LAUSR

Abstract Metal porphyrin and phthalocyanine have found variety of applications in catalysis, electronic and spintronic devices and photovoltaic cells, many of which rely on accurate position of the molecules and alignment of their electronic levels with respect to the substrate. The substrate and local environment affect significantly the electronic properties of these macrocyclic molecules. Computational simulations provide valuable insights for engineering the molecule–metal, molecule–molecule and molecule–ligand interfaces. In this review, we focus on adsorption of metal phthalocyanine, particularly iron phthalocyanine, on graphite, epitaxial graphene, and metal substrates. These systems show varied interfacial binding strength and chameleon-like molecular electronic structures. Spin of the molecules can be controlled by small ligands, and the ground state can be tuned between S = 1, S = 1/2 and S = 0. Inclusion of van der Waals interaction in the first-principles calculations is shown to be essential for accurate description of the interfaces.