the termination shock December 16 2004 and later entered interstellar space when it crossed the heliopause on August 25 2012 providing the first direct probe of conditions in the ISM Stone et al 2005 Interstellar extinction Edit The ISM is also responsible for extinction and reddening the decreasing light intensity and shift in the dominant observable wavelengths of light from a star These effects are caused by scattering and absorption of photons and allow the ISM to be observed with the naked eye in a dark sky The apparent rifts that can be seen in the band of the Milky Way a uniform disk of stars are caused by absorption of background starlight by molecular clouds within a few thousand light years from Earth Far ultraviolet light is absorbed effectively by the neutral components of the ISM For example a typical absorption wavelength of atomic hydrogen lies at about 121 5 nanometers the Lyman alpha transition Therefore it is nearly impossible to see light emitted at that wavelength from a star farther than a few hundred light years from Earth because most of it is absorbed during the trip to Earth by intervening neutral hydrogen Heating and cooling EditThe ISM is usually far from thermodynamic equilibrium Collisions establish a Maxwell Boltzmann distribution of velocities and the temperature normally used to describe interstellar gas is the kinetic temperature which describes the temperature at which the particles would have the observed Maxwell Boltzmann velocity distribution in thermodynamic equilibrium However the interstellar radiation field is typically much weaker than a medium in thermodynamic equilibrium it is most often roughly that of an A star surface temperature of 10 000 K highly diluted Therefore bound levels within an atom or molecule in the ISM are rarely populated according to the Boltzmann formula Spitzer 1978 2 4 Depending on the temperature density and ionization state of a portion of the ISM different heating and cooling mechanisms determine the temperature of the gas Heating mechanisms Edit Heating by low energy cosmic rays The first mechanism proposed for heating the ISM was heating by low energy cosmic rays Cosmic rays are an efficient heating source able to penetrate in the depths of molecular clouds Cosmic rays transfer energy to gas through both ionization and excitation and to free electrons through Coulomb interactions Low energy cosmic rays a few MeV are more important because they are far more numerous than high energy cosmic rays Photoelectric heating by grains The ultraviolet radiation emitted by hot stars can remove electrons from dust grains The photon is absorbed by the dust grain and some of its energy is used to overcome the potential energy barrier and remove the electron from the grain This potential barrier is due to the binding energy of the electron the work function and the charge of the grain The remainder of the photon s energy gives the ejected electron kinetic energy which heats the gas through collisions with other particles A typical size distribution of dust grains is n r r 3 5 where r is the radius of the dust particle 9 Assuming this the projected grain surface area distribution is pr2n r r 1 5 This indicates that the smallest dust grains dominate this method of heating 10 Photoionization When an electron is freed from an atom typically from absorption of a UV photon it carries kinetic energy away of the order Ephoton Eionization This heating mechanism dominates in H II regions but is negligible in the diffuse ISM due to the relative lack of neutral carbon atoms X ray heating X rays remove electrons from atoms and ions and those photoelectrons can provoke secondary ionizations As the intensity is often low this heating is only efficient in warm less dense atomic medium as the column density is small For example in molecular clouds only hard x rays can penetrate and x ray heating can be ignored This is assuming the region is not near an x ray source such as a supernova remnant Chemical heating Molecular hydrogen H2 can be formed on the surface of dust grains when two H atoms which can travel over the grain meet This process yields 4 48 eV of energy distributed over the rotational and vibrational modes kinetic energy of the H2 molecule as well as heating the dust grain This kinetic energy as well as the energy transferred from de excitation of the hydrogen molecule through collisions heats the gas Grain gas heating Collisions at high densities between gas atoms and molecules with dust grains can transfer thermal energy This is not important in HII regions because UV radiation is more important It is also less important in diffuse ionized medium due to the low density In the neutral diffuse medium grains are always colder but do not effectively cool the gas due to the low densities Grain heating by thermal exchange is very important in supernova remnants where densities and temperatures are very high Gas heating via grain gas collisions is dominant deep in giant molecular clouds especially at high densities Far infrared radiation penetrates deeply due to the low optical depth Dust grains are heated via this radiation and can transfer thermal energy during collisions with the gas A measure of efficiency in the heating is given by the accommodation coefficient a T 2 T T d T displaystyle alpha frac T 2 T T d T where T is the gas temperature Td the dust temperature and T2 the post collision temperature of the gas atom or molecule This coefficient was measured by Burke amp Hollenbach 1983 as a 0 35 Other heating mechanisms A variety of macroscopic heating mechanisms are present including Gravitational collapse of a cloud Supernova explosions Stellar winds Expansion of H II regions Magnetohydrodynamic waves created by supernova remnantsCooling mechanisms Edit Fine structure cooling The process of fine structure cooling is dominant in most regions of the Interstellar Medium except regions of hot gas and regions deep in molecular clouds It occurs most efficiently with abundant atoms having fine structure levels close to the fundamental level such as C II and O I in the neutral medium and O II O III N II N III Ne II and Ne III in H II regions Collisions will excite these atoms to higher levels and they will eventually de excite through photon emission which will carry the energy out of the region Cooling by permitted lines At lower temperatures more levels than fine structure levels can be populated via collisions For example collisional excitation of the n 2 level of hydrogen will release a Ly a photon upon de excitation In molecular clouds excitation of rotational lines of CO is important Once a molecule is excited it eventually returns to a lower energy state emitting a photon which can leave the region cooling the cloud Radiowave propagation Edit Atmospheric attenuation in dB km as a function of frequency over the EHF band Peaks in absorption at specific frequencies are a problem due to atmosphere constituents such as water vapor H2O and carbon dioxide CO2 Radio waves from 10 kHz very low frequency to 300 GHz extremely high frequency propagate differently in interstellar space than on the Earth s surface There are many sources of interference and signal distortion that do not exist on Earth A great deal of radio astronomy depends on compensating for the different propagation effects to uncover the desired signal 11 12 Discoveries Edit The Potsdam Great Refractor a double telescope with 80cm 31 5 and 50 cm 19 5 lenses inaugurated in 1899 used to discover interstellar calcium in 1904 In 1864 William Huggins used spectroscopy to determine that a nebula is made of gas 13 Huggins had a private observatory with an 8 inch telescope with a lens by Alvin Clark but it was equipped for spectroscopy which enabled breakthrough observations 14 In 1904 one of the discoveries made using the Potsdam Great Refractor telescope was of calcium in the interstellar medium 15 The astronomer Johannes Frank Hartmann determined from spectrograph observations of the binary star Mintaka in Orion that there was the element calcium in the intervening space 15 Interstellar gas was further confirmed by Slipher in 1909 and then by 1912 interstellar dust was confirmed by Slipher 16 In this way the overall nature of the interstellar medium was confirmed in a series of discoveries and postulizations of its nature 16 In September 2020 evidence was presented of solid state water in the interstellar medium and particularly of water ice mixed with silicate grains in cosmic dust grains 17 History of knowledge of interstellar space Edit Herbig Haro object HH 110 ejects gas through interstellar space 18 The nature of the interstellar medium has received the attention of astronomers and scientists over the centuries and understanding of the ISM has developed However they first had to acknowledge the basic concept of interstellar space The term appears to have been first used in print by Bacon 1626 354 455 The Interstellar Skie hath so much Affinity with the Starre that there is a Rotation of that as well as of the Starre Later natural philosopher Robert Boyle 1674 discussed The inter stellar part of heaven which several of the modern Epicureans would have to be empty Before modern electromagnetic theory early physicists postulated that an invisible luminiferous aether existed as a medium to carry lightwaves It was assumed that this aether extended into interstellar space as Patterson 1862 wrote this efflux occasions a thrill or vibratory motion in the ether which fills the interstellar spaces The advent of deep photographic imaging allowed Edward Barnard to produce the first images of dark nebulae silhouetted against the background star field of the galaxy while the first actual detection of cold diffuse matter in interstellar space was made by Johannes Hartmann in 1904 19 through the use of absorption line spectroscopy In his historic study of the spectrum and orbit of Delta Orionis Hartmann observed the light coming from this star and realized that some of this light was being absorbed before it reached the Earth Hartmann reported that absorption from the K line of calcium appeared extraordinarily weak but almost perfectly sharp and also reported the quite surprising result that the calcium line at 393 4 nanometres does not share in the periodic displacements of the lines caused by the orbital motion of the spectroscopic binary star The stationary nature of the line led Hartmann to conclude that the gas responsible for the absorption was not present in the atmosphere of Delta Orionis but was instead located within an isolated cloud of matter residing somewhere along the line of sight to this star This discovery launched the study of the Interstellar Medium In the series of investigations Viktor Ambartsumian introduced the now commonly accepted notion that interstellar matter occurs in the form of clouds 20 Following Hartmann s identification of interstellar calcium absorption interstellar sodium was detected by Heger 1919 through the observation of stationary absorption from the atom s D lines at 589 0 and 589 6 nanometres towards Delta Orionis and Beta Scorpii Subsequent observations of the H and K lines of calcium by Beals 1936 revealed double and asymmetric profiles in the spectra of Epsilon and Zeta Orionis These were the first steps in the study of the very complex interstellar sightline towards Orion Asymmetric absorption line profiles are the result of the superposition of multiple absorption lines each corresponding to the same atomic transition for example the K line of calcium but occurring in interstellar clouds with different radial velocities Because each cloud has a different velocity either towards or away from the observer Earth the absorption lines occurring within each cloud are either blue shifted or red shifted respectively from the lines rest wavelength through the Doppler Effect These observations confirming that matter is not distributed homogeneously were the first evidence of multiple discrete clouds within the ISM This light year long knot of interstellar gas and dust resembles a caterpillar 21 The growing evidence for interstellar material led Pickering 1912 to comment that While the interstellar absorbing medium may be simply the ether yet the character of its selective absorption as indicated by Kapteyn is characteristic of a gas and free gaseous molecules are certainly there since they are probably constantly being expelled by the Sun and stars The same year Victor Hess s discovery of cosmic rays highly energetic charged particles that rain onto the Earth from space led others to speculate whether they also pervaded interstellar space The following year the Norwegian explorer and physicist Kristian Birkeland wrote It seems to be a natural consequence of our points of view to assume that the whole of space is filled with electrons and flying electric ions of all kinds We have assumed that each stellar system in evolutions throws off electric corpuscles into space It does not seem unreasonable therefore to think that the greater part of the material masses in the universe is found not in the solar systems or nebulae but in empty space Birkeland 1913 Thorndike 1930 noted that it could scarcely have been believed that the enormous gaps between the stars are completely void Terrestrial aurorae are not improbably excited by charged particles emitted by the Sun If the millions of other stars are also ejecting ions as is undoubtedly true no absolute vacuum can exist within the galaxy In September 2012 NASA scientists reported that polycyclic aromatic hydrocarbons PAHs subjected to interstellar medium ISM conditions are transformed through hydrogenation oxygenation and hydroxylation to more complex organics a step along the path toward amino acids and nucleotides the raw materials of proteins and DNA respectively 22 23 Further as a result of these transformations the PAHs lose their spectroscopic signature which could be one of the reasons for the lack of PAH detection in interstellar ice grains particularly the outer regions of cold dense clouds or the upper molecular layers of protoplanetary disks 22 23 In February 2014 NASA announced a greatly upgraded database 24 for tracking polycyclic aromatic hydrocarbons PAHs in the universe According to scientists more than 20 of the carbon in the universe may be associated with PAHs possible starting materials for the formation of life PAHs seem to have been formed shortly after the Big Bang are widespread throughout the universe and are associated with new stars and exoplanets 25 In April 2019 scientists working with the Hubble Space Telescope reported the confirmed detection of the large and complex ionized molecules of buckminsterfullerene C60 also known as buckyballs in the interstellar medium spaces between the stars 26 27 See also EditAstrophysical maser Diffuse interstellar band Fossil stellar magnetic field Heliosphere List of interstellar and circumstellar molecules List of plasma physics articles Photodissociation regionReferences EditCitations Edit Herbst Eric 1995 Chemistry in The Interstellar Medium Annual Review of Physical Chemistry 46 27 54 Bibcode 1995ARPC 46 27H doi 10 1146 annurev pc 46 100195 000331 Boulanger F Cox P Jones A P 2000 Course 7 Dust in the Interstellar Medium In F Casoli J Lequeux F David eds Infrared Space Astronomy Today and Tomorrow p 251 Bibcode 2000isat conf 251B a b c Ferriere 2001 Nelson Jon 2020 Voyager Interstellar Mission NASA Archived from the original on 2017 08 25 Retrieved November 29 2020 The Pillars of Creation Revealed in 3D European Southern Observatory 30 April 2015 Retrieved 14 June 2015 Starr Michelle 19 October 2020 Voyager Spacecraft Detect an Increase in The Density of Space Outside The Solar System ScienceAlert Retrieved 19 October 2020 Kurth W S Gurnett D A 25 August 2020 Observations of a Radial Density Gradient in the Very Local Interstellar Medium by Voyager 2 The Astrophysical Journal Letters 900 1 L1 Bibcode 2020ApJ 900L 1K doi 10 3847 2041 8213 abae58 S2CID 225312823 Retrieved 19 October 2020 Voyager Fast Facts Jet Propulsion Laboratory Mathis J S Rumpl W Nordsieck K H 1977 The size distribution of interstellar grains Astrophysical Journal 217 425 Bibcode 1977ApJ 217 425M doi 10 1086 155591 Weingartner J C Draine B T 2001 Photoelectric Emission from Interstellar Dust Grain Charging and Gas Heating Astrophysical Journal Supplement Series 134 2 263 281 arXiv astro ph 9907251 Bibcode 2001ApJS 134 263W doi 10 1086 320852 S2CID 13080988 Samantha Blair Interstellar Medium Interference video SETI Talks Archived from the original on 2021 11 14 Voyager 1 Experiences Three Tsunami Waves in Interstellar Space video JPL Archived from the original on 2015 07 09 The First Planetary Nebula Spectrum Sky amp Telescope 2014 08 14 Retrieved 2019 11 29 William Huggins 1824 1910 www messier seds org Retrieved 2019 11 29 a b Kanipe Jeff 2011 01 27 The Cosmic Connection How Astronomical Events Impact Life on Earth Prometheus Books ISBN 9781591028826 a b V M Slipher Papers 1899 1965 Potpov Alexey et al 21 September 2020 Dust ice mixing in cold regions and solid state water in the diffuse interstellar medium Nature Astronomy 5 78 85 arXiv 2008 10951 Bibcode 2021NatAs 5 78P doi 10 1038 s41550 020 01214 x S2CID 221292937 Retrieved 26 September 2020 A geyser of hot gas flowing from a star ESA Hubble Press Release Retrieved 3 July 2012 Asimov Isaac Asimov s Biographical Encyclopedia of Science and Technology 2nd ed S Chandrasekhar 1989 To Victor Ambartsumian on his 80th birthday Journal of Astrophysics and Astronomy 18 1 408 409 Bibcode 1988Ap 29 408C doi 10 1007 BF01005852 S2CID 122547053 Hubble sees a cosmic caterpillar Image Archive ESA Hubble Retrieved 9 September 2013 a b NASA Cooks Up Icy Organics to Mimic Life s Origins Space com September 20 2012 retrieved September 22 2012 a b Gudipati Murthy S Yang Rui September 1 2012 In Situ Probing Of Radiation Induced Processing Of Organics In Astrophysical Ice Analogs Novel Laser Desorption Laser Ionization Time Of Flight Mass Spectroscopic Studies The Astrophysical Journal Letters 756 1 L24 Bibcode 2012ApJ 756L 24G doi 10 1088 2041 8205 756 1 L24 S2CID 5541727 PAH IR Spectroscopic Database The Astrophysics amp Astrochemistry Laboratory NASA Ames Research Center Retrieved October 20 2019 Hoover Rachel February 21 2014 Need to Track Organic Nano Particles Across the Universe NASA s Got an App for That NASA Retrieved February 22 2014 Starr Michelle 29 April 2019 The Hubble Space Telescope Has Just Found Solid Evidence of Interstellar Buckyballs ScienceAlert com Retrieved 29 April 2019 Cordiner M A et al 22 April 2019 Confirming Interstellar C60 Using the Hubble Space Telescope The Astrophysical Journal Letters 875 2 L28 arXiv 1904 08821 Bibcode 2019ApJ 875L 28C doi 10 3847 2041 8213 ab14e5 S2CID 121292704 Sources Edit Bacon Francis 1626 Sylva 3545 ed Beals C S 1936 On the interpretation of interstellar lines Monthly Notices of the Royal Astronomical Society 96 7 661 678 Bibcode 1936MNRAS 96 661B doi 10 1093 mnras 96 7 661 Birkeland Kristian 1913 Polar Magnetic Phenomena and Terrella Experiments The Norwegian Aurora Polaris Expedition 1902 03 section 2 New York Christiania now Oslo H Aschelhoug amp Co p 720 Boyle Robert 1674 The Excellency of Theology Compar d with Natural Philosophy vol ii iv p 178 Burke J R Hollenbach D J 1983 The gas grain interaction in the interstellar medium Thermal accommodation and trapping Astrophysical Journal 265 223 Bibcode 1983ApJ 265 223B doi 10 1086 160667 Dyson J 1997 Physics of the Interstellar Medium London Taylor amp Francis Field G B Goldsmith D W Habing H J 1969 Cosmic Ray Heating of the Interstellar Gas Astrophysical Journal 155 L149 Bibcode 1969ApJ 155L 149F doi 10 1086 180324 Ferriere K 2001 The Interstellar Environment of our Galaxy Reviews of Modern Physics 73 4 1031 1066 arXiv astro ph 0106359 Bibcode 2001RvMP 73 1031F doi 10 1103 RevModPhys 73 1031 S2CID 16232084 Haffner L M Reynolds R J Tufte S L Madsen G J Jaehnig K P Percival J W 2003 The Wisconsin Ha Mapper Northern Sky Survey Astrophysical Journal Supplement 145 2 405 arXiv astro ph 0309117 Bibcode 2003ApJS 149 405H doi 10 1086 378850 S2CID 51746099 The Wisconsin Ha Mapper is funded by the National Science Foundation Heger Mary Lea 1919 Stationary Sodium Lines in Spectroscopic Binaries Publications of the Astronomical Society of the Pacific 31 184 304 Bibcode 1919PASP 31 304H doi 10 1086 122890 Lamb G L 1971 Analytical Descriptions of Ultrashort Optical Pulse Propagation in a Resonant Medium Reviews of Modern Physics 43 2 99 124 Bibcode 1971RvMP 43 99L doi 10 1103 RevModPhys 43 99 Lequeux James 2005 The Interstellar Medium PDF Astronomy and Astrophysics Library Springer Bibcode 2005ism book L doi 10 1007 B137959 ISBN 978 3 540 21326 0 S2CID 118429018 McKee C F Ostriker J P 1977 A theory of the interstellar medium Three components regulated by supernova explosions in an inhomogeneous substrate Astrophysical Journal 218 148 Bibcode 1977ApJ 218 148M doi 10 1086 155667 Patterson Robert Hogarth 1862 Colour in nature and art Essays in History and Art 10 Reprinted from Blackwood s Magazine a href Template Citation html title Template Citation citation a CS1 maint postscript link Pickering W H 1912 The Motion of the Solar System relatively to the Interstellar Absorbing Medium Monthly Notices of the Royal Astronomical Society 72 9 740 743 Bibcode 1912MNRAS 72 740P doi 10 1093 mnras 72 9 740 Spitzer L 1978 Physical Processes in the Interstellar Medium Wiley ISBN 978 0 471 29335 4 Stone E C Cummings A C McDonald F B Heikkila B C Lal N Webber W R 2005 Voyager 1 Explores the Termination Shock Region and the Heliosheath Beyond Science 309 5743 2017 2020 Bibcode 2005Sci 309 2017S doi 10 1126 science 1117684 PMID 16179468 S2CID 34517751 Thorndike S L 1930 Interstellar Matter Publications of the Astronomical Society of the Pacific 42 246 99 Bibcode 1930PASP 42 99T doi 10 1086 124007 Yan Yong Xin Gamble Edward B Nelson Keith A December 1985 Impulsive stimulated scattering General importance in femtosecond laser pulse interactions with matter and spectroscopic applications The Journal of Chemical Physics 83 11 5391 5399 Bibcode 1985JChPh 83 5391Y doi 10 1063 1 449708 External links Edit Wikimedia Commons has media related to Interstellar media Freeview Video Chemistry of Interstellar Space William Klemperer Harvard University A Royal Institution Discourse by the Vega Science Trust The interstellar medium an online tutorial Portals Astronomy Spaceflight Solar System Science Retrieved from https en wikipedia org w index php title Interstellar medium amp oldid 1123175167, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.