Techniques for Measuring the Mechanical Properties of Organic Semiconductors
Techniques for Measuring the Mechanical Properties of Organic Semiconductors

Author: Daniel Rodriquez Jr.

Publisher:

Published: 2018

Total Pages: 156

ISBN-13:

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Mechanical flexibility and deformability are at the core of the advantages offered by organic semiconductors. Therefore, an in-depth understanding of the mechanical properties of these materials is crucial to the design of robust organic electronic devices such as solar cells, sensors, and displays. Since these devices are typically fabricated as thin films, on the order of 200 nm, it can be difficult to measure the mechanical properties using traditional techniques, such as tensile testing, that require bulk samples. This thesis examines and compares various methods of testing the mechanical properties of thin films and correlates the molecular structure of organic semiconductors to such properties. Chapter 1 and Appendix A use mechanical buckling and crack-onset strain techniques to measure the elastic modulus and the strain at fracture in fullerene-based semiconductors. These methods were used to examine the effect of incompletely separated grades of electron acceptors on the mechanical deformability of organic solar cells in an effort to simultaneously improve the mechanical robustness of the organic solar cells and reduce the energy of production. Chapter 2 and Appendix B use mechanical buckling, crack-onset strain, and the onset of wrinkles (collectively known as film-on-elastomer techniques) to show a decrease in the stiffness and an increase in the ductility of small-molecule semiconductors that bear side-chains in the backbone structure and compare the results to fullerene-based semiconductors. Chapter 3 and Appendix C compare the results from two different methods of measuring thin-film mechanical properties; film-on-elastomer and film-on-water methods. The film-on-water method uses water to support thin films while conducting a tensile test. These methods were used to measure the mechanical properties of poly(3-hexylthiophene) in a range of molecular weight and the results were directly compared. In Chapter 4 and Appendix D a technique known as scratch testing was used, for the first time, to measure the cohesion and adhesion of semiconducting polymers. The cohesive and adhesive strength were measured as a function of the length of the side chain in poly(3-alkylthiophenes) and molecular weight in poly(3-hexylthiophene).

MECHANICAL AND ELECTRO-MECHANICAL PROPERTIES OF CRYSTALLINE ORGANIC SEMICONDUCTORS.
MECHANICAL AND ELECTRO-MECHANICAL PROPERTIES OF CRYSTALLINE ORGANIC SEMICONDUCTORS.

Author: Marcos A. Reyes-Martinez

Publisher:

Published: 2015

Total Pages:

ISBN-13:

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The study of the physical properties of organic crystalline semiconductors has allowed the advent of a new generation of high-performance organic electronic devices. Exceptional charge-transport properties and recent developments in large-area patterning techniques make organic single crystals (OSCs) excellent candidates for their utilization in the next-generation of electronic technologies, including flexible and conformable organic thin-film devices. In spite of the profound knowledge of the structural and electrical properties of OSCs, knowledge of the mechanical properties and the effects of mechanical strain is almost non-existent. This dissertation aims to bring new understanding of the intrinsic mechanical properties and the effect of mechanical strains in charge transport phenomena in organic semiconductors. The wrinkling instability is chosen as the metrology tool for the effective in-plane elastic constants of OSCs. We demonstrate that the wrinkling instability can be used to obtain the elastic constants of single crystals of rubrene, tetracene, PDIF-CN$_2$ (N,N'-1H,1H-perfluorobutyldicyanoperylene-carboxydi-imide) and perylene. We demonstrate that wrinkling is a practical method to map the in-plane mechanical anisotropy in OSCs. In addition, we utilize wrinkling to characterize how the elastic modulus of pBTTT (poly(2,5-bis(3-alkylthiophen- 2-yl)thieno[3,2-b]thiophene)) changes with increasing molecular weight, from the monomer to the pentamer and the high molecular weight polymer. To elucidate the effects of mechanical strain on charge transport, we first demonstrate and quantify the existence of a piezoresistive effect in rubrene crystals by the application of bending strains along its b [010] axis. A piezoresistive coefficient of approximately 11.26 is determined and confirmed through density functional theory (DFT) calculations. Second, we take advantage of wrinkling as a unique way to strain the conducting channel of field-effect transistors in a non-destructive, reversible, and predictable manner. We observe field-effect mobility modulation upon wrinkling and establish that it is controlled by the strain experienced by the insulator-semiconductor interface upon deformation. Finally, we propose a model based on plate bending to quantify the net strain at the insulator-semiconductor interface and predict the change in mobility. These contributions are the first to quantitatively correlate the crystal structure and the mechanical properties of OSCs, as well as the first to study electro-mechanical behavior in OSCs.

Organic Semiconductors for Optoelectronics
Organic Semiconductors for Optoelectronics

Author: Hiroyoshi Naito

Publisher: John Wiley & Sons

Published: 2021-07-30

Total Pages: 388

ISBN-13: 1119146127

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Comprehensive coverage of organic electronics, including fundamental theory, basic properties, characterization methods, device physics, and future trends Organic semiconductor materials have vast commercial potential for a wide range of applications, from self-emitting OLED displays and solid-state lighting to plastic electronics and organic solar cells. As research in organic optoelectronic devices continues to expand at an unprecedented rate, organic semiconductors are being applied to flexible displays, biosensors, and other cost-effective green devices in ways not possible with conventional inorganic semiconductors. Organic Semiconductors for Optoelectronics is an up-to-date review of the both the fundamental theory and latest research and development advances in organic semiconductors. Featuring contributions from an international team of experts, this comprehensive volume covers basic properties of organic semiconductors, characterization techniques, device physics, and future trends in organic device development. Detailed chapters provide key information on the device physics of organic field-effect transistors, organic light-emitting diodes, organic solar cells, organic photosensors, and more. This authoritative resource: Provides a clear understanding of the optoelectronic properties of organic semiconductors and their influence to overall device performance Explains the theories behind relevant mechanisms in organic semiconducting materials and in organic devices Discusses current and future trends and challenges in the development of organic optoelectronic devices Reviews electronic properties, device mechanisms, and characterization techniques of organic semiconducting materials Covers theoretical concepts of optical properties of organic semiconductors including fluorescent, phosphorescent, and thermally-assisted delayed fluorescent emitters An important new addition to the Wiley Series in Materials for Electronic & Optoelectronic Applications, Organic Semiconductors for Optoelectronics bridges the gap between advanced books and undergraduate textbooks on semiconductor physics and solid-state physics. It is essential reading for academic researchers, graduate students, and industry professionals involved in organic electronics, materials science, thin film devices, and optoelectronics research and development.

Physics of Organic Semiconductors
Physics of Organic Semiconductors

Author: Wolfgang Brütting

Publisher: John Wiley & Sons

Published: 2012-10-02

Total Pages: 660

ISBN-13: 3527654968

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The field of organic electronics has seen a steady growth over the last 15 years. At the same time, our scientific understanding of how to achieve optimum device performance has grown, and this book gives an overview of our present-day knowledge of the physics behind organic semiconductor devices. Based on the very successful first edition, the editors have invited top scientists from the US, Japan, and Europe to include the developments from recent years, covering such fundamental issues as: - growth and characterization of thin films of organic semiconductors, - charge transport and photophysical properties of the materials as well as their electronic structure at interfaces, and - analysis and modeling of devices like organic light-emitting diodes or organic lasers. The result is an overview of the field for both readers with basic knowledge and for an application-oriented audience. It thus bridges the gap between textbook knowledge largely based on crystalline molecular solids and those books focusing more on device applications.

Survey of Organic Semiconductors Included Electrical and Mechanical Properties of Plastics
Survey of Organic Semiconductors Included Electrical and Mechanical Properties of Plastics

Author: John H. Meiser

Publisher:

Published: 1968

Total Pages: 161

ISBN-13:

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A comprehensive list of organic semiconductors has been prepared to include compounds having low resistivities. Where electrical and mechanical properties were found, they were included. Five classes of compounds were reviewed and ten compounds were suggested as displaying electrical hysteresis effects due to mechanical loading. Included in the tables is a listing of physical properties of commercially available plastics. (Author).

Electronic Processes in Organic Semiconductors
Electronic Processes in Organic Semiconductors

Author: Anna Köhler

Publisher: John Wiley & Sons

Published: 2015-06-08

Total Pages: 436

ISBN-13: 3527332928

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The first advanced textbook to provide a useful introduction in a brief, coherent and comprehensive way, with a focus on the fundamentals. After having read this book, students will be prepared to understand any of the many multi-authored books available in this field that discuss a particular aspect in more detail, and should also benefit from any of the textbooks in photochemistry or spectroscopy that concentrate on a particular mechanism. Based on a successful and well-proven lecture course given by one of the authors for many years, the book is clearly structured into four sections: electronic structure of organic semiconductors, charged and excited states in organic semiconductors, electronic and optical properties of organic semiconductors, and fundamentals of organic semiconductor devices.

Mechanical Properties and Crystal Growth Studies of Semiconductor Alloys
Mechanical Properties and Crystal Growth Studies of Semiconductor Alloys

Author:

Publisher:

Published: 1993

Total Pages: 48

ISBN-13:

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Compound semiconductors are attractive materials for optoelectronic devices since they present a broad selection of band gaps. The mechanical properties of these materials is of interest for both practical and theoretical reasons, however, there is a paucity of experimental information on this topic . The objective of this research program was to develop methods for providing reliable experimental information on the mechanical properties of compound semiconductors and their alloys. The main activity has been the measurement of the hardness of these materials. We have used two basic hardness measurements: conventional microhardness measurements, such as the Vickers hardness test; and the Nanoindentor hardness. For the former measurements, bulk crystals or thick films Were needed. A significant part of the program was devoted to preparing relevant samples for these measurements. We used conventional methods of crystal growth for producing bulk crystals and we developed novel methods of vapor phase epitaxial growth to prepare thick films of variable composition. The Nanoindentor was used for measuring the hardness and the modulus of thin films and bulk samples were measured by Vickers or with the Nanoindentor. We investigated a wide variety of semiconductor systems for measurement, but we selected a few systems that had well established device applications for particular emphasis in our studies.

Organic Flexible Electronics
Organic Flexible Electronics

Author: Piero Cosseddu

Publisher: Woodhead Publishing

Published: 2020-09-29

Total Pages: 666

ISBN-13: 012818891X

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Organic Electronics is a novel field of electronics that has gained an incredible attention over the past few decades. New materials, device architectures and applications have been continuously introduced by the academic and also industrial communities, and novel topics have raised strong interest in such communities, as molecular doping, thermoelectrics, bioelectronics and many others.Organic Flexible Electronics is mainly divided into three sections. The first part is focused on the fundamentals of organic electronics, such as charge transport models in these systems and new approaches for the design and synthesis of novel molecules. The first section addresses the main challenges that are still open in this field, including the important role of interfaces for achieving high-performing devices or the novel approaches employed for improving reliability issues.The second part discusses the most innovative devices which have been developed in recent years, such as devices for energy harvesting, flexible batteries, high frequency circuits, and flexible devices for tattoo electronics and bioelectronics.Finally the book reviews the most important applications moving from more standard flexible back panels to wearable and textile electronics and more futuristic applications like ingestible systems. Reviews the fundamental properties and methods for optimizing organic electronic materials including chemical doping and techniques to address stability issues Discusses the most promising organic electronic devices for energy, electronics, and biomedical applications Addresses key applications of organic electronic devices in imagers, wearable electronics, bioelectronics