Black Hole: Comparison
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BThe theory of black holes are the celestial objects existing at the center of every galaxy. They can currently only be described by their spin, charge, and angular momentum, with other attributes derived from the basic properties. The existence of bwas conceived by Karl Schwarzschild during World War II. The term black hole for the then-theoretical celestial object was coined later by John Wheeler. Black holes was first predicted by German physicist and astronomer Karl Schwarzschild in 1916, with the exact solutions to Einstein's field equations of general relativity one year after its publication. Finnish physicist Gunnar Nordström proposed a theory of gravity and electromagnetism with four spatial dimensions in 1914, and later developed into the stationary chargedare thought to have the escape velocity faster than the speed of light, which means not even light can escape their gravitational fields. Currently, most astronomical scientists have reached the consensus that black hole in 1918s exist at the center of every galaxy.

  • black hole
  • general relativity
  • active galactic nuclei

1.Physical HiPropertiestory

The existence of bBlack holes was predictcan only be described by German physicisttheir spin, charge, and astronomer Karl Schwarzschild in 1916ngular momentum, with the exact solution to the Einstein field equations of general relativity [1]other attributes derived from the basic properties. They non-charged stationary Schwarzschild black hole became the main subject of interest for the leading Manhattan Project scientists, such as J. Robert Oppenheimer and John A. Wheeler, a decade laterare thought in classical cosmology, i.e. the Big Bang model, to be the result [2][3]. Johnf A. Wheeler coined the term "black hole" and furthered the Schwarzschild Radius defincollapsing matter following the event horizxplosion of Schwarzschild black holes to the singularity [3][4]. Difflarge stars into superentiated from the Einstein-Rosen Bridge approach to Schwarzschild wormholes that discover the dimensions of space, J. Robert Oppenheimer turned to the nuclear stability of fusion cores with the presumptions of neutrons, and published the paper with George Volkoff in 1939, proving neutron cores, like white dwarfs, could not be indefinitely heavovae. Therefore, the mass of a black hole is often depicted in terms of solar mass, denoted by [5][6][2]m.

German aeronautWical engineer and mathematical physicist Hans Reissner and Finnishth their basic physicist Gunnar Nordström, respectively in 1916 and 1918, put forth the al properties, four types of black hole with mass and chargs have [7][8]; thbeen non-stationary solution to general relativity was not derived until 1963 by Roy Patrick Kerr, defining the space outside a rotating black hole [1][9]. Iproposed by theoretical physicists, with each type named in honor 1965, Americanof them physicist Ezra T. Newman generalized the Kerr solution and found the axisymmetric solution to general relativity with the both rotating and electrically charged black hole [101]. The classical theoretic developments of black holes are thence completed with the physical properties listed in Table 1 [11]::

Table 1. Types of Black Hole.

Types of Black Hole
NameChargeSpin
Schwarzchild black holeNoNo
Kerr black holeNoYes
Kerr-Newman black holeYesYes
Reissner-Nordström black holeYesNo
 
NameChargeSpin
Schwarzchild black holeNoNo
Kerr black holeNoYes
Kerr-Newman black holeYesYes
Reissner-Nordström black holeYesNo

2.The SBignificance in Co Bang Interpretationsmology

OppenTheimer's proof reinforced the belief that black holes resul idea of the universe starting out from star collapse, following the explosion of large stars into supernovae, with the Big Bang cosmology ideated by an atom originated from the Belgian physicist contemporary to Einstein's time, George Lemaître, and popularized by . On March 28, 1949, the English astronomer Fred Hoyle on March 28, 1949popularized the phrase the "Big Bang" during a defense [122]. The frefore, solar mass (denoted by m) amework of the Big Bang Theory and nuclear physics usually adopted to describe the mass of a black holewas later constructed into the cosmic interpretations of the theoretical celestial object.

Two types of black holes are categorized in the Bang Bang model according to the origins, primordial black hole and the normative black hole from stellar remnants. Primordial black holes are thought to be created not soon after the Big Bang, and the black holes from stellar remnants are thought to be created after a star exhausted its capacities for nuclear fusion [2]. It is estimated that for a star to be capable of compaction into a singularity, it must have a mass greater than 3.4 times that of the Sun.

The paradigmatic q

Characteristics

Questioning into the Big Bang interpretations was marked by British mathematical physicist and astronomer Roger Penrose'ste a few features have been attributions in 1963 to the asymptotic properties to the space-time continuum [13]. It waed to black holes in obs calculated by Steven Weinberg in 1981 that the time required for a proton to decay would far surpass the age of the universe calculated by the Big Bang model, having a lifetime at least 1020 times rvational astronomy, amof the latter [14]. Roger Penrose sought to reconcile the Big Bang model with the particle physics advancements and proposed the "Before the Big Bang" insights in 2006 and Conformal Cyclic Cosmology later [15][16][17]. Black hole as which include its Bolometrophysics thus signify the threshold of our current understandings of the luminosity, denoted by LBol, universe.

3. Application

The application of black hole physics on quantum mechanics emerged in the 1970s at the end of the Space Race. Cryogenic engineering was adopted to further the photometric method from Schwarzschild, and black hole thermodynamics became one of the main topic of interest [18]. The applicatiosolute magnitude, the widely known evens of black holes physics led to further empirical findings such as Hawking radiation with observations on the antimatter distribution around black holes [19]. It was once bel horizon and singularieved thaty, Hawking radiation implies the eventual evaporation of black holes, but the idea was rejected by some physicists and later and Hawking himself [20][21][22].

Ipoin observational astronomy, Bolometric luminosity (denoted by LBol) is s, applied to describe the black hole mass and accretion rate phenomenon with actictive galactic nuclei (AGN) , etc. [233]. With the large range of bolometric luminosities for a given The stellar remnant belief of black hole mass, Eddington limit is applied to define an approximate upper limit to the luminosity [24]. Tpostulates the absolute magnitude of black holes can be derived thanks to the findings of Hawking radiation, and low surface brightness galaxies also came into the vision of observational astronomers [25].

4. Scientific & Cultural Influences

Tt the event horizon is the threshe concept of black hole did not catch popular attention until Steven Hawking published his book A Brief History of Time in 1988. Its scientific influld in space whence, however, never faded since its conception by Einstein's general theory of relativity. Albeit it is unrealistic to circumvent black holes from nuclear weaponry, where Einstein's letter to Franklin D. Roosevelt saw to that, the critical and intensive development of the applied physics originated from the Manhattan Project scientists and with the NASA Deep Space Network [26][27][28].e the gravitational force surpasses the velocity of light, and relativity theory The part of the black hole histories with nuclear weapons is put on stage by Christopher Nolan with the movie Oppenheimer iostulates the sin 2023 [29]. Also brought to popular culture by Nolan is wormholes in his artistic depictions in the 2014 movie Interstellar [30].

The mity being a point ore classical cultures swayed from the reflections of wars and nuclear weapons, characterized by Stanley Kubrick, and the movie The Black Hole directed by Gary Nelson screened in 1979 inspired the modern and contemporary cultures with George Lucas’ Star Wars -- a return to the films first ever made with the space theater by Georges Méliès, A Trip to the Moon [31][32][33][34].

5. New Progress

With the facilitation of NASA Deep Space Network, the U.S.A.'s space-based telescope missions operate differently in concept with the European counterparts. The European Space Agency (ESA)'s missions, characterized by Planck Observatory, International Gamma-Ray Astrophysics Laboratory (INTEGRAL), XMM-Newton, etc., concentrate on cosmological observations, while the NASA missions focus more on the wavelength functionalities [35]. A list of space-based telescopes commissioned by the two major institutions is summarized in Table 2.

Table 2. List of Major Space-Based Telescopes
YearTelescopeInstitutionWavelengthObjectives
1990Hubble Space TelescopeNASA & ESAVisible, UV, Near-IRDeep Space Objects
1995Solar & Heliospheric ObservatoryNASA & ESAOptical-UV, MagneticSun and Solar Wind
1999XMM-NewtonESAX-rayVarious
1999Chandra X-ray ObservatoryNASAX-rayVarious
2002INTEGRALESAGamma ray, X-ray, VisibleVarious
2003Galaxy Evolution ExplorerNASAUVGalaxies
2003Spitzer Space TelescopeNASAIRDistant and Nearby Objects
2004Swift Gamma Ray Burst ExplorerNASAGamma ray, X-ray, UV, VisibleVarious
2006COROTCNES & ESAVisibleExtrasolar planets
2006Solar Terrestrial Relations ObservatoryNASAVisible, UV, RadioSun and Coronal Mass Ejections
2008Fermi Gamma-ray Space TelescopeNASAGamma-rayVarious
2009Herschel Space ObservatoryESA & NASAFar-IRVarious
2009Planck ObservatoryESAMicrowaveCosmic Microwave Background
2009Kepler MissionNASAVisibleExtrasolar planets

The modern and contemporary progresses for black hole astrophysics have sprung up in the technological realm. The Laser Interferometer Gravitational-Wave Observatory (LIGO) was completed in 1999, with the first search for gravitational waves beginning 2002 and concluding in 2010 [36]. The sister facility Virgo began its construction in 1997 in the countryside near Pisa, in Italy, and the European Gravitational Observatory (EGO) was founded in 2000 [37]. Inaugurated in 2003, Virgo's scientific observations began in 2007, and an agreement to operate Virgo and the LIGO detectors, in the USA, as a ‘single machine’ was signed [38].

Contemporary Developments

Mainland China born cosmologist Yang I. Pachankis theorized that black holes are thermonuclear-binding to white holes, and derived data evidence from the NASA multi-wavelength space-based telescopes seen in Figure 1 [39][40][41]. He interpreted the antimatter-saturated surface plasma interactions to be mediated by the fifth cosmic force, shifting between fusion and fission processes just as centromeres in DNAs do [42][43]. He asserts the formation of Hawking points is backlash from the black hole seed and white hole seed collision momentum, resulting from the asymptotic thermodynamics [11].

Figure 1. Surface recombination of NGC 3034 anti-matter plasma with neutron signature in the black hole portal and the white hole.

Figure 1. Surface recombination of NGC 3034 anti-matter plasma with neutron signature in the black hole portal and the white hole.

infinite spacetime curvature.

References

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  6. Wormhole Tunnels in Spacetime May Be Possible, New Research Suggests . Scientific American. Retrieved 2023-10-7
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  8. H. Reissner; Über die Eigengravitation des elektrischen Feldes nach der Einsteinschen Theorie. Ann. der Phys. 1916, 355, 106-120.
  9. Canterbury Distinguished Professor Roy Kerr’s black hole theory proven right . University of Canterbury. Retrieved 2023-10-7
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  15. Penrose, R.. Before the Big Bang: An Outrageous New Perspective and Its Implications for Particle Physics; European Physical Society Accelerator Group (EPS-AG): Edinburgh, Scotland, 2006; pp. 2759-2762.
  16. Roger Penrose; The Big Bang and its Dark-Matter Content: Whence, Whither, and Wherefore. Found. Phys. 2018, 48, 1177-1190.
  17. V. G. Gurzadyan; R. Penrose; CCC and the Fermi paradox. Eur. Phys. J. Plus 2016, 131, 1-5.
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  19. Interesting Stephen Hawking Theories and Facts That Made Him Famous . Interesting Engineering. Retrieved 2023-10-8
  20. Black Hole Evaporation and Information Loss . Perimeter Institute. Retrieved 2023-10-8
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  22. Hrvoje Nikolić; HRVOJE NIKOLIĆTheoretical Physics Division, Rudjer Bošković Institute, P.O.B. 180, HR-10002 Zagreb, Croatia; Samuel L. Braunstein; Stefano Pirandola; Karol Życzkowski; Manas K. Patra; R. Srikanth; Srikanth Hebri; BLACK HOLES RADIATE BUT DO NOT EVAPORATE. Int. J. Mod. Phys. D 2005, 14, 2257-2261.
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  24. Woo, J.-H. Active Galactic Nucleus Black Hole Masses and Bolometric Luminosities. The Astrophysical Journal 2002, 579, 530-544.
  25. Greg Bothun; Chris Impey; Stacy McGaugh; Low-Surface-Brightness Galaxies: Hidden Galaxies Revealed. Publ. Astron. Soc. Pac. 1997, 109, 745.
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  31. Stanley Kubrick (1928-1999) . IMDb. Retrieved 2023-10-8
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  37. Our Sister Facilities . LIGO Caltech. Retrieved 2023-10-8
  38. Virgo History . Virgo. Retrieved 2023-10-8
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  40. Pachankis, Y.I. Some Concepts of Space, Time, and Lengths in Simplified Chinese* — An Analytical Linguistics Approach. International Journal of Innovative Science and Research Technology 2022, 7, 550-662.
  41. Pachankis, Y.I. A Multi­-wavelength Data Analysis with Multi­-mission Space Telescopes. International Journal of Innovative Science and Research Technology 2022, 7, 701-­708.
  42. Pachankis, Y.I. Data-Driven Insights to Cosmology in the Dark Universe. J. Plasma Chem. Plasma Process. Res. 2022, 3, 43-50.
  43. Pachankis, Y.I. On Centromeres’ Evidential Values in Physical Cosmology. Global Journal of Science Frontier Research - I 2023, 23, 13-18.
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