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Author: Gabriele Canzi
Publisher:
ISBN: 9781321011050
Category :
Languages : en
Pages : 204
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Book Description
Understanding the intricacies of inner sphere electron transfer has been a challenge for nearly 50 years. Since the preparation of the Creutz-Taube ion extensive research in inorganic mixed valence systems has been performed. We employ coalescence of [nu](CO) bandshapes observed in the 1-D infrared (IR) spectra of mixed valence complexes to determine rate constants of electron transfer (ET). Herein we report synthesis, characterization, and spectroscopy of Ru3O clusters bound to metallic nanoparticles, and report ET rates in the "ultrafast" regime. We observe that ET rates are faster when there is favorable electronic alignment between the Ru clusters and the Au nanoparticle. In addition, results show that ground state ET rate constants that are in the "ultrafast" regime depend on the pre-exponential term within the frequency factor, [nu]N not the activation energy as expected in a system undergoing ergodic electron transfer. We extended our knowledge of these complexes by studying ET at a semiconducting nanoparticle interface. Working in collaboration with Prof. Emily Weiss at Northwestern University, a complementary view of the parameters that govern ET in such systems has been developed by investigating ET rates between the triruthenium clusters and QDs. The photoinduced electron transfer rate from photoexcited CdSe QDs to triruthenium clusters having either a pyridine-4-carboxylic acid or a 4-mercaptopyridine linkage are reported. Results show that the intrinsic charge separation rate constant (kCS,int), is approximately seven times faster for a thiol linked cluster compared to a nicotinic acid bound cluster. Thus the charge transfer rates between colloidal quantum dots and redox-active ligands adsorbed to their surfaces can be tuned through the choice of the coordinating headgroup of the ligand. We report that exchange of electrons across hydrogen bonds can increase the strength of typically weak interactions. A thermodynamically stable mixed valence dimer is obtained upon the one electron reduction of a Ru3O cluster with a isonicotinic acid ancillary ligand. Observed intervalence charge transfer bands (IVCT) indicate significant coupling between the two Ru centers through linked by a hydrogen bonding interaction. The IVCT bands are found to be best explained by a semi-classical 3-state model, further highlighting the importance of the bridging interaction in these systems. Additionally, we report that the electronic coupling between two metal centers can be modulated by simple ancillary ligand substitution. The wavefunction overlap of two metal centers bridged by a hydrogen bond is found to be non-zero. We report a series of new Ru3O clusters with ancillary ligands capable of pi-stacking in solution upon a single electron reduction. Large splittings are observed berween the reductions in the electrochemical responses of these newly synthesized systems. The effects on the electrochemical splitting of the reduction waves by donating and withdrawing ligands on the "bridge" are compared. A crystal structure of the ground state shows no significant evidence of pi-pi interaction between clusters in solution. The major themes of this thesis are the role of electronic coupling, Hab, on long range ET in supramolecular mixed valence systems, and the importance of the bridging interaction in modulating Hab in these systems.
Author: Gabriele Canzi
Publisher:
ISBN: 9781321011050
Category :
Languages : en
Pages : 204
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Book Description
Understanding the intricacies of inner sphere electron transfer has been a challenge for nearly 50 years. Since the preparation of the Creutz-Taube ion extensive research in inorganic mixed valence systems has been performed. We employ coalescence of [nu](CO) bandshapes observed in the 1-D infrared (IR) spectra of mixed valence complexes to determine rate constants of electron transfer (ET). Herein we report synthesis, characterization, and spectroscopy of Ru3O clusters bound to metallic nanoparticles, and report ET rates in the "ultrafast" regime. We observe that ET rates are faster when there is favorable electronic alignment between the Ru clusters and the Au nanoparticle. In addition, results show that ground state ET rate constants that are in the "ultrafast" regime depend on the pre-exponential term within the frequency factor, [nu]N not the activation energy as expected in a system undergoing ergodic electron transfer. We extended our knowledge of these complexes by studying ET at a semiconducting nanoparticle interface. Working in collaboration with Prof. Emily Weiss at Northwestern University, a complementary view of the parameters that govern ET in such systems has been developed by investigating ET rates between the triruthenium clusters and QDs. The photoinduced electron transfer rate from photoexcited CdSe QDs to triruthenium clusters having either a pyridine-4-carboxylic acid or a 4-mercaptopyridine linkage are reported. Results show that the intrinsic charge separation rate constant (kCS,int), is approximately seven times faster for a thiol linked cluster compared to a nicotinic acid bound cluster. Thus the charge transfer rates between colloidal quantum dots and redox-active ligands adsorbed to their surfaces can be tuned through the choice of the coordinating headgroup of the ligand. We report that exchange of electrons across hydrogen bonds can increase the strength of typically weak interactions. A thermodynamically stable mixed valence dimer is obtained upon the one electron reduction of a Ru3O cluster with a isonicotinic acid ancillary ligand. Observed intervalence charge transfer bands (IVCT) indicate significant coupling between the two Ru centers through linked by a hydrogen bonding interaction. The IVCT bands are found to be best explained by a semi-classical 3-state model, further highlighting the importance of the bridging interaction in these systems. Additionally, we report that the electronic coupling between two metal centers can be modulated by simple ancillary ligand substitution. The wavefunction overlap of two metal centers bridged by a hydrogen bond is found to be non-zero. We report a series of new Ru3O clusters with ancillary ligands capable of pi-stacking in solution upon a single electron reduction. Large splittings are observed berween the reductions in the electrochemical responses of these newly synthesized systems. The effects on the electrochemical splitting of the reduction waves by donating and withdrawing ligands on the "bridge" are compared. A crystal structure of the ground state shows no significant evidence of pi-pi interaction between clusters in solution. The major themes of this thesis are the role of electronic coupling, Hab, on long range ET in supramolecular mixed valence systems, and the importance of the bridging interaction in modulating Hab in these systems.
Author: Kamran T Mahmudov
Publisher: Royal Society of Chemistry
ISBN: 1788014685
Category : Science
Languages : en
Pages : 676
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Book Description
This book provides an overview of the role of different types of noncovalent interactions in both homogeneous and heterogeneous catalysis.
Author: Abel M. Maharramov
Publisher: John Wiley & Sons
ISBN: 1119113857
Category : Science
Languages : en
Pages : 481
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Book Description
This book aims to overview the role of non-covalent interactions, such as hydrogen and halogen bonding, π-π, π-anion and electrostatic interactions, hydrophobic effects and van der Waals forces in the synthesis of organic and inorganic compounds, as well as in design of new crystals and function materials. The proposed book should allow to combine, in a systematic way, recent advances on the application of non-covalent interactions in synthesis and design of new compounds and functional materials with significance in Inorganic, Organic, Coordination, Organometallic, Pharmaceutical, Biological and Material Chemistries. Therefore, it should present a multi- and interdisciplinary character assuring a rather broad scope. We believe it will be of interest to a wide range of academic and research staff concerning the synthesis of new compounds, catalysis and materials. Each chapter will be written by authors who are well known experts in their respective fields.
Author: Pavel Hobza
Publisher: Royal Society of Chemistry
ISBN: 1847558534
Category : Science
Languages : en
Pages : 239
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Book Description
Co-authored by an experimentalist (Klaus M3ller-Dethlefs ) and theoretician (Pavel Hobza), the aim of this book is to provide a general introduction into the science behind non-covalent interactions and molecular complexes using some important experimental and theoretical methods and approaches.
Author: Jonathan W. Steed
Publisher: John Wiley & Sons
ISBN: 9780470858707
Category : Science
Languages : en
Pages : 320
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Book Description
Supramolecular chemistry and nanochemistry are two strongly interrelated cutting edge frontiers in research in the chemical sciences. The results of recent work in the area are now an increasing part of modern degree courses and hugely important to researchers. Core Concepts in Supramolecular Chemistry and Nanochemistry clearly outlines the fundamentals that underlie supramolecular chemistry and nanochemistry and takes an umbrella view of the whole area. This concise textbook traces the fascinating modern practice of the chemistry of the non-covalent bond from its fundamental origins through to it expression in the emergence of nanochemistry. Fusing synthetic materials and supramolecular chemistry with crystal engineering and the emerging principles of nanotechnology, the book is an ideal introduction to current chemical thought for researchers and a superb resource for students entering these exciting areas for the first time. The book builds from first principles rather than adopting a review style and includes key references to guide the reader through influential work. supplementary website featuring powerpoint slides of the figures in the book further references in each chapter builds from first principles rather than adopting a review style includes chapter on nanochemistry clear diagrams to highlight basic principles
Author: Alberto Otero de la Roza
Publisher: Elsevier
ISBN: 0128098368
Category : Science
Languages : en
Pages : 478
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Book Description
Non-covalent Interactions in Quantum Chemistry and Physics: Theory and Applications provides an entry point for newcomers and a standard reference for researchers publishing in the area of non-covalent interactions. Written by the leading experts in this field, the book enables experienced researchers to keep up with the most recent developments, emerging methods, and relevant applications. The book gives a comprehensive, in-depth overview of the available quantum-chemistry methods for intermolecular interactions and details the most relevant fields of application for those techniques. Theory and applications are put side-by-side, which allows the reader to gauge the strengths and weaknesses of different computational techniques. - Summarizes the state-of-the-art in the computational intermolecular interactions field in a comprehensive work - Introduces students and researchers from related fields to the topic of computational non-covalent interactions, providing a single unified source of information - Presents the theoretical foundations of current quantum mechanical methods alongside a collection of examples on how they can be applied to solve practical problems
Author: Tennyson L Doane (III.)
Publisher:
ISBN:
Category :
Languages : en
Pages : 192
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Book Description
Nanomedicine has shown great promise for the treatment of a variety of complex diseases including cancer. The use of nanomaterials for non-covalent drug delivery has shown great success in the delivery of photodynamic therapy drugs in animal models, and has great potential as a general delivery vector for hydrophobic drugs. A detailed understanding of what physical forces dictate efficacy in the loading, transport, and delivery of non-covalent drugs is required for optimization and clinical translation. This thesis examines the non-covalent interactions between silicon phthalocyanine 4 (Pc 4) and polyethylene glycol coated gold nanoparticles (PEGylated Au NPs) through photophysics and transport studies. A detailed investigation of Pc 4{u2019}s photophysical behavior in water both with and without Au NPs is presented, elucidating the role of intramolecular photoinduced electron transfer and aggregation behavior. Gel electrophoresis studies of PEGylated Au NPs described in this work provide insights on fundamental physical properties of NPs as well as the local environment through which they translate. This thesis provides a zbottom-up" approach to non-covalent drug delivery which will be helpful in translating non-covalent drug delivery to more complex systems.
Author: Say Lee Teh
Publisher:
ISBN:
Category :
Languages : en
Pages : 146
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Book Description
The work presented in this dissertation attempts to form an understanding of the importance of polymer connectivity and nanoparticle shape and curvature on the formation of non-covalent interactions between polymer and nanoparticles by monitoring the dispersion of nanoparticles in copolymers containing functionalities that can form non-covalent interactions with carbon nanoparticles. The first portion of this study is to gain a fundamental understanding of the role of electron donating/withdrawing moieties on the dispersion of the fullerenes in copolymers. UV-Vis spectroscopy and x-ray diffraction were used to quantify the miscibility limit of C60 fullerene with the incorporation of electron donor-acceptor interactions (EDA) between the polymer and fullerene. The miscibility and dispersion of the nanoparticles in a polymer matrix are interpreted to indicate the extent of intermolecular interactions, in this case non-covalent EDA interactions. Experimental data indicate that the presence of a minority of interacting functional groups within the polymer chains leads to an optimum interaction between polymer and fullerene. This is further affirmed by density functional theory (DFT) calculations that specify the binding energy between interacting monomers and fullerenes. The second portion focuses on the impact of sample preparation on the dispersion of graphene nanocomposites. Visualization and transparency are used to quantify the dispersion of graphene in the polymer matrix. In addition, differential scanning Calorimetry (DSC) also provides insight into the efficiency of the preparation process in forming a homogeneous sample, where rapid precipitation and solvent evaporation are studied. Examining the change in glass transition temperature, T[subscript g], with nanoparticle addition also provides insight into the level of interaction and dispersion in the graphene nanocomposites. The approach of utilizing non-covalent interactions to enhance the dispersion of polymer nanocomposites is realized by varying the functional group in the copolymer chains, while the impact of nanoparticle shape is also examined. The optimum enhancement of dispersion is interpreted in terms of the improvement of interaction between polymer and nanocomposites. This interpretation leads to the conclusion that chain connectivity and the ability of the polymer to conform to the nanoparticle shape are two important factors that govern the formation of non-covalent interactions in polymer nanocomposites.
Author: Andrey Karshikoff
Publisher: World Scientific Publishing Company
ISBN: 9789811228087
Category : Science
Languages : en
Pages : 446
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Book Description
"This interdisciplinary book unites comprehensive considerations of the physics of non-covalent interactions with the specificity of their biochemical application in protein sciences, succeeding where pure physics and biochemical textbooks have failed. This second edition includes new chapters on intrinsically disordered proteins, microcalorimetry of proteins, cold denaturation, thermodynamic stability and thermal adaptability of proteins"--
Author: Bradley Carroll Miller
Publisher:
ISBN:
Category : Carbon nanotubes
Languages : en
Pages : 157
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Book Description
Low-loading polymer nanocomposites (PNC) are an area of great interest in polymer science. As nanoparticles (NP) are typically expensive in comparison to matrix materials; the low loading regime makes the most efficient use of materials, and represents the optimum for realizing cost effective, high-performance PNCs. However, formulating effective low-loading composites is not without challenges. In addition to the typical requirement of good dispersion for efficient translation of NP properties to the bulk, low-loading composites can sometimes exhibit anomalous (non-classical) dynamics, and unpredictable properties. It is within this context that this thesis aims to examine the effects of NP geometry and softness on the occurrence and nature of anomalous melt dynamics in low-loading PNCs. The first project presented in this thesis outlines the synthesis and characterization of few-layer graphene (FLG) used in subsequent dynamics studies. From graphite to exfoliated graphite oxide, chemically reduced FLG, and annealed FLG; composition and optoelectric persistence width were tracked through elemental analysis and Raman spectroscopy respectively. A profilometic analysis of some samples was performed using atomic force microscopy. Finally, spectroscopic and compositional information were combined with a geometric growth model to yield a scaled empirical formula that is simultaneously indicative of both compositional purity and optoelectric grade. Next, PNC melt dynamics were probed for low-loading PNCs filled with fullerenes, carbon nanotubes, and FLG. Graphitic nanoparticles with at least one common dimension, an identical series of styrene-acrylonitrile co-polymers matrices, and identical composite processing conditions were used to form a ceteris paribus assessment of the effect of NP geometry on PNC melt dynamics under conditions favorable for anomalous viscoelastic behavior. Rheometry and NMR relaxometry were used to probe the dynamics on both the bulk and local scale. Bulk and local, segmental dynamics were combined to create segmental scale model (with and without attractive NP-polymer interactions) describing the origin of anomalous viscoelastic behavior in the bulk. Finally, neutron reflectivity was used to probe matrix self-diffusion in low-loading PNCs of polystyrene (PS) filled with novel, PS-based, soft, nanoparticles. The effect of NP softness on the diffusive dynamics in PNCs is examined.
