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引用次数: 1
摘要
在这篇文章中,我们试图给出一个性能很好的简单量子引力拉格朗日量。非极化截面的费曼微积分,以及相关的图,表现良好。该操作可通过维度计数重新规范化。它暗示了无质量引力子的标准爱因斯坦引力。还需要做进一步的调查。1. 一个或多或少表现良好的4维量子引力拉格朗日量?注意身份1 R / D / 2 = + = + Rab[ΓΓ]4使用狄拉克或克利福德代数表示Γ=θ+θ∗一(θ)的基础上切线空间Tp在点p (X)和[θ∗)的基础上提出余切空间T∗p (X)在同一点p, e .嘉当的符号一样,谁写的度规g的veilbeins e gμμμ=θ为ν= eμ安倍δνb,δab克罗内克符号,我们有时会抑制减号或虚数单位我在下面。58 E.B. Torbrand Dhrif D / =Γ(∂μ+ωμμ+)=Γ∇Γ= eμΓ。因此,我们也得出θ∗D/ θ = θ∗(+R/)θ = θ∗θ +R。这里θ是引力子。这里我们抑制了一个项,包括一个耦合常数,16πG。注意这是希尔伯特-爱因斯坦作用s重力,爱因斯坦=∫
A more or less well behaved quantum gravity Lagrangean in dimension 4
In this article we try to give a simple Quantum Gravity Lagrangean that behaves quite well. Feynman calculus for unpolarized crosssections, and the diagrams involved, behave good. The action is renormalizable by dimension counting. It implies standard Einstein gravity for a massless graviton. Further investigations have to be done. 1. A More or Less Well Behaved Quantum Gravity Lagrangean in Dimension 4? Note the identity 1 D/ 2 = +R/ = +Rab [Γ,Γ] 4 using the Dirac or Clifford Algebra representation Γ = θ + θ∗a [θ] a ON basis on the tangent space Tp(X) over a point p and [θ ∗a] a raised ON basis on the cotangent space T ∗ p (X) over the same point p, just like in the notation of E. Cartan, who wrote the metric g in terms of the veilbeins eμ = θ a μ as gμν = e a μδabe b ν , δab the Kronecker delta, and We sometimes suppress a minus-sign or a imaginary unit i in the following. 58 E.B. Torbrand Dhrif D/ = Γ(∂μ + ωμ + Aμ) = Γ ∇a Γ = eμΓ . We thus also conclude θ∗D/ θ = θ∗( +R/ )θ = θ∗ θ +R with R the Ricci scalar. Here θ is the graviton or vierbein. Here we have suppressed a term, including a coupling constant, 16πG. Notice that this is the Hilbert-Einstein action SGravity,Einstein = ∫
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