Conformal symmetry, its motivations, its applications

On a given space or spacetime ${\displaystyle M}$  with coordinates ${\displaystyle x^{\mu }}$ , distances are defined using a metric ${\displaystyle g_{\mu \nu }}$ . In particular, the length of an infinitesimal vector ${\displaystyle v^{\mu }}$  is ${\displaystyle \|v\|={\sqrt {g_{\mu \nu }v^{\mu }v^{\nu }}}}$ . If we know distances, we can also compute angles. The angle ${\displaystyle \theta }$  between two infinitesimal vectors ${\displaystyle v^{\mu },w^{\mu }}$  obeys

${\displaystyle \cos \theta ={\frac {g_{\mu \nu }v^{\mu }w^{\nu }}{{\sqrt {g_{\mu \nu }v^{\mu }v^{\nu }}}{\sqrt {g_{\mu \nu }w^{\mu }w^{\nu }}}}}}$ 

A map ${\displaystyle f:M\to M}$  is called an isometry if it preserves distances, equivalently if it preserves the metric:

${\displaystyle f{\text{ isometry }}\iff g_{\mu \nu }(f(x))df^{\mu }df^{\nu }=g_{\mu \nu }(x)dx^{\mu }dx^{\nu }}$ 

A map ${\displaystyle f:M\to M}$  is called a conformal transformation if it preserves angles. Any isometry is a conformal transformation, but the converse is not true. For any function ${\displaystyle \lambda :M\to \mathbb {R} }$ , the metrics ${\displaystyle g_{\mu \nu }}$  and ${\displaystyle \lambda g_{\mu \nu }}$  define the same angles. To preserve angles, a map therefore only needs to preserve the metric up to a scalar factor:

${\displaystyle f{\text{ conformal transformation }}\iff \exists \lambda ,\ g_{\mu \nu }(f(x))df^{\mu }df^{\nu }=\lambda (x)g_{\mu \nu }(x)dx^{\mu }dx^{\nu }}$ 

case of flat metric, dilations etc.

not conformal example. ${\displaystyle z^{2}}$ ? Not conformal at a point.

conformal symmetry: inv. under conf. transfo.

Now the metric is dynamical as well.

2d already special

String theory (while we are at it)