弦論歷史

弦論是將結合量子力學廣義相對論萬有理論理論物理學

弦論已得到數十年的深入研究,在歷史上出現了兩次超弦革命。在眾多研究人員共同努力下,弦理論早已與量子引力粒子物理凝聚態物理宇宙學純數學融匯貫通,發展成了一個廣泛多樣的學科。

S矩陣理論

維爾納·海森堡1943年一項研究計劃說[1]弦理論是S-矩陣理論的產物。[2]

約翰·惠勒于1937年引入S矩阵后,[3][4]從1950年後期到60年代,許多著名的理論家都接受並提倡。但該領域在70年代中期被邊緣化並被丟棄[5] 並在80年代被量子色動力學取代了。[6]

1943年,维尔纳·海森堡提出了S矩阵理论作为粒子相互作用的原理。[7]

雷格理論

1950年代後期,不同人各自發現了存在許多自旋更高的強相互作用粒子,這很明顯非基本粒子

雙共振模型

加布里埃萊·韋內齊亞諾意大利弦論先驅於1968年建構。

玻色弦理論超弦理論

玻色弦理論

1974年,約翰·席瓦茲若埃爾·捨克[37]米谷民明[38]先驅建構。

他們研究了玻色子弦振動,發現特性與引力子匹配。這導致了玻色子弦理論的發展。

弦理論是根據泊里雅科夫作用量[39]描述弦如何在空間和時間中移動。像彈簧一樣,弦往往會收縮以最小化其勢能,但能量守恆會阻止它們消失而振盪。通過將量子力學應用於弦,可以推斷出弦不同振動模式,每個振動狀態又皆是不同粒子。每粒粒子的質量,以及相互作用的方式,都是由弦的振動方式決定。

第一次超弦革命

第二次超弦革命

1990年代,受對偶性的啓發,愛德華·維頓造了個11維的M理論,把5種版本的10維超弦理論與11維超重力論推演成M理論的6個形。這些發現帶動了第二次超弦革命有數百篇論文出現。

千禧年

參考

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進一步閱讀

  • Paul Frampton. . Frontiers in Physics, W. A. Benjamin. 1974. ISBN 978-0-8053-2581-2.
  • Joel A. Shapiro. . 2007. arXiv:0711.3448可免费查阅 [hep-th].
  • John H. Schwarz. . 2012. arXiv:1201.0981可免费查阅 [physics.hist-ph].
  • Andrea Cappelli; Elena Castellani; Filippo Colomo; Paolo Di Vecchia. . Cambridge University Press. 2012. ISBN 978-0-521-19790-8.
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