This book presents a multidisciplinary approach to single-molecule electronics. It includes a complete overview of the field, from the synthesis and design of molecular candidates to the prevalent experimental techniques, complemented by a detailed theoretical description. This all-inclusive strategy provides the reader with the much-needed perspective to fully understand the far-reaching ramifications of single-molecule electronics. In addition, a number of state-of-the-art topics are discussed, including single-molecule spectro-electrical methods, electrochemical DNA sequencing technology, and single-molecule chemical reactions. As a result of this integrative effort, this publication may be used as an introductory textbook to both graduate and advanced undergraduate students, as well as researchers with interests in single-molecule electronics, organic electronics, surface science, and nanoscience.

Due to the rapid growth in the electronics industry for over the last century, the demand for more advanced materials has been raised. As a result of this, the number of the scientific studies to develop new type of electronic materials has increased and new fields of research such as molecular electronics and nanotechnology are now established. The trend in the advances in electronics follows the miniaturisation of the electrical components and therefore introducing single or a few molecules into electronic devices has become an important topic. In this work, a summary of the new aspects/developments in the field of single-molecule electronics is presented. Symmetrical tolane compounds with thiol (SH), amino (NH2), pyridyl (Py) and cyano (CN) anchoring groups were synthesised and single-molecule conductances of those molecules were systematically compared. With the help of density functional theory (DFT) calculations, single-molecular junction formation mechanism is also identified. Oligoyne molecular wires with different anchoring groups are also synthesised and their electron transport properties at the single-molecule level are studied. The stability of the functional diaryltetrayne compounds is discussed and X-ray molecular structures of the stable tetraynes are presented. The effects of the molecular length and the anchoring group are discussed in detail. Additionally, oligoynes with methyl shielding of the carbon backbone are synthesised and their stability is discussed. Finally, length-persistent, conjugated OPE and tolane analogues with different molecular lengths and amine anchors were synthesised and their transport properties were investigated in quantum dot sensitised solar cells.

PPV materials are very stable and can be further functionalized along their main-chains, however due to shorter effective conjugations lengths (smaller than that of the oligoenes), the range of electronic tunability is smaller in these materials. In addition to this family of symmetric molecules other asymmetric oligoene molecules were synthesized as candidates for single-molecule rectification. These molecules allow different electronic coupling to the right and left electrodes, which may modulate their IV characteristics.

As functional elements in opto-electronic devices approach the singlemolecule limit, conducting organic molecular wires are the appropriate interconnects that enable transport of charges and charge-like particles such as excitons within the device. Reproducible syntheses and a thorough understanding of the underlying principles are therefore indispensable for applications like even smaller transistors, molecular machines and light-harvesting materials. Bringing together experiment and theory to enable applications in real-life devices, this handbook and ready reference provides essential information on how to control and direct charge transport. Readers can therefore obtain a balanced view of charge and exciton transport, covering characterization techniques such as spectroscopy and current measurements together with quantitative models. Researchers are thus able to improve the performance of newly developed devices, while an additional overview of synthesis methods highlights ways of producing different organic wires. Written with the following market in mind: chemists, molecular physicists, materials scientists and electrical engineers.

This book provides a comprehensive overview of the rapidly developing field of molecular electronics. It focuses on our present understanding of the electrical conduction in single-molecule circuits and provides a thorough introduction to the experimental techniques and theoretical concepts. It will also constitute as the first textbook-like introduction to both the experiment and theory of electronic transport through single atoms and molecules. In this sense, this publication will prove invaluable to both researchers and students interested in the field of nanoelectronics and nanoscience in general. Molecular Electronics is self-contained and unified in its presentation. It may be used as a textbook on nanoelectronics by graduate students and advanced undergraduates studying physics and chemistry. In addition, included are previously unpublished material that will help researchers gain a deeper understanding into the basic concepts involved in the field of molecular electronics.

The theory, methods, and practices needed to build molecules and supramolecular systems Using a synthetic approach to organic materials chemistry, this book sets forth tested and proven methods and practices that make it possible to engineer organic molecules offering special properties and functions. Throughout the book, plenty of real-world examples demonstrate the countless possibilities of creating one-of-a-kind molecules and supramolecular systems to support a broad range of applications. The book explores applications in both materials and bioorganic chemistry, including molecular electronics, energy storage, sensors, nanomedicine, and enzyme engineering. Organic Synthesis and Molecular Engineering consists of fourteen chapters, each one contributed by one or more leading international experts in the field. The contributions are based on a thorough review and analysis of the current literature as well as the authors' firsthand experience in the lab engineering new organic molecules. Designed as a practical lab reference, the book offers: Tested and proven synthetic approaches to organic materials chemistry Methods and practices to successfully engineer functionality into organic molecules Explanations of the principles and concepts underlying self-assembly and supramolecular chemistry Guidance in selecting appropriate structural units used in the design and synthesis of functional molecules and materials Coverage of the full range of applications in materials and bioorganic chemistry A full chapter on graphene, a new topic generating intense research Organic Synthesis and Molecular Engineering begins with core concepts, molecular building blocks, and synthetic tools. Next, it explores molecular electronics, supramolecular chemistry and self-assembly, graphene, and photoresponsive materials engineering. In short, it offers everything researchers need to fully grasp the underlying theory and then build new molecules and supramolecular systems.