DOI: https://doi.org/10.14710/jpa.v8i1.29176

Relativistic Effects and Stellar Properties in Hipparcos Binary Stars, White Dwarfs, and Neutron Stars

Verdi Yasin orcid scopus publons  -  Department of Informatics Engineering at Sekolah Tinggi Manajemen Informatika dan Komputer Jayakarta, Jakarta, Indonesia
Taufik Roni Sahroni orcid scopus  -  Department of Industrial Engineering, Bina Nusantara University, Jakarta, Indonesia
*Ruben Cornelius Siagian orcid scopus  -  Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Negeri Medan, Medan, Indonesia
Sri Mardiyati  -  Department of Informatics Engineering, Universitas Indraprasta PGRI, Jakarta, Indonesia
Pandhu Pramarta  -  Department of Informatics Engineering, Universitas Indraprasta PGRI, Jakarta, Indonesia
Riyanto Wujarso  -  Department of Management Science, Sekolah Tinggi Ilmu Ekonomi Jayakarta, Jakarta, Indonesia
Saprudin Saprudin  -  Department of Accounting, Sekolah Tinggi Ilmu Ekonomi Jayakarta, Jakarta, Indonesia
Edward Alfin orcid  -  Department of Mathematics Education, Universitas Indraprasta PGRI, Jakarta, Indonesia
Received: 24 Aug 2025; Revised: 24 Dec 2025; Accepted: 2 Jan 2026; Available online: 27 Feb 2026; Published: 27 Feb 2026.

Citation Format:
Abstract

The research analyzes astrophysical phenomena in binary stars, fast stars, white dwarfs, and neutron stars, taking relativistic effects into account using Hipparcos catalog data. The objectives are to evaluate the relativistic precession of binary stars, the Shapiro delay due to the supermassive black hole Sgr A, the relativistic correction of neutron star luminosity, the distribution of star populations in the Hertzsprung–Russell diagram, the gravitational redshift of white dwarfs, and the characteristics of stars with extreme transverse velocities. Data from 10,726 binary star systems and 602 white dwarfs were processed numerically using R for data manipulation, visualization, and statistical calculations. The results show that relativistic precession in binary stars is generally small, increases in narrow orbits, and follows a power law with respect to the semi-major axis (exponent −0.453). Shapiro delay varies with projected distance to Sgr A, with most stars experiencing small delays, while some experience delays of up to 310 seconds. Neutron star luminosity shows a relativistic correction of ~0.03%, consistent with gravitational redshift and time dilation. The Hertzsprung–Russell diagram shows a clear separation between giants, main sequence stars, and white dwarfs, with a significant linear relationship between absolute magnitude and color index (B−V). The gravitational redshift of white dwarfs is controlled by radius (exponent −1.0001), while stars with extreme velocities form a heterogeneous and evenly distributed population. In conclusion, Hipparcos data support general relativity predictions and enable quantitative evaluation of stellar physics and evolution. Research novelties include systematic measurements of relativistic precession, Shapiro delay, neutron star luminosity corrections, white dwarf radius–redshift relationships, and kinematic characteristics of extreme stars.

Fulltext View|Download
Keywords: Relativistic precession; Shapiro delay; Gravitational redshift; Hipparcos catalog; Stellar kinematics.

Article Metrics:

Article Info
Section: Articles
Language : EN
Recent articles
Performance Comparison of Large-Core Optical Waveguides with Waste-Derived and Analytical-Grade Chitosan Core Materials Estimation of Geothermal Energy Potential Using Monte Carlo Simulation at Jaboi Geothermal Field, Indonesia Effect of Pepper Stem Fiber Orientation on Mechanical Properties, Water Absorption, and Biodegradation of Cassava Bioplastic Films More recent articles
  1. K. Sośnica, G. Bury, R. Zajdel, K. Kazmierski, J. Ventura-Traveset, R. Prieto-Cerdeira, and L. Mendes, "General Relativistic Effects Acting on the Orbits of Galileo Satellites," Celest. Mech. Dyn. Astron, 133(4), 14 (2021)
  2. A. Tedesco, "Orbital Motion, Periastron Advance and Galaxy Rotation Curves beyond General Relativity," (2023)
  3. M. Pössel, "Light, Delayed: the Shapiro Effect and the Newtonian Limit," arXiv, arXiv:2110.07016 (2021)
  4. J. Piekarewicz, "The Nuclear Physics of Neutron Stars," arXiv:2209.14877 (2022)
  5. L. G. Althaus, M. E. Camisassa, S. Torres, T. Battich, A. H. Córsico, A. Rebassa-Mansergas, and R. Raddi, "Structure and Evolution of Ultra-Massive White Dwarfs in General Relativity," Astron. Astrophys., 668, A58 (2022)
  6. V. V. Makarov, "Mass Ratios of Long-Period Binary Stars Resolved in Precision Astrometry Catalogs of Two Epochs," Rev. Mex. Astron. Astrofís., 57(2), 399-405 (2021)
  7. V. V. Makarov, "Differential Proper Motion Spin of the Hipparcos and Gaia Celestial Reference Frames," Astron J., 164(4), 157 (2022)
  8. J. González-Payo, J. A. Caballero, and M. Cortés-Contreras, "Reaching the Boundary Between Stellar Kinematic Groups and Very Wide Binaries-IV: The Widest Washington Double Star Systems With ρ≥ 1000 Arcsec in Gaia DR3," Astron. Astrophys., 670, A102 (2023)
  9. A. M. Hamadamen and I. M. Murad, "The Apsidal Motion and OC Plot of V2815 Orion Algol Binary Stars," in 2024 10th Int. Eng. Conf. on Adv. Comput. Civ. Eng. (IEC), 136-141. IEEE (2024)
  10. A. Abu-Dhaim, A. Taani, D. Tanineah, N. Tamimi, M. Mardini, and M. Al-Wardat, "Studying the Physical Parameters of the Stellar Binary System HIP 42455 (HD 73900)," Acta Astron., 72(3), 171-181 (2022)
  11. A. A. Abushattal, A. A. Alrawashdeh, and A. F. Kraishan, "Astroinformatics: The Importance of Mining Astronomical Data in Binary Stars Catalogues," Commun. BAO., 69(2), 251-255 (2022)
  12. I. Izmailov and M. Khovritchev, "New Orbital Parameters of 850 Wide Visual Binary Stars and Their Statistical Properties," Res. Astron. Astrophys., 25(1), 015016 (2025)
  13. M. A. C. Perryman, L. Lindegren, J. Kovalevsky, E. Hog, U. Bastian, P. L. Bernacca, M. Creze, F. Donati, M. Grenon, M. Grewing, F. van Leeuwen, H. van der Marel, F. Mignard, C. A. Murray, R. S. Le Poole, H. Schrijver, C. Turon, F. Arenou, M. Froeschle, and C. S. Petersen, "The HIPPARCOS Catalogue," Astron. Astrophys., 323, L49–L52 (1997)
  14. T. D. Brandt, "The Hipparcos–Gaia Catalog of Accelerations: Gaia EDR3 Edition," Astrophys. J. Suppl. Ser., 254(2), 42 (2021)
  15. S. Rathod, A. T. Kumar, and S. Haripriya, "Data Manipulation Using R Tidyverse," Statistical Procedures for Analyzing Agricultural Data Using R., 17 (2023)
  16. Y. Dai, "Power-Law Relationship between the Semi-Major Axis and Rotation Period Ratio in an Eccentric System: Its Physical Meaning and Various Applications," (2024)
  17. Y. F. Dai, "Eccentricity Excitation Equation and Its Underlying Mechanism: Orbital Precession Mechanism," (2024)
  18. S. R. Green and R. M. Wald, "Newtonian and Relativistic Cosmologies," Phys. Rev. D, 85(6), 063512 (2012)
  19. E. G. Haug, Relativistic Newtonian Gravity Makes Dark Energy Superfluous?, (2021)
  20. G. Antoniciello, L. Borsato, G. Lacedelli, V. Nascimbeni, O. Barragán, and R. Claudi, "Detecting General Relativistic Orbital Precession in Transiting Hot Jupiters," Mon. Not. R. Astron. Soc., 505(2), 1567–1574 (2021)
  21. A. Yahalom, "The Weak Field Approximation of General Relativity and the Problem of Precession of the Perihelion for Mercury," Symmetry., 15(1), 39 (2022)
  22. I. H. Stairs, "Pulsars in Binary Systems: Probing Binary Stellar Evolution and General Relativity," Science., 304(5670), 547–552 (2004)
  23. M. A. Al-Wardat, A. M. Hussein, H. M. Al-Naimiy, and M. A. Barstow, "Comparison of Gaia and Hipparcos Parallaxes of Close Visual Binary Stars and the Impact on Determinations of Their Masses," Publ. Astron. Soc. Aust., 38, e002 (2021)
  24. A. Jordán and G. Á. Bakos, "Observability of the General Relativistic Precession of Periastra in Exoplanets," Astrophys. J., 685(1), 543-552 (2008)
  25. A. Melatos, "Radiative Precession of an Isolated Neutron Star," Mon. Not. R. Astron. Soc., 313(2), 217-228 (2000)
  26. R. Capuzzo-Dolcetta and M. Sadun-Bordoni, "Orbital Precession of Stars in the Galactic Centre," Mon. Not. R. Astron. Soc., 522(4), 5828-5839 (2023)
  27. S. Kopeikin and B. Mashhoon, "Gravitomagnetic Effects in the Propagation of Electromagnetic Waves in Variable Gravitational Fields of Arbitrary-Moving and Spinning Bodies," Phys. Rev. D, 65(6), 064025 (2002)
  28. V. B. Braginskij and V. N. Rudenko, "Relativistic Gravitational Experiments," Sov. Phys. Usp., 13, 165 (1970)
  29. C. Wang, J. Hu, Y. Zhang, and H. Shen, "Properties of Neutron Stars Described by a Relativistic Ab Initio Model," Astrophys. J., 897(1), 96 (2020)
  30. J. G. G. Gimenez, Effects of the Generalized Uncertainty Principle on Neutron Stars, (2025)
  31. D. F. Gray, "The Observation and Analysis of Stellar Photospheres," Cambridge University Press (2021)
  32. C. Gallart, M. Zoccali, and A. Aparicio, "The Adequacy of Stellar Evolution Models for the Interpretation of the Color-Magnitude Diagrams of Resolved Stellar Populations," Annu. Rev. Astron. Astrophys., 43(1), 387-434 (2005)
  33. A. Mucciarelli, E. Carretta, L. Origlia, and F. R. Ferraro, "The Chemical Composition of Red Giant Stars in Four Intermediate-Age Clusters of the Large Magellanic Cloud," Astron. J., 136(1), 375-388 (2008)
  34. S. Vitali, D. Slumstrup, P. Jofré, L. Casamiquela, H. Korhonen, S. Blanco-Cuaresma, M. L. Winther, and V. Aguirre Borsen-Koch, "Exploring the Dependence of Chemical Traits on Metallicity—Chemical Trends for Red Giant Stars With Asteroseismic Ages," Astronomy & Astrophysics, 687, A164 (2024)
  35. A. Generozov and H. B. Perets, "Constraints on the Origins of Hypervelocity Stars: Velocity Distribution, Mergers, and Star Formation History," Mon. Not. R. Astron. Soc., 513(3), 4257–4266 (2022)
  36. E. M. Rossi, S. Kobayashi, and R. E. Sari, "The Velocity Distribution of Hypervelocity Stars," Astrophys. J., 795(2), 125 (2014)

Last update:

No citation recorded.

Last update:

No citation recorded.