量子非谐振子和双势阱模型中的六次与八次混合非谐项的基态能隙

doi:10.12677/MP.2024.142005

期刊菜单

量子非谐振子和双势阱模型中的六次与八次混合非谐项的基态能隙
The Ground-State Energy Gap of Sexic-Octic Mixed Anharmonicities in the Quantum Anharmonic Oscillator and the Double-Well Potential

DOI: 10.12677/MP.2024.142005, PDF, 国家自然科学基金支持
作者: 张会鹏, 樊炜：江苏科技大学理学院，江苏镇江
关键词: 瞬子；量子非谐振子；数值自举；半正定优化；Instanton； Quantum Anharmonic Oscillator； Numerical Bootstrap； Semidefinite Optimization

摘要: 量子非谐振子和双势阱是重要的数学物理模型，其中，计算源自于非简谐项的基态能隙是一个重要的问题。对于含有纯非谐项的情况，我们最近的研究发现可以用同一个公式来描述它们源自于纯非谐项的基态能隙，意味着这两个模型中的非谐效应存在着某种联系。上述发现是关于的纯非谐项的情况，在本文中我们将继续关注含有混合非谐项的情况，我们计算了六次与八次混合非谐项所产生的基态能隙，发现它们仍然由同样的公式来描述，从而进一步确认了这种未知联系的存在性。

Abstract: The quantum anharmonic oscillator and the double-well potential models are important mathe-matical physics models in which the ground-state energy gap coming from the anharmonic terms is an important topic. For the case of pure anharmonic term, we find a qualitative formula that de-scribes the ground-state energy gap of both the anharmonic oscillator and the double-well poten-tial, which means that there is some connection between the anharmonic effects in the two models. The above discovery is about the case of pure anharmonic term, in this paper we will continue to focus on the case with mixed anharmonic term, we study this energy gap for the case of the sex-tic-octic mixed anharmonic term, and find that they are still described by the same qualitative formula, thus further confirming the existence of this unknown connection.

文章引用：张会鹏, 樊炜. 量子非谐振子和双势阱模型中的六次与八次混合非谐项的基态能隙[J]. 现代物理, 2024, 14(2): 39-46. https://doi.org/10.12677/MP.2024.142005

参考文献

[1]	Müller-Kirsten, H.J.W. (2012) Introduction to Quantum Mechanics: Schrödinger Equation and Path Integral. 5th Edition, World Scientific, Singapore. [Google Scholar] [CrossRef]
[2]	Kleinert, H. (2004) Path Integrals in Quantum Me-chanics, Statistics, Polymer Physics, and Financial Markets. 3th Edition, World Scientific, Singapore. [Google Scholar] [CrossRef]
[3]	Bender, C.M. and Wu, T.T. (1969) Anharmonic Oscillator. Physical Review, 184, 1231-1260. [Google Scholar] [CrossRef]
[4]	Gildener, E. and Patrascioiu, A. (1977) Pseudoparticle Contribu-tions to the Energy Spectrum of a One-Dimensional System. Physical Review D, 16, 423-430. [Google Scholar] [CrossRef]
[5]	Bender, C.M. and Wu, T.T. (1971) Large-Order Behavior of Per-turbation Theory. Physical Review Letters, 27, 461-465. [Google Scholar] [CrossRef]
[6]	Polyakov, A.M. (1977) Quark Confinement and Topology of Gauge Groups. Nuclear Physics B, 120, 429-458. [Google Scholar] [CrossRef]
[7]	Belavin, A.A., Polyakov, A.M., Schwartz, A.S. and Tyupkin, Y.S. (1975) Pseudoparticle Solutions of the Yang-Mills Equations. Physics Letters B, 59, 85-87. [Google Scholar] [CrossRef]
[8]	Hooft, G. (1976) Symmetry Breaking through Bell-Jackiw Anomalies. Physical Review Letters, 37, 8-11. [Google Scholar] [CrossRef]
[9]	Jackiw, R. and Rebbi, C. (1976) Vacuum Periodicity in a Yang-Mills Quantum Theory. Physical Review Letters, 37, 172-175. [Google Scholar] [CrossRef]
[10]	Callan Jr., C.G., Dashen, R.F. and Gross, D.J. (1976) The Struc-ture of the Gauge Theory Vacuum. Physics Letters B, 63, 334-340. [Google Scholar] [CrossRef]
[11]	Callan Jr., C.G. and Coleman, S.R. (1977) The Fate of the False Vacuum. II. First Quantum Corrections. Physical Review D, 16, 1762-1768. [Google Scholar] [CrossRef]
[12]	Fan, W. and Zhang, H. (2023) Non-Perturbative Instanton Effects in the Quartic and the Sextic Double-Well Potential by the Numerical Bootstrap Approach.
[13]	Fan, W. and Zhang, H. (2023) A Non-Perturbative Formula Unifying Double-Wells and Anharmonic Oscillators under the Numerical Bootstrap Approach.
[14]	Lin, H.W. (2020) Bootstraps to Strings: Solving Random Matrix Models with Positivity. Journal of High Energy Physics, 2020, 1-28. [Google Scholar] [CrossRef]
[15]	Bissi, A., Sinha, A. and Zhou, X. (2022) Selected Topics in Analytic Conformal Bootstrap: A Guided Journey. Physics Reports, 991, 1-89. [Google Scholar] [CrossRef]
[16]	Poland, D., Rychkov, S. and Vichi, A. (2019) The Conformal Bootstrap: Theory, Numerical Techniques, and Applications. Reviews of Modern Physics, 91, Article ID: 015002. [Google Scholar] [CrossRef]
[17]	Li, W. (2018) Inverse Bootstrapping Conformal Field Theo-ries. Journal of High Energy Physics, 2018, Article No. 77. [Google Scholar] [CrossRef]
[18]	El-Showk, S., Paulos, M.F., Poland, D., Rychkov, S., Sim-mons-Duffin, D. and Vichi, A. (2012) Solving the 3D Ising Model with the Conformal Bootstrap. Physical Review D, 86, Article ID: 025022. [Google Scholar] [CrossRef]
[19]	Han, X., Hartnoll, S.A. and Kruthoff, J. (2020) Bootstrapping Matrix Quantum Mechanics. Physical Review Letters, 125, Article ID: 041601. [Google Scholar] [CrossRef]
[20]	Aikawa, Y., Morita, T. and Yoshimura, K. (2022) Bootstrap Method in Harmonic Oscillator. Physics Letters B, 833, Article ID: 137305. [Google Scholar] [CrossRef]
[21]	Berenstein, D. and Hulsey, G. (2022) Bootstrapping More QM Systems. Journal of Physics A: Mathematical and Theoretical, 55, Article ID: 275304. [Google Scholar] [CrossRef]
[22]	Bhattacharya, J., Das, D., Das, S.K., Jha, A.K. and Kundu, M. (2021) Numerical Bootstrap in Quantum Mechanics. Physics Letters B, 823, Article ID: 136785. [Google Scholar] [CrossRef]
[23]	Du, B., Huang M. and Zeng, P. (2022) Bootstrapping Cala-bi-Yau Quantum Mechanics. Communications in Theoretical Physics, 74, Article ID: 095801. [Google Scholar] [CrossRef]
[24]	Aikawa, Y., Morita, T. and Yoshimura, K. (2022) Application of Bootstrap to a θ Term. Physical Review D, 105, Article ID: 085017. [Google Scholar] [CrossRef]
[25]	Li, W. (2022) Null Bootstrap for Non-Hermitian Hamiltonians. Physical Review D, 106, Article ID: 125021. [Google Scholar] [CrossRef]
[26]	Sachdev, S. (1999) Quantum Phase Transitions. Physics World, 12, Article No. 33. [Google Scholar] [CrossRef]
[27]	Buckingham, M. and Fairbank, W. (1961) Chapter III. The Nature of the λ-Transition in Liquid Helium. In: Progress in Low Temperature Physics, Vol. 3, Elsevier, Amsterdam, 80-112. [Google Scholar] [CrossRef]
[28]	Lipatov, L.N. (1977) Divergence of Perturbation Series and Pseudoparticles. JETP Letters, 25, 104-107.
[29]	Brezin, E., Le Guillou, J.C. and Zinn-Justin, J. (1977) Perturbation Theory at Large Order. I. The φ2N Interaction. Physical Review D, 15, 1544-1557. [Google Scholar] [CrossRef]
[30]	Brezin, E., Le Guillou, J.C. and Zinn-Justin, J. (1977) Perturbation Theory at Large Order. II. Role of the Vacuum Instability. Physical Review D, Particles Fields, 15, 1558-1564. [Google Scholar] [CrossRef]
[31]	Zinn-Justin, J. (1979) X. Large Order Estimates in Perturbation Theory. Physics Reports, 49, 205-213. [Google Scholar] [CrossRef]

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