天文随心听|讲述宇宙与人的故事

好学蜗牛

为你捕捉最新最快的天文前沿信息,你不知道的和你想知道的天文内容都在这里,一起加入天文随心听的大家庭吧,我们一起探索宇宙无穷的奥秘!你也可以关注微信公众号——科学大唠嗑——了解更多信息。 主播简介:好学蜗牛,蜗牛研习社创始人,二手天文学家,多年从事科学普及工作,曾策划并执行了2018年1月31日超级月亮直播并为央视各段新闻提供视频直播信号,网络及电视观看人数近2亿。 联系VX:haoxuewoniu

  1. 2時間前

    【第二季】162|【终结之问】与无法预知的风险共处

    参考文献 1. Turner, M. S., & Wilczek, F. (1982). Might our vacuum be metastable? Nature, 298, 633–634. 2. 马可·奥勒留.《沉思录》(Meditations). 中华书局. 3. 保罗·戴维斯(Paul Davies). (1994).《宇宙的最后三分钟》. 上海科学技术出版社. 4. Tegmark, M. (2003). Parallel Universes. Scientific American, 288(5), 40–51. 5. 英国《新科学家》杂志编辑部.《新科学漫游指南》. 科学出版社. 6. Wilczek, F. (2015). A Beautiful Question: Finding Nature’s Deep Design. Penguin Press. 7. Taleb, N. N. (2007). The Black Swan: The Impact of the Highly Improbable. Random House. [极低概率极大影响事件章节] 8. Coleman, S. (1977). Fate of the false vacuum: Semiclassical theory. Physical Review D, 15(10), 2929–2936. 9. Buttazzo, D., et al. (2013). Investigating the near-criticality of the Higgs boson. Journal of High Energy Physics, 2013, 089. 10. Espinosa, J. R., et al. (2013). Cosmological implications of the Higgs mass measurement. Journal of Cosmology and Astroparticle Physics, 2013(09), 032.

    10分

  2. 1日前

    【第二季】161|【终结之问】真空泡泡与多元宇宙

    参考文献 1. Coleman, S., & De Luccia, F. (1980). Gravitational effects on and of vacuum decay. Physical Review D, 21(12), 3305–3315. 2. Guth, A. H., & Weinberg, E. J. (1983). Could the universe have recovered from a slow first-order phase transition? Nuclear Physics B, 212(2), 321–364. 3. Freivogel, B., et al. (2009). Observational consequences of a landscape. Journal of High Energy Physics, 2006, 059. 4. Johnson, M. C., & Larfors, M. (2008). Field dynamics and tunneling in a flux landscape. Physical Review D, 78, 083534. 5. Quanta Magazine. (2015). Physicists Study How Universes Might Bubble Up and Collide. Quanta Magazine. 6. 阿兰·古斯(Alan Guth). (1997).《暴胀宇宙》(The Inflationary Universe). 上海科学技术出版社. 7. Linde, A. (1986). Eternally existing self-reproducing chaotic inflationary universe. Physics Letters B, 175(4), 395–400. 8. Hawking, S. W., & Moss, I. G. (1982). Supercooled phase transitions in the very early universe. Physics Letters B, 110(1), 35–38. 9. 保罗·戴维斯(Paul Davies). (1994).《宇宙的最后三分钟》. 上海科学技术出版社. 10. 英国《新科学家》杂志编辑部.《新科学漫游指南》. 科学出版社. [永恒暴胀与多元宇宙章节]

    10分

  3. 2日前

    【第二季】160|【终结之问】宇宙还能撑多久

    参考文献 1. Coleman, S. (1977). Fate of the false vacuum: Semiclassical theory. Physical Review D, 15(10), 2929–2936. 2. Coleman, S., & De Luccia, F. (1980). Gravitational effects on and of vacuum decay. Physical Review D, 21(12), 3305–3315. 3. Isidori, G., Ridolfi, G., & Strumia, A. (2001). On the metastability of the standard model vacuum. Nuclear Physics B, 609(3), 387–409. 4. 保罗·戴维斯(Paul Davies). (1994).《宇宙的最后三分钟》. 上海科学技术出版社. 5. Espinosa, J. R., et al. (2013). Cosmological implications of the Higgs mass measurement. Journal of Cosmology and Astroparticle Physics, 2013(09), 032. 6. Buttazzo, D., et al. (2013). Investigating the near-criticality of the Higgs boson. Journal of High Energy Physics, 2013, 089. 7. Turner, M. S., & Wilczek, F. (1982). Might our vacuum be metastable? Nature, 298, 633–634. 8. 泰森、斯特劳斯、戈特. (2016).《欢迎来到宇宙》. 人民邮电出版社. [量子隧穿章节] 9. 罗伯托·巴蒂斯顿. (2022).《宇宙的第一缕光》. 中信出版集团. 10. Quanta Magazine. (2014). Is the Universe Ripe for a Quantum Collapse? Quanta Magazine.

    9分

  4. 3日前

    【第二季】159|【终结之问】LHC与宇宙的命运

    参考文献 1. Degrassi, G., et al. (2012). Higgs mass and vacuum stability in the Standard Model at NNLO. Journal of High Energy Physics, 2012, 098. 2. Espinosa, J. R., et al. (2013). Cosmological implications of the Higgs mass measurement. Journal of Cosmology and Astroparticle Physics, 2013(09), 032. 3. ATLAS Collaboration & CMS Collaboration. (2015). Combined measurement of the Higgs boson mass. Physical Review Letters, 114, 191803. 4. Buttazzo, D., et al. (2013). Investigating the near-criticality of the Higgs boson. Journal of High Energy Physics, 2013, 089. 5. 罗伯托·巴蒂斯顿. (2022).《宇宙的第一缕光》. 中信出版集团. 6. 英国《新科学家》杂志编辑部.《新科学漫游指南》. 科学出版社. [希格斯场与真空稳定性章节] 7. Turner, M. S., & Wilczek, F. (1982). Is our vacuum metastable? Nature, 298, 633–634. 8. 保罗·戴维斯(Paul Davies). (1994).《宇宙的最后三分钟》. 上海科学技术出版社. 9. Quanta Magazine. (2013). Higgs Boson Discovery Could Mean the End of Universe—in 10 Billion Years. Quanta Magazine. 10. 赵忠贤主编.《自然百年物理经典》. 北京大学出版社. [顶夸克与希格斯场关系章节]

    11分

  5. 4日前

    【第二季】158|【终结之问】假真空

    参考文献 1. Coleman, S., & De Luccia, F. (1980). Gravitational effects on and of vacuum decay. Physical Review D, 21(12), 3305–3315. 2. Coleman, S. (1977). Fate of the false vacuum: Semiclassical theory. Physical Review D, 15(10), 2929–2936. 3. Turner, M. S., & Wilczek, F. (1982). Might our vacuum be metastable? Nature, 298, 633–634. 4. 保罗·戴维斯(Paul Davies). (1994).《宇宙的最后三分钟》(The Last Three Minutes). 上海科学技术出版社. 5. 泰森、斯特劳斯、戈特. (2016).《欢迎来到宇宙》(Welcome to the Universe). 人民邮电出版社. [量子隧穿章节] 6. 罗伯托·巴蒂斯顿. (2022).《宇宙的第一缕光》. 中信出版集团. [真空稳定性表述] 7. Degrassi, G., et al. (2012). Higgs mass and vacuum stability in the Standard Model at NNLO. Journal of High Energy Physics, 2012, 098. 8. Buttazzo, D., et al. (2013). Investigating the near-criticality of the Higgs boson. Journal of High Energy Physics, 2013, 089. 9. 英国《新科学家》杂志编辑部.《新科学漫游指南》. 科学出版社. [希格斯场与真空稳定性章节] 10. Quanta Magazine. (2014). Is the Universe Ripe for a Quantum Collapse? Quanta Magazine.

    12分

  6. 5月1日

    【第二季】156|【终结之问】大统一理论——五十年没有答案

    参考文献: 1. Georgi, H., & Glashow, S. L. (1974). Unity of All Elementary-Particle Forces. Physical Review Letters, 32(8), 438–441. 2. Dimopoulos, S., Raby, S., & Wilczek, F. (1981). Supersymmetry and the scale of unification. Physical Review D, 24(6), 1681–1683. 3. Murayama, H., & Pierce, A. (2002). Not even decoupling can save minimal supersymmetric SU(5). Physical Review D, 65(5), 055009. 4. Babu, K. S., & Mohapatra, R. N. (1993). Predictive neutrino spectrum in minimal SO(10) grand unification. Physical Review Letters, 70(20), 2845–2848. 5. Nishino, H., et al. (Super-Kamiokande Collaboration). (2012). Search for Nucleon Decay via p→e+π0 and p→μ+π0 in a Large Water Cherenkov Detector. Physical Review Letters, 102(14), 141801. 6. Hyper-Kamiokande Proto-Collaboration. (2018). Hyper-Kamiokande Design Report. arXiv:1805.04163. 7. Ellis, J., et al. (2020). Proton Decay: Still Waiting. International Journal of Modern Physics A, 35(17), 2030014. 8. Weinberg, S. (1980). Conceptual foundations of the unified theory of weak and electromagnetic interactions. Reviews of Modern Physics, 52(3), 515–523. 9. Langacker, P. (1981). Grand unified theories and proton decay. Physics Reports, 72(4), 185–385. 10. Glashow, S. L. (1980). Towards a Unified Theory: Threads in a Tapestry. Nobel Lecture. Retrieved from https://www.nobelprize.org/prizes/physics/1979/glashow/lecture/

    12分

  7. 4月30日

    【第二季】155|【终结之问】极端物质——中子星与夸克星

    参考文献: 1. Lattimer, J. M., & Prakash, M. (2007). Neutron star observations: Prognosis for equation of state constraints. Physics Reports, 442(1–6), 109–165. 2. Ozel, F., & Freire, P. (2016). Masses, Radii, and the Equation of State of Neutron Stars. Annual Review of Astronomy and Astrophysics, 54, 401–440. 3. Witten, E. (1984). Cosmic separation of phases. Physical Review D, 30(2), 272–285. 4. Alford, M. G., et al. (2008). Hybrid stars that masquerade as neutron stars. Nature, 445(7125), E7–E8. 5. Annala, E., et al. (2018). Gravitational-wave constraints on the neutron-star-matter equation of state. Physical Review Letters, 120(17), 172703. 6. Fonseca, E., et al. (2021). Refined Mass and Geometric Measurements of the High-mass PSR J0740+6620. The Astrophysical Journal Letters, 915(1), L12. 7. Baym, G., et al. (2018). From hadrons to quarks in neutron stars: a review. Reports on Progress in Physics, 81(5), 056902. 8. Hewish, A., et al. (1968). Observation of a Rapidly Pulsating Radio Source. Nature, 217(5130), 709–713. 9. Demorest, P. B., et al. (2010). A two-solar-mass neutron star measured using Shapiro delay. Nature, 467(7319), 1081–1083. 10. Shapiro, S. L., & Teukolsky, S. A. (1983). Black Holes, White Dwarfs, and Neutron Stars: The Physics of Compact Objects. Wiley. Chapters 9–10.

    11分

  8. 4月29日

    【第二季】154|【终结之问】质子消亡后的宇宙

    参考文献: 1. Adams, F. C., & Laughlin, G. (1997). A dying universe: The long-term fate and evolution of astrophysical objects. Reviews of Modern Physics, 69(2), 337–372. 2. Adams, F. C., & Laughlin, G. (1999). The Five Ages of the Universe: Inside the Physics of Eternity. Free Press. 3. Dyson, F. J. (1979). Time without end: Physics and biology in an open universe. Reviews of Modern Physics, 51(3), 447–460. 4. Barrow, J. D., & Tipler, F. J. (1986). The Anthropic Cosmological Principle. Oxford University Press. Chapter 10. 5. Frautschi, S. (1982). Entropy in an expanding universe. Science, 217(4560), 593–599. 6. Page, D. N. (1976). Particle emission rates from a black hole. Physical Review D, 13(2), 198–206. 7. Krauss, L. M., & Starkman, G. D. (2000). Life, the Universe, and Nothing. The Astrophysical Journal, 531(1), 22–30. 8. Penrose, R. (2010). Cycles of Time: An Extraordinary New View of the Universe. Bodley Head. Chapters 1–2. 9. Carroll, S. (2010). From Eternity to Here: The Quest for the Ultimate Theory of Time. Dutton. Part IV. 10. Rees, M. (1997). Before the Beginning: Our Universe and Others. Perseus Books. Chapter 11.

    11分
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为你捕捉最新最快的天文前沿信息,你不知道的和你想知道的天文内容都在这里,一起加入天文随心听的大家庭吧,我们一起探索宇宙无穷的奥秘!你也可以关注微信公众号——科学大唠嗑——了解更多信息。 主播简介:好学蜗牛,蜗牛研习社创始人,二手天文学家,多年从事科学普及工作,曾策划并执行了2018年1月31日超级月亮直播并为央视各段新闻提供视频直播信号,网络及电视观看人数近2亿。 联系VX:haoxuewoniu

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