高级搜索

化繁为简的局域化方法

downloadPDF

上一篇

下一篇

张欣宇. 2025: 化繁为简的局域化方法, 物理, 54(6): 396-403. doi: 10.7693/wl20250604
引用本文: 张欣宇. 2025: 化繁为简的局域化方法, 物理, 54(6): 396-403. doi: 10.7693/wl20250604
shu
ZHANG Xin-Yu. 2025: Localization methods:simplifying complexity, Physics, 54(6): 396-403. doi: 10.7693/wl20250604
Citation: ZHANG Xin-Yu. 2025: Localization methods:simplifying complexity, Physics, 54(6): 396-403. doi: 10.7693/wl20250604
shu

化繁为简的局域化方法

  • 浙江大学物理学院 浙江近代物理中心 杭州 310058

    • 通讯作者: 张欣宇,email:xinyu.zhang@zju.edu.cn
  • 基金项目:

    国家自然科学基金(批准号:12475073)资助项目

Localization methods:simplifying complexity

  • Zhejiang Institute of Modern Physics, School of Physics, Zhejiang University, Hangzhou 310058, China

    • Corresponding author: ZHANG Xin-Yu, xinyu.zhang@zju.edu.cn

  • 摘要: 量子场论的微扰论方法在解释物理学中的许多重要现象时面临失效的困境,而目前尚没有分析非微扰效应的一般理论框架。超对称的引入为突破这一瓶颈提供了关键路径。局域化方法充分利用超对称的特性,将无穷维泛函积分约化为方便处理的有限维积分、离散求和或矩阵积分,成为非微扰计算的核心工具。文章简要介绍局域化方法的基本思想,梳理该方法的发展脉络,揭示其在物理与数学交叉领域的深远影响。
    Abstract: Perturbative methods in quantum field theory often encounter limitations in explaining many crucial physical phenomena. Moreover, there remains a lack of general theoretical frameworks for analyzing non-perturbative effects. The introduction of supersymmetry provides a critical pathway to overcome this bottleneck. Leveraging the unique properties of supersymmetry, localization methods reduce infinite-dimensional functional integrals to manageable finite-dimensional integrals, discrete summations, or matrix integrals. This development has established localization methods as a cornerstone tool for non-perturbative computations. This article provides a concise overview of the fundamental principles of localization methods, traces their historical evolution, and highlights their profound implications at the intersection of physics and mathematics.
  • 加载中
  • 江云峰. 物理,2025,54(6):380
    周稀楠. 物理,2025,54(6):388
    顾杰. 物理,2025,54(6):404
    Birmingham D,Blau M,Rakowski M et al. Phys. Rept.,1991, 209:129
    Cordes S,Moore G,Ramgoolam S. Nucl. Phys. Proc. Suppl., 1995,41:184
    Pestun V et al. J. Phys.,2017,A50(44):440301
    Lefschetz S. Transactions of the American Mathematical Society, 1926,28:1
    Duistermaat J,Heckman G. Invent. Math.,1982,69:259
    Atiyah M,Bott R. Topology,1984,23:1
    Berline N,Vergne M C R. Acad. Sci.,Paris,Sér. I,1982, 295:539
    Witten E. Nucl. Phys.,1982,B202:253
    Witten E. J. Diff. Geom.,1982,17(4):661
    Alvarez-Gaume L. Commun. Math. Phys.,1983,90:161
    Friedan D,Windey P. Nucl. Phys. B,1984,235:395
    Floer A. Commun. Math. Phys.,1988,118(2):215
    Donaldson S. J. Diff. Geom.,1983,18(2):279
    Donaldson S. Topology,1990,29:257
    Atiyah M. Proc. Symp. Pure Math.,1988,48:285
    Witten E. Commun. Math. Phys.,1988,117:353
    Seiberg N,Witten E. Nucl. Phys.,1994,B426:19
    Witten E. Math. Res. Lett.,1994,1:769
    Moore G,Witten E. Adv. Theor. Math. Phys.,1997,1:298
    Moore G,Saxena V,Singh R. 2024,arXiv:2408.02744
    Vafa C,Witten E. Nucl. Phys.,1994,B431:3
    Kapustin A,Witten E. Commun. Num. Theor. Phys.,2007,1:1
    Witten E. Commun. Math. Phys.,1988,118:411
    Witten E. Phys. Lett. B,1988,206:601
    Labastida J,Pernici M,Witten E. Nucl. Phys.,1988,B310:611
    Rozansky L,Witten E. Selecta Math.,1997,3:401
    Nekrasov N. Adv. Theor. Math. Phys.,2003,7(5):831
    Seiberg N,Witten E. Nucl. Phys.,1994,B431:484
    Moore G,Nekrasov N,Shatashvili S. Commun. Math. Phys., 2000,209:97
    Nekrasov N,Okounkov A. Prog. Math.,2006,244:525
    Nekrasov N,Shadchin S. Commun. Math. Phys.,2004,252: 359
    Nekrasov N,Pestun V. SIGMA,2023,19:047
    Zhang X. Phys. Rev.,2019,D100(12):125015
    Bershadsky M,Cecotti S,Ooguri H et al. Commun. Math. Phys., 1994,165:311
    Iqbal A,Kozcaz C,Vafa C. JHEP,2009,10:069
    Manschot J,Moore G,Zhang X. JHEP,2020,06:150
    Alday L,Gaiotto D,Tachikawa Y. Lett. Math. Phys.,2010, 91:167
    Nekrasov N,Shatashvili S. 16th International Congress on Mathematical Physics (ICMP09),2009. p.265
    Nekrasov N. JHEP,2016,03:181
    Nekrasov N. 2017,arXiv:1711.11582
    Jeong S,Zhang X. Phys. Rev. D,2024,109(12):125006
    Jeong S,Zhang X. JHEP,2020,04:026
    Pestun V. Commun. Math. Phys.,2012,313:71
    Kapustin A,Willett B,Yaakov I. JHEP,2010,03:089
    Kim H,Kim S. JHEP,2013,05:144
    Källén J,Zabzine M. JHEP,2012,05:125
    Doroud N,Gomis J,Le Floch B et al. JHEP,2013,05:093
    Benini F,Cremonesi S. Commun. Math. Phys.,2015,334(3): 1483
    Hama N,Hosomichi K,Lee S. JHEP,2011,05:014
    Imamura Y,Yokoyama D. Phys. Rev. D,2012,85:025015
    Hama N,Hosomichi K. JHEP,2012,09:033
    Imamura Y. PTEP,2013,2013(7):073B01
    Kim H,Kim J,Kim S. 2012,arXiv:1211.0144
    Karlhede A,Rocek M. Phys. Lett. B,1988,212:51
    Johansen A. Int. J. Mod. Phys. A,1995,10:4325
    Blau M. JHEP,2000,11:023
    Festuccia G,Seiberg N. JHEP,2011,06:114
    Dumitrescu T,Festuccia G,Seiberg N. JHEP,2012,08:141
    Dumitrescu T,Festuccia G. JHEP,2013,01:072
  • 加载中
计量
  • 文章访问数:  34
  • HTML全文浏览数:  34
  • PDF下载数:  10
  • 施引文献:  0
出版历程
  • 收稿日期:  2025-04-07

化繁为简的局域化方法

    通讯作者: 张欣宇,email:xinyu.zhang@zju.edu.cn
  • 浙江大学物理学院 浙江近代物理中心 杭州 310058
  • 收稿日期:  2025-04-07
基金项目: 

摘要: 量子场论的微扰论方法在解释物理学中的许多重要现象时面临失效的困境,而目前尚没有分析非微扰效应的一般理论框架。超对称的引入为突破这一瓶颈提供了关键路径。局域化方法充分利用超对称的特性,将无穷维泛函积分约化为方便处理的有限维积分、离散求和或矩阵积分,成为非微扰计算的核心工具。文章简要介绍局域化方法的基本思想,梳理该方法的发展脉络,揭示其在物理与数学交叉领域的深远影响。

English Abstract

    全文HTML

参考文献 (62)

目录

/

返回文章
返回