We demonstrate coherent control over the photoelectron circular dichroism in randomly 
oriented chiral molecules, based on quantum interference between multiple photoionization 
pathways. To significantly enhance the chiral signature, we use a finite manifold of 
indistinguishable (1+1’) resonantly enhanced multiphoton ionization pathways interfering at 
a common photoelectron energy but probing different intermediate states. We show that 
this coherent control mechanism maximizes the number of molecular states that 
constructively contribute to the dichroism at an optimal photoelectron energy and thus 
outperforms other schemes, including interference between opposite-parity pathways driven 
by bichromatic (w , 2w) fields as well as sequential pump-probe ionization.