This study aims to investigate essential concepts in quantum mechanics and theoretical physics, with an emphasis on the 1+1 dimension. We examine the Dirac equation for relativistic spin-1/2 particles, the Time-Dependent Schrödinger Equation in 1+1 spacetime with flat conformal metric, and connect them to the Dirac equation. Additionally, we explore the Alcubierre Metric related to warp drive, particle modeling in a harmonic potential using the Schrödinger Equation, and the Gödel Metric Solution to depict the peculiarities of spacetime. The research aims to deepen the understanding of these concepts, identify theoretical implications, and their potential applications. This research aims to enhance the understanding of fundamental physics, assist in the development of future technologies, and provide deeper insights into the universe. Its benefits lie in contributing to theoretical understanding in physics, which can spark the development of new theories. This study is limited to physics concepts in the 1+1 dimensions, without empirical experiments or practical applications. The primary focus is on the theoretical analysis of these concepts. The results of this research have potential theoretical implications in understanding basic physics and spacetime phenomena. The simplification and connections between these concepts can aid in the development of new theories in theoretical physics. The uniqueness of this research lies in its integrative approach to quantum mechanics and theoretical physics concepts in the 1+1 dimension, which may not have been extensively explored previously. Through this research, we have investigated several key concepts in quantum mechanics and theoretical physics in the 1+1 dimension. These findings can make a significant contribution to our understanding of the universe and the potential development of new theories in physics.

Quantum Mechanics; Spacetime Curvature; Metric Relationships; Relativistic Physics

1. Siagian RC, Alfaris L, Nurahman A, Muhammad AC, Nyuswantoro UI, Nasution B. Separation of Variables Method in Solving Partial Differential Equations and Investigating the Relationship between Gravitational Field Tensor and Energy-Momentum Tensor in Einstein’s Theory of Gravity. Kappa Journal. 2023;7(2):343–51.

2. Bhaduri B, Yessenov M, Abouraddy AF. Anomalous refraction of optical spacetime wave packets. Nature Photonics. 2020;14(7):416–21.

3. Riva MM, Vernizzi F. Radiated momentum in the post-Minkowskian worldline approach via reverse unitarity. Journal of High Energy Physics. 2021;2021(11):1–41.

4. Hammad F, Sadeghi P, Fleury N, Leblanc A. What can we learn from the conformal noninvariance of the Klein–Gordon equation? International Journal of Modern Physics A. 2021;36(30):2150224.

5. Hansraj S, Megandhren G, Banerjee A, Mkhize N. All conformally flat Einstein–Gauss–Bonnet static metrics. Classical and Quantum Gravity. 2021;38(6):065018.

6. Ney A. The world in the wave function: A metaphysics for quantum physics. Oxford University Press; 2021.

7. Qian W. On the Physical Process and Essence of the Photoelectric Effect. Journal of Applied Mathematics and Physics. 2023;11(6):1580–97.

8. Siagian RC, Alfaris L, Nurahman A, Sumarto EP. TERMODINAMIKA LUBANG HITAM: HUKUM PERTAMA DAN KEDUA SERTA PERSAMAAN ENTROPI. Jurnal Kumparan Fisika [Internet]. 2023 May;6(1):1–10. Available from: https://ejournal.unib.ac.id/kumparan_fisika/article/view/26855

9. Budiman Nasution, Ruben Cornelius Siagian, Arip Nurahman, Lulut Alfaris. EXPLORING THE INTERCONNECTEDNESS OF COSMOLOGICAL PARAMETERS AND OBSERVATIONS: INSIGHTS INTO THE PROPERTIES AND EVOLUTION OF THE UNIVERSE. SPEKTRA [Internet]. 2023 Apr 29 [cited 2023 May 1];8(1). Available from: https://journal.unj.ac.id/unj/index.php/spektra/article/view/34133

10. BHATT M. String Theory predictions that relate to exotic dark matter. 2023;

11. Rizzo A. On the Vacuum Hydrodynamics of Moving Bodies. Journal of High Energy Physics. 2023;1:1–48.

12. Sinaga GHD, Panjaitan MB, Siagian RC, Siahaan KWA. MEMAHAMI INDAHNYA SEMESTA DENGAN DASAR TEORI KOSMOLOGI DAN ASTRONOMI FISIKA SERTA SEJARAHNYA [Internet]. Penerbit Widina; Available from: https://books.google.co.id/books?id=BKtwEAAAQBAJ

13. Alfaris L, Siagian RC, Sumarto EP. Study Review of the Speed of Light in Space-Time for STEM Student. Jurnal Penelitian Pendidikan IPA. 2023;9(2):509–19.

14. Planet B. A. Pendahuluan. ILMU DASAR ASTRONOMI. 2022;70.

15. Barley K, Vega-Guzmán J, Ruffing A, Suslov SK. Discovery of the relativistic Schrödinger equation. Physics-Uspekhi. 2022;65(1):90.

16. MISBAH M. Teori Relativitas. 2023;

17. Dennis MR, Tijssen T, Morgan MA. On the Majorana representation of the optical Dirac equation. Journal of Physics A: Mathematical and Theoretical. 2023;56(2):024004.

18. Marsch E, Narita Y. Dirac equation based on the vector representation of the Lorentz group. The European Physical Journal Plus. 2020;135(10):1–12.

19. Nasution B, Alfaris L, Siagian RC. Basic Mechanics of Lagrange and Hamilton as Reference for STEM Students. Jurnal Penelitian Pendidikan IPA. 2023;9(2):898–905.

20. González-Jiménez R, Nikolakopoulos A, Jachowicz N, Udías J. Nuclear effects in electron-nucleus and neutrino-nucleus scattering within a relativistic quantum mechanical framework. Physical Review C. 2019;100(4):045501.

21. Murphy CW. Dimension-8 operators in the standard model effective field theory. Journal of High Energy Physics. 2020;2020(10):1–48.

22. Albertin ET, Bradshaw ZP, Kirt KM, Long KE, Nguyen A. On Dirac Factorization, Fractional Calculus, and Polynomial Linearization. arXiv preprint arXiv:221206062. 2022;

23. Alkhateeb M, Matzkin A. Relativistic Bohmian trajectories and Klein-Gordon currents for spin-0 particles. Foundations of Physics. 2022;52(5):104.

24. Kilian E, Toroš M, Deppisch FF, Saakyan R, Bose S. Requirements on quantum superpositions of macro-objects for sensing neutrinos. Physical Review Research. 2023;5(2):023012.

25. Siagian RC. Filsafat Fisika dalam konteks Teori Relativitas. philosophy. 1:20.

26. Han S. The Weyl double copy in vacuum spacetimes with a cosmological constant. Journal of High Energy Physics. 2022;2022(9):1–20.

27. Farag NG, Eltanboly AH, El-Azab M, Obayya S. On the analytical and numerical solutions of the one-dimensional nonlinear Schrodinger equation. Mathematical Problems in Engineering. 2021;2021:1–15.

28. Nasution B, Siagian RC, Ritonga W, Alfaris L, Muhammad AC, Nurahman A. Investigating the Density Distribution of Dark Matter in Galaxies: Monte Carlo Analysis and Model Comparison. Indonesian Review of Physics (IRiP). 2023;6(1).

29. Nasution B, Siagian RC, Ritonga W, Alfaris L, Muhammad AC, Nurahman A. A Monte Carlo Density Distribution Model Study to Analyze Galaxy Structure, Mass Distribution, and Dark Matter Phenomena. Indonesian Review of Physics. 2023;6(1):24–45.

30. Misbah M. Persamaan Differensial Matematika Fisika. 2022;

31. Chen WX. Studies on Maxwell Equations, Electromagnetic Wave Equations and Functions in Cosmological Special Relativity Theory. Electromagnetic Wave Equations and Functions in Cosmological Special Relativity Theory (March 12, 2023). 2023;

32. Santos-Pereira OL, Abreu EM, Ribeiro MB. Fluid dynamics in the warp drive spacetime geometry. The European Physical Journal C. 2021;81:1–22.

33. Gutti S, Kulkarni S, Prasad V. Closed timelike curves and energy conditions in regular spacetimes. The European Physical Journal C. 2022;82(12):1136.

34. García JF, Sabín C. Dirac equation in exotic spacetimes. Physical Review D. 2019;99(2):025008.

35. Bobrick A, Martire G. Introducing physical warp drives. Classical and Quantum Gravity. 2021;38(10):105009.

36. Donmez O. The gravitational collapse of the dust toward the newly formed rotating black holes in Kerr and 4-D Einstein-Gauss-Bonnet Gravities. arXiv preprint arXiv:230711725. 2023;

37. Ovalle J, Contreras E, Stuchlik Z. Kerr–de Sitter black hole revisited. Physical Review D. 2021;103(8):084016.

38. Siagian RC, Alfaris L, Muhammad AC, Nyuswantoro UI, Rancak GT. The Orbital Properties of Black Holes: Exploring the Relationship between Orbital Velocity and Distance. Journal of Physics and Its Applications [Internet]. 2023 Jun 1 [cited 2023 Jun 2];5(2):35–42. Available from: https://ejournal2.undip.ac.id/index.php/jpa/article/view/17860

39. Nasution B, Ritonga W, Siagian RC, Alfaris L, Muhammad AC, Nyuswantoro UI, et al. Physics Visualization of Schwarzschild Black Hole through Graphic Representation of the Regge-Wheeler Equation using R-Studio Approach. Sainmatika: Jurnal Ilmiah Matematika dan Ilmu Pengetahuan Alam. 2023;20(1):8–24.

40. Siagian RC, Alfaris L, Muhammad AC, Mamou AE, Rancak GT, Nyuswantoroe UI, et al. Pengantar Matematika Geometri Lubang Hitam. wawasan Ilmu;

41. Siagian RC, Alfaris L, Sinaga GHD. Review for Understanding Dark Matter in The Universe as Negative Energy. In 2023. p. 679–85.