2D Quantum Gravity in the Proper-Time Gauge

Ryuichi Nakayama

2D Quantum Gravity in the Proper-Time Gauge

Ryuichi Nakayama

Abstract

A two-loop (cylinder) amplitude of the 2d pure gravity theory is obtained in the proper-time gauge ($g_{00}=1$, $g_{01}=g_{10}=0$) in the continuum formulation. The constraint $T_{01}=0$ is solved and used to reduce the problem of field theory to that of quantum mechanics. This reduction can also be proved by using a conformal Ward identity. The amplitude depends on the lengths $l_1, l_2$ of the boundaries, the proper time $T$ and a non-negative integer $m$ associated with winding modes around the boundaries.

2D Quantum Gravity in the Proper-Time Gauge

Abstract

A two-loop (cylinder) amplitude of the 2d pure gravity theory is obtained in the proper-time gauge (

) in the continuum formulation. The constraint

is solved and used to reduce the problem of field theory to that of quantum mechanics. This reduction can also be proved by using a conformal Ward identity. The amplitude depends on the lengths

of the boundaries, the proper time

and a non-negative integer

associated with winding modes around the boundaries.

2D Quantum Gravity in the Proper-Time Gauge

Abstract

2D Quantum Gravity in the Proper-Time Gauge

Abstract

Paper Structure