Rotaxanes and Photovoltaic Materials Based on Pi-Conjugated Donors and Acceptors: Toward Energy Transduction on the Nanoscale

The flow of energy between its various forms is central to our understanding of virtually all natural phenomena, from the origins and fate of the universe to the mechanisms that underpin Life. Therefore, a deeper fundamental understanding of how to manage energy processes at the molecular scale will open new doors in science and technology. This dissertation describes organic molecules and materials that are capable of transducing various forms of energy on the nanoscale, namely, a class of mechanically interlocked molecules known as rotaxanes for electrochemical-to-mechanical energy transduction (Part I), and a class of thin films known as organic photovoltaics (OPVs) for solar-to-electric energy transduction (Part II). These materials are all based on conjugated molecules with a capacity to donate or accept pi-electrons. A contemporary challenge in molecular nanotechnology is the development of artificial molecular machines (AMMs) that mimic the ability of motor proteins (e.g. myosin, kinesin) to perform mechanical work by leveraging a combination of energy sources and rich structural chemistry. Part I describes the synthesis, characterization, molecular dynamics, and switching properties of a series of `daisy chain' and oligorotaxane AMM prototypes. All compounds are templated by charge transfer and hydrogen bonding interactions between pi-associated 1,5-dioxynaphthlene donors appended with polyether groups and pi-acceptors of either neutral (naphthalenediimide) or charged (4,4´-bipyridinium) varieties, and are synthesized using efficient one-pot copper(I)-catalyzed azide-alkyne cycloaddition `click chemistry' protocols. The interlocked architectures of these rotaxanes enable them to express sophisticated secondary structures (i.e. foldamers) and mechanical motions in solution, which have been elucidated using dynamic 1H NMR spectroscopy. Furthermore, molecular dynamics simulations, cyclic voltammetry, and spectroelectrochemistry experiments have demonstrated that the muscle-like contractile-extensile motions of the daisy chains can be controlled by redox or thermal stimuli. It is concluded that donor-acceptor daisy chains and oligorotaxanes of unprecendented complexity can be readily prepared using click chemistry and actuated in solution. Motivated by the global demand for low-cost renewable energy, novel pi-donor molecules based on thiophene and diketopyrrolopyrrole (DPP) moieties are investigated in the context of thin-film materials for OPV technologies in Part II. Homologous families of small-molecule donors have been synthesized to investigate the effects of various molecular design principles on the morphological, optical, electronic, and photovoltaic properties of the corresponding thin-film materials. This strategy has been executed in the context of inorganic-organic hybrid OPVs and also more conventional bulk heterojunction (BHJ) OPVs. In the former case, a series of terthiophene surfactants with systematic variations in valency, geometry, and flexibility are electrodeposited on transparent electrodes from aqueous solutions to yield lamellar Zn(OH)2 materials with nanoscale periodicity, which are characterized by scanning electron miscroscopy and two-dimensional grazing incidence X-ray scattering. It is concluded that monovalent, flexible, linear surfactants yield the most dense and anisotropic nanostructures that are ideal for OPVs. For BHJ OPVs, the family of compounds under investigation are small molecule (SM) donors based on electron-rich heterocyclic acenes (benzodithiophene, benzodifuran, naphtho-dithiophene) and electron-poor thiophene-flanked DPP units. Single crystal X-ray structures of the SM donors are compared with morphological, hole mobility, photovoltaic efficiency data on their blends with a common fullerene acceptor to elucidate the optimal molecular design principles for this class of OPVs. It is concluded that the best-performing molecules have a symmetric architecture in which the central acene core comprises an extended pi-system.