Geometric Engineering and Almost Mathieu Operator
Abstract: The type IIA string theory on a non-compact Calabi-Yau geometry known as the local $\mathbb{P}{1} \times \mathbb{P}{1}$ gives rise to five-dimensional N =1 supersymmetric SU(2) gauge theory compactified on a circle, known as geometric engineering. So it is necessary to study the $\mathbb{P}{1} \times \mathbb{P}{1}$ in details. Since the spectrum of the local $\mathbb{P}{1} \times \mathbb{P}{1}$ can be written as $E=R{2}\left(\mathrm{e}{p}+\mathrm{e}{-p}\right)+\mathrm{e}{x}+\mathrm{e}{-x}$, then by the result of almost Mathieu operator, we show that: (1) when $R{2}<1$, the spectrum is absolutely continuous which meanings the medium is conductor. (2) when $1\le R{2}<e{\beta}$, the spectrum is singular continuous known as quantum Hall effect. (3) when $R{2}>e{\beta}$, the spectrum is almost surely pure point and exhibits Anderson localization. In other words, there are two phase transition points which one is $R{2}=1$ and the other one is $R{2}=e{\beta}$.
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