- #1
earth2
- 82
- 0
Hi guys,
I have to brush up my knowledge about self-dual Yang Mills and I'm reading an ancient paper by Yang about it...and of course I'm stuck...although Yang writes 'it is easy to see that'...
Ok, so the self-duality condition of the YM field strength tensor is defined as
2F_{\mu\nu}=\epsilon_{\mu\nu\rho\sigma}F^{\rho\sigma}.
If I know go to complex coords defined by
\sqrt{2}y=x_1+i x_2 \quad \sqrt{2}\bar{y}=x_1-i x_2
and
\sqrt{2}z=x_3+i x_3 \quad \sqrt{2}\bar{z}=x_3-i x_4
the metric transforms to
g_{y\bar{y}}=g_{\bar{y}{y}}=g_{z\bar{z}}=g_{\bar{z}{z}}=1. So far I've understood everything. But then Yang says it's easy to see that the self-duality condition becomes
F_{yz}=0=F_{\bar{y}\bar{z}}
F_{y\bar{y}}=F_{z\bar{z}}
The question know is: how do i see the last two equations? Does the epsilon tensor somehow transform if i go to these complex coords?
Cheers,
earth2
I have to brush up my knowledge about self-dual Yang Mills and I'm reading an ancient paper by Yang about it...and of course I'm stuck...although Yang writes 'it is easy to see that'...
Ok, so the self-duality condition of the YM field strength tensor is defined as
2F_{\mu\nu}=\epsilon_{\mu\nu\rho\sigma}F^{\rho\sigma}.
If I know go to complex coords defined by
\sqrt{2}y=x_1+i x_2 \quad \sqrt{2}\bar{y}=x_1-i x_2
and
\sqrt{2}z=x_3+i x_3 \quad \sqrt{2}\bar{z}=x_3-i x_4
the metric transforms to
g_{y\bar{y}}=g_{\bar{y}{y}}=g_{z\bar{z}}=g_{\bar{z}{z}}=1. So far I've understood everything. But then Yang says it's easy to see that the self-duality condition becomes
F_{yz}=0=F_{\bar{y}\bar{z}}
F_{y\bar{y}}=F_{z\bar{z}}
The question know is: how do i see the last two equations? Does the epsilon tensor somehow transform if i go to these complex coords?
Cheers,
earth2