Low‐dimensional (LD) materials demonstrate intriguing optical properties, which lead to
applications in diverse fields, such as photonics, biomedicine and energy. Due to …

Insights from spectroscopic experiments led to the development of quantum mechanics as
the common theoretical framework for describing the physical and chemical properties of …

Quantum mechanics provides the most accurate microscopic description of the world around
us, yet the interface between quantum mechanics and biology is only now being explored …

The authors review the physics of ultrafast dynamics in semiconductors and their
heterostructures, including both the observed experimental phenomena and the theoretical …

Molecular aggregates are abundant in nature; they form spontaneously in concentrated
solutions and on surfaces and can be synthesized by supramolecular chemistry techniques …

This chapter gives an introduction to interacting many-body systems. Interaction effects give
rise to collective behavior, dominated by mean field effects, as well as to correlations. We …

Predicting the electronic structure of extended organic molecules constitutes an important
fundamental task of modern chemistry. Studies of electronic excitations, charge-transfer …

A theory for four-wave-mixing signals from molecular aggregates, which includes effects of
two-exciton states, static disorder, and coupling to a phonon bath with an arbitrary spectral …

The technological demand to push the gigahertz (109 hertz) switching speed limit of today's
magnetic memory and logic devices into the terahertz (1012 hertz) regime underlies the …

Many important molecular systems are made out of assemblies of coupled localized
chromophores. Examples are molecular crystals, 1-3 J aggregates, 4-8 biological light …