Modeling nanoplasmonics from an atomistic point of view: from theory to applications

<br />The theoretical modeling of plasmonics is challenging due to the complex interplay&nbsp;between electromagnetic waves, the electronic properties of the material, and the&nbsp;geometrical arrangement of the substrate. In the last decades, the comprehension of&nbsp;plasmons related phenomena arising in noble metal nanostructures and in graphene&nbsp;has benefited from the development of several theoretical methods, which can be divided into two main categories: continuum and&nbsp;ab initio&nbsp;methods respectively. The&nbsp;first are based on classical electrodynamics principles and are limited to the study&nbsp;of systems with a simple shape only, because otherwise the resolution of Maxwell&rsquo;s&nbsp;equation would be impossible.In addition, they may fail when quantum effects&nbsp;have a predominant role on the optical properties of the system, such as in the&nbsp;case of complex-shape structures and nanojunctions.On the contrary,&nbsp;ab initio&nbsp;methods are able to overcome such limitations and return a precise description of&nbsp;plasmonic substrates. However, due to their high computational cost, such methods&nbsp;are constrained to systems of a few thousand of atoms. In this context, classical, yet&nbsp;atomistic models can predict results close to&nbsp;ab initio&nbsp;methods, while being computationally efficient such as continuum models. In this thesis, the optical properties of&nbsp;plasmonic nanostructures are investigated by using a classic, atomistic model called&nbsp;&omega;FQ, which has been developed by the research group I joined during my Ph.D.&nbsp;internship. In&nbsp;&omega;FQ, the charge interaction between the atoms of the nanostructure&nbsp;is modeled in terms of electric conduction between nearest neighbors via a simple&nbsp;Drude mechanism, which is modulated by a Fermi-like step function that mimics&nbsp;quantum tunneling effects. In this way,&nbsp;&omega;FQ is able to take into account quantum&nbsp;effects and returns results in agreement with&nbsp;ab initio&nbsp;references. In particular, the&nbsp;Thesis discusses the developments performed during my Ph.D. research activity to&nbsp;the initial formulation of the&nbsp;&omega;FQ model. Attention is firstly paid to the extension&nbsp;of&nbsp;&omega;FQ to model the optical properties of noble metal NPs which are characterized&nbsp;by interband effects. Then, the coupling between a molecular system, treated at the&nbsp;quantum mechanical level, and a plasmonic substrate, described by means of the&nbsp;&omega;FQ model, is presented and analysed. In this way, the modeling of the enhanced&nbsp;Raman spectrum of target molecules adsorbed on a plasmonic substrate becomes&nbsp;possible.<br />