Materialelære

Understanding Geologic Carbon Sequestration and Gas Hydrate from Molecular Simulation systematically introduces CO2 geological sequestration and gas hydrate at the molecular-scale, with research including interfacial properties of multiphase, multicomponent systems, hydrogen bonding properties, adsorption characteristics of CO2CH4 in the pore, kinetic properties of decomposition/nucleation/growth of gas hydrate, the influence of additives on gas hydrate growth dynamics, and hydrate prevention and control technology. This book focuses on research-based achievements and provides a comprehensive look at global progress in the field. Because there are limited resources available on carbon geologic sequestration technology and gas hydrate technology at the molecular level, this book fills a gap in scientific literature and elucidates on further research.

Bio-Based and Bio-Inspired Pavement Construction Materials explores the role of materials in carbon management, performance enhancement, and supply chain management in pavement construction. It presents various production techniques, experimental characterization methods, applications, numerical modeling, and simulation approaches for bio-based and bio-inspired pavement construction materials. The book demonstrates how bio-based and bio-inspired materials can be used in pavements to solve problems related to sustainability while simultaneously enhancing the mechanical properties of materials. Supply chain management, life-cycle analysis, and environmental assessment of using these materials are all covered in this volume as well.

Biofuels Production from Lignocellulosic Materials presents the latest scientific and technical advances in the bioprocessing of lignocellulosic materials for disposal, resource recovery, and biofuel and bioenergy production. The book emphasizes the main chemical and biological properties of lignocellulosic materials, its pre-treatment, emerging nutrient recovery technologies, the role of microbial biotechnology in lignocellulosic materials management, and the sustainable use of biofuel for anthropogenic activities to fulfil energy demand. Lignocellulose biorefinery outcomes are examined from multiple perspectives, including applied chemical, mechanical, and enzymatic pre-treatments technologies, and cost-effective and energy-efficient options for developing high value-added products. This is a valuable reference for scientists, researchers, engineers, and industrial practitioners, as well as graduate and postgraduate students working on the utilization of lignocellulosic materials.

Nanomaterials in Biomass Conversion: Advances and Applications for Bioenergy, Biofuels and Biobased Products critically reviews basic principles and advances in nanotechnology for the production of biofuels and bioenergy. Sections explain the fundamentals of nanomaterials, their properties, characterization, and basic processes for synthesis while also reviewing various methods and technologies for the conversion of biomass to bioenergy, biofuels, and value-added products using nanomaterials. This includes homogeneous and heterogeneous nano-catalytic systems, nano-photocatalytic conversion, nanomaterial-assisted anaerobic digestion, nanoparticles-immobilized enzymes conversion, the production of biogas, volatile fatty acids, value-added products, and in carbon capture and conversion to sustainable energy products, and much more. Final sections address technoeconomics and financial viability in the context of the circular economy, risk related to toxicology, stability, and environmental impacts, and consider the various challenges and future opportunities of biomass conversion through nanomaterials.

High-Volume Mineral Admixtures in Cementitious Binders: Towards Carbon-Neutral Construction delivers an overview of the broad applications of high-volume supplementary cementitious materials (SCMs) in cementitious binders, addressing the most promising ways to use them to reduce carbon emissions in the construction and building industry. This book focuses on the applications and scientific challenges of high-volume SCMs blends, elaborating on the possibilities as well as offering original perspectives on using different kinds of blended cements in the manufacturing process. Emphasis is placed on activity estimation and quality assessment, the properties of high-volume SCM-blends at both the fresh and hardened stages, self-hydraulic properties, and potential use as the sole binder, as well as associated environmental impacts and carbon footprint reduction.

This book reports on cutting-edge research and technical achievements in the field of hydraulic drives. The chapters, selected from contributions presented at the International Scientific-Technical Conference on Hydraulic and Pneumatic Drives and Controls, NSHP 2023, held on October 11-13, 2023, in Piechowice, Poland, cover a wide range of topics such as theoretical advances in fluid technology, work machines in mining, construction, marine and manufacturing industry, and practical issues relating to the application and operation of hydraulic drives. Further topics include: safety and environmental issues associated with the use of machines with hydraulic drive, designing test stands with hydraulic and pneumatic components, advancing control of hydraulic systems, analyzing vibration issues, application of renewable energy sources, and new materials in the design of hydraulic components. Special emphasis is given to new solutions for hydraulic components and systems as well as to theidentification of phenomena and processes occurring during the operation of hydraulic and pneumatic systems.

Do you know why honey drips whereas ketchup refuses to budge in the bottle? Or what kettles have in common with power stations, or how to cook with radar?This delightful and accessible book provides a smorgasbord and a whirlwind tour of the multitude of physical phenomena that occur in a kitchen: from the diffusion of nutrients during cooking to how an extractor fan works, how smells disperse, and where quantum effects are hidden. These and numerous other fascinating phenomena are served up in an engaging manner that will fascinate and tantalise the taste buds of anyone who enjoys eating, cooking or simply spending time in the kitchen. No specialist technical or mathematical knowledge is required to enjoy this book. Tuck right in and discover the universe of physical laws in your very own kitchen...

This book provides an overview of the initiation of combustion processes of polymeric materials. It presents physicochemical processes associated with heating as well as numerical methods for initiation parameter calculation. In addition, the book describes thermal degradation of polymers and the effect of an incident heat flux on initiation time. It then highlights the most commonly used devices for measuring the time to ignition using external heat sources. The target group of this book are scientists and researchers dealing with materials combustion and also graduates and practitioners focused on fire protection.

This handy volume illustrates the basics of clinical three-dimensional (3D) printing, addressing the practical aspects of establishing a simple and effective 3D printing service in a medical facility. No longer confined to makers and workshops, this very recent technology has been fast developing and rapid prototyping has proven its potential in the clinical field as well, leading to new approaches. The declared aim of this work is enabling medical professionals to create bespoke anatomical models from a series of CT or MRI images, and assisting them in choosing the best suited 3D printers and materials for each specific clinical need. The text includes original, full-color step-by-step photos for better guidance, and a complete review of related publications in literature. Single chapters devoted to specific areas of 3D printing application, such as rhinoplasty, ear reconstruction, oculoplasty, maxillofacial surgery, as well as for surgical simulations.Contents are completed by a review of the legal aspects and the safety and quality considerations, as well as a thorough examination of the variety of 3D printers, compatible materials as filaments and resins, and including the available online resources. Plastic, Ophthalmologic and Maxillofacial surgeons, and professionals dealing with surgical reconstruction, will find this guide to be a valuable companion for the understanding of 3D printing in clinical practice.

This monograph examines the stability of various coupled systems with local Kelvin-Voigt damping. The development of this area is thoroughly reviewed along with the authors' contributions. New results are featured on the fundamental properties of solutions of linear transmission evolution PDEs involving Kelvin-Voigt damping, with special emphasis on the asymptotic behavior of these solutions. The vibrations of transmission problems are highlighted as well, making this a valuable resource for those studying this active area of research. The book begins with a brief description of the abstract theory of linear evolution equations with a particular focus on semigroup theory. Different types of stability are also introduced along with their connection to resolvent estimates. After this foundation is established, different models are presented for uni-dimensional and multi-dimensional linear transmission evolution partial differential equations with Kelvin-Voigt damping. Stabilization of Kelvin-Voigt Damped Systems will be a useful reference for researchers in mechanics, particularly those interested in the study of control theory of PDEs.

This book presents a collection of chapters on modern bioelectrochemistry, showing different aspects of emerging techniques and materials, biodevice design and reactions. The chapters provide relevant bibliographic information for researchers and students interested in electrochemical impedance spectroscopy applied in biodevices, trends, and validation on impedimetric immunosensors in the application of routine analysis, electrochemical-surface plasmon bioanalytics and carbon nanomaterials in electrochemical biodevices, insights on inorganic complexes and metal based for biomarkers sensors, bioelectrodes and cascade reactions and field effect-based reactions.

This book offers a multidisciplinary perspective on research and developments at the interface between industrial design, textile engineering and fashion. It covers advances in fashion and product design, and in textile production alike, reporting on sustainable industrial procedures, ergonomics research and practices, new materials and circular design, as well as issues in marketing, communication, and education. A special emphasis is given to universal and inclusive strategies in design. Gathering the proceedings of the 6th International Fashion and Design Congress, CIMODE 2023, held on October 4¿6, 2023, in Mexico City, Mexico, this book offers extensive information and a source of inspiration to both researchers and professionals in the field of fashion, design, engineering, communication as well as education.Chapter 26 is available open access under a Creative Commons Attribution 4.0 International License via link.springer.com.

This book covers recent developments in the understanding, quantification, and exploitation of entanglement in spin chain models from both condensed matter and quantum information perspectives. Spin chain models are at the foundation of condensed matter physics and quantum information technologies and elucidate many fundamental phenomena such as information scrambling, quantum phase transitions, and many-body localization. Moreover, many quantum materials and emerging quantum devices are well described by spin chains. Comprising accessible, self-contained chapters written by leading researchers, this book is essential reading for graduate students and researchers in quantum materials and quantum information.  The coverage is comprehensive, from the fundamental entanglement aspects of quantum criticality, non-equilibrium dynamics, classical and quantum simulation of spin chains through to their experimental realizations, and beyond into machine learning applications.

This book explores cutting-edge topics on hydrogen and fuel cell technologies in aviation. Coverage includes comparisons with conventional technologies, hydrogen storage options, energy management strategies, life cycle assessment, and application of fuel cells in different aerial vehicle classes. It also offers insights into recent progress and new technological developments in the field, along with case studies and practical applications. Fuel Cell and Hydrogen Technologies in Aviation is an invaluable guide for students, researchers, and engineers working on sustainable air transportation and the performance and environmental analysis of fuel cell-powered aerial vehicles.

This book compares premetered methods to self-metered processes and addresses general properties of premetered methods. It presents specific properties of slot, slide, and curtain coating. The book is divided in three parts:Part I compares premetered methods to self-metered processes. It explains the term "e;premetered,"e; which is an expression of the law of mass conservation, and discusses the physical fluid properties that are relevant for premetered processes. Furthermore, it presents in detail the various basic flow fields that make up premetered coating methods. Lastly, it introduces the concepts of wall shear stress, residence time, and hydrodynamic assist to dynamic wetting. Part II addresses general properties of premetered methods, such as the fluid conditioning and delivery systems, the nominal film thickness, and the film thickness uniformity, both in machine and cross-web directions (die design). It lists the attractive features of simultaneous multilayer applications, including an explanation of how mixing of adjacent layers can be prevented. This section concludes by revisiting examples of economic considerations.Part III presents specific properties of slot, slide, and curtain coating. It examines various topics, such as coating equipment and coating configurations, coating modes, details of the various flow fields, operating window and process limitations, and process optimization.

This work systematically investigates the use of high-quality (high-Q) resonators as coding particles of chipless cooperative radar targets to overcome clutter. Due to their high-Q, the backscattered signature can outlast clutter and permit reliable readouts in dynamic environments as well as its integration in other types of cooperative radar targets for joint identification, sensing, and ranging capabilities.This is first demonstrated with temperature and pressure sensors in the microwave frequency range, which include the characterization of a novel temperature sensor for machine tool monitoring up to 400 (deg)C, as well as inside the machine. Afterwards, the thesis proposes and demonstrates the use of metallic as well as dielectric Electromagnetic BandGap (EBG) structures to enable the realization and to enhance the capabilities at mm-Wave and THz frequencies compared to microwave frequencies with compact monolithic multi-resonator cooperative radar targets. Furthermore, this work studies the integration of resonators as coding particles inside larger retroreflective configurations such as Luneburg lenses to achieve long-range and high accuracy for localization and, at the same time, frequency coding robust against clutter for identification. Finally, the successful readout of these cooperative radar targets is demonstrated in cluttered dynamic environments, as well as with readers based on Frequency-Modulated Continuous-Wave (FMCW) radars.

This interdisciplinary book covers the fundamentals of optical whispering gallery mode (WGM) microcavities, light¿matter interaction, and biomolecular structure with a focus on applications in biosensing. Novel biosensors based on the hybridization of WGM microcavities and localized surface plasmon resonances (LSPRs) in metal nanoparticles have emerged as the most sensitive microsystem biodetection technology that boasts single molecule detection capability without the need for amplification and labeling of the analyte. The book provides an ample survey of the physical mechanisms of WGMs and LSPRs for detecting affinity, concentration, size, shape and orientation of biomarkers, while informing the reader about different classes of biomolecules, their optical properties and their importance in label-free clinical diagnostics.This expanded and updated second edition features a new chapter that introduces the reader to advanced in vivo biosensing techniques using WGM microcavities, looking at photothermal sensing, methods for trapping neutral atoms around WGM microcavities, and practical aspects of optoplasmonic sensing. The second Edition now provides a comprehensive introduction to the use of WGM microcavities in physical sensing which includes measurements with frequency combs, macro and micro (one atom) lasers, gyroscopes, optomechanical and parity-time-symmetric sensor devices.Chapter-end problems round out this comprehensive and fundamental textbook, inspiring a host of up-and-coming physicists, bioengineers, and medical professionals to make their own breakthroughs in this blossoming new field. This textbook can be used for both introductory and advanced courses about the modern optics of optical microcavities.

The novel finite element formulations fall into the category of geometrically exact Kirchhoff-Love beams. A prominent characteristic of this category is that the absence of shear deformation is strongly enforced by removing two degrees of freedom. Further, the corresponding beam theories exhibit not only translational but also rotational degrees of freedom and their configurations thus form a non-additive and non-commutative space. Sophisticated interpolation schemes are required that need to be tested not only for locking, spatial convergence behavior, and energy conservation, but also for observer invariance and path-independence. For the three novel beam element formulations all these properties are analytically and numerically studied and confirmed, if applicable. Two different rotation parameterization strategies are employed based on the well-known geodesic interpolation used in many Simo-Reissner beams and the lesser known split into the so-called \textit{smallest rotation} and a torsional part. Application of the former parameterization results in a mixed finite element formulation intrinsically free of locking phenomena. Additionally, the first geometrically exact Kirchhoff-Love beam element is presented, which strongly enforces inextensibility by removing another degree of freedom. Furthermore, the numerical efficiency of the new beam formulations is compared to other beam elements that allow for or suppress shear deformation. When modeling very slender beams, the new elements offer distinct numerical advantages.Standard molecular dynamics simulations, which are commonly used to study polymers, suffer from a lack of a careful mathematical basis and the use of an expensive explicit time integration scheme. To circumvent these shortcomings and to be able to simulate stretching experiments on relevant time scales, the problem is described by a stochastic partial differential equation, which can be solved using the finite element method with a backward Euler temporal discretization. In detail, the polymer is represented by a Kirchhoff-Love beam with a linear elastic constitutive model. Inertial and electrostatic forces are neglected. It is deformed by a distributed load mimicking collisions with molecules of the surrounding fluid. Naturally, this load heavily fluctuates over time and space and mean values need to be computed in a Monte Carlo manner. To vastly speed up the fitting process to experimental data in a Bayesian framework, a surrogate model based on a Gaussian process is set up, which directly computes the mean values for given material parameters. The uncertainties and correlations of the material parameters are studied and compared to the literature.

Systematically introduces and summarizes the fundamental and experimental research results of recent progress on flexible electronic packaging and encapsulation technology.

This book provides cutting-edge, up-to-date research findings on the use of bionanocomposites in biodegradable and environmental applications, while also detailing how to achieve bionanocomposites preparation, characteristics, and significant enhancements in physical, chemical, mechanical, thermal properties and applications. This book on biodegradable and environmental properties of bionanocomposites provides a comprehensive and updated review of major innovations in the field of polymer-based bionanocomposites for biodegradable and environmental applications. It covers properties and applications, including the synthesis of polymer-based bionanocomposites from different sources biomaterials-based composites and tactics on the efficacy and major challenges associated with successful scale-up fabrication on bionanocomposites.It is an essential reference for future research in bionanocomposites as topics such as sustainable, biodegradable, and environmental methods for highly innovative and applied materials are current topics of importance. The book covers a wide range of research on bionanocomposite and their biodegradable and environmental applications. Updates on the most relevant polymer-based bionanocomposite and their prodigious potential in the fields of biodegradable and the environment are presented. Leading researchers from industry, academy, government, and private research institutions across the globe contribute to this book. Scientists, engineers, and students with interest in the most important advancements in the field of bionanocomposites involving high-performance bionanocomposites will benefit from this book which is highly application-oriented.   

This textbook presents the fundamental concepts and theories in solid-state engineering physics in a very simple, systematic, and comprehensive way. The book is written in a lucid manner so that students are able to understand the realization behind the mathematical concepts which are the backbone of this subject. All the subject fundamentals and related derivations are discussed in an easy and comprehensive way to make the students strong about the basics of the solid-state engineering physics. The philosophy of presentation and material content in the book are based on concept-based approach toward the subject. The key features also lie in the solutions of several interesting numerical problems so that the students should have the idea of the practical usages of the subject. The book will benefit students who are taking introductory courses in solid-state physics for engineering.

Um bei der Fertigung von Faserverbundkunststoffen Zeit, Energie und Kosten sparen zu können, werden möglichst viele Informationen über die Vorgänge während des Fertigungsprozesses benötigt. Die Integration von Foliensensoren in die hergestellten Bauteile ist eine von mehreren Möglichkeiten, diese Informationen zu erhalten. Foliensensoren bestehen aus einer thermoplastischen Folie, auf der metallische Elektroden strukturiert sind. Ihre Integration in das Bauteil bringt unterschiedliche Vor- und Nachteile mit sich. Einerseits sind bauteilintegrierte Sensoren flexibler einsetzbar als werkzeugintegrierte Sensoren und ermöglichen eine feinere räumliche Auflösung der Aushärtevorgänge. Andererseits werden sie bei der Fertigung zum Produktbestandteil. Sie sollten deswegen einfach und kostengünstig sein, sowie die Lasttragfähigkeit nicht beeinträchtigen. Aus mechanischer Sicht bringen Foliensensoren vor allem ein Delaminationsrisiko mit sich. Die Wahl des thermoplastischen Substratmaterials macht dabei den entscheidenden Einflussfaktor aus. Während Sensoren auf Basis des häufig verwendeten Materials Polyimid ein erhebliches Delaminationsrisiko mit sich bringen, ist der Einfluss von Polyetherimid weit weniger schädlich oder verbessert sogar einzelne Festigkeitskennwerte. Neben dem Substratmaterial wirken sich auch die metallischen Sensorstrukturen auf die Belastbarkeit aus. Zur Gestaltung minimalinvasiver Sensoren sollte ein möglichst geringer Metallisierungsgrad angestrebt werden. Das verbreitetste Design für Foliensensoren zur Aushärteüberwachung sind sogenannte Interdigitalelektroden, die eine elektrische Kapazität bilden, deren Impedanz von der direkten Umgebung beeinflusst wird. In variothermen Fertigungsprozessen besteht eine Herausforderung darin, den Einfluss der Temperatur von dem des Aushärtegrades zu trennen. Die an integrierten Sensoren gemessenen Impedanzinformationen müssen dazu eine Verarbeitung durchlaufen, in deren Verlauf die Frequenzabhängigkeit und die Einflüsse von Temperatur und Sensorgeometrie aus den Daten entfernt werden. Für eine variotherme Aushärteüberwachung ist daher die Verwendung eines zusätzlichen Temperatursensors unverzichtbar. Die Sensordaten bieten darüber hinaus Potential für die Ermittlung des Faservolumengehalts oder zur Detektion von Harzfehlanmischungen.

This book discusses generalized applications of energy storage systems using experimental, numerical, analytical, and optimization approaches. The book includes novel and hybrid optimization techniques developed for energy storage systems. It provides a range of applications of energy storage systems on a single platform. The book broadly covers-thermal management of electronic components in portable electronic devices; modeling and optimization aspects of energy storage systems; management of power generation systems involving renewable energy; testing, evaluation, and life cycle assessment of energy storage systems, etc. This book will serve as a reference resource for researchers and practitioners in academia and industry.

This book gathers the best peer-reviewed papers presented at the Italian Concrete Conference, held in Naples, Italy, on October 12-15, 2022. The conference topics encompass the aspects of design, execution, rehabilitation, and control of concrete structures, with particular reference to theory and modeling, applications and realizations, materials and investigations, technology, and construction techniques. The contributions amply demonstrate that today¿s structural concrete applications concern not only new constructions, but more and more rehabilitation, conservation, strengthening, and seismic upgrading of existing premises, and that requirements cover new aspects within the frame of sustainability, including environmental friendliness, durability, adaptability, and reuse of works and/or materials. As such, the book represents an invaluable, up-to-the-minute tool, providing an essential overview of structural concrete, as well as all new materials with cementitious matrices.

This book discusses the behaviour of isolated concrete bottle-shaped struts affected by internal expansion reactions (ISR). For that purpose, the numerical modelling of damaged concrete was performed using the Concrete Damaged Plasticity Model (CDPM) implemented in ABAQUS and validated the model through Sankovich's tests. A procedure to automatically obtain the concrete plasticity and damage parameters, essential for CDPM, was developed in Matlab. The inputs were the characteristic compressive strength of the concrete, the equivalent length of the finite element mesh and the ratio between the plastic and inelastic compressive strains. The results showed that the CDPM could represent the load-bearing mechanisms of isolated concrete bottle-shaped struts for a range of several stress levels to which these elements may be subjected in the panels investigated. The numerical simulations for different expansion levels consistently captured the expected damage profile of the panels and the load corresponding to the formation of the first crack, the estimated crack opening, and the ultimate load. For the panels investigated, the reduction observed in the failure load reached values close to 70%, the increase of the tensile plastic deformation was more than 60%, and the maximum crack opening can reach an increase of 113% when compared with those observed experimentally in panels without internal swelling reactions The book also offers a systematic review of the current state of knowledge and it is a valuable resource for scientists, students, practitioners, and lecturers in various scientific and engineering disciplines, namely, civil and materials engineering, as well as and other interested parties.

This book presents innovative laser desorption ionization (LDI)-active nanophotonic structures for addressing the challenges that matrix-assisted laser desorption ionization mass spectrometry (MALDI-MS) is currently facing and for enhancing LDI efficiency. It presents a variety of cutting-edge nanophotonic structures to satisfy the mass-analytical needs of sensitivity, reproducibility, and quantification. As opposed to the commercialized, conventional organic matrix used in MALDI-MS, these nanostructures are validated to be highly effective in detecting small metabolites and drugs, highlighting their considerable potential in the mass spectrometry field. It also systematically elucidates fundamental LDI processes in terms of the photo-thermal, electronic, and structural characteristics of nanophotonic structures, offering mechanistic knowledge of LDI-MS. Even though LDI-MS performance is heavily influenced by a number of nanostructure parameters, relatively little is known about the LDI processes associated with those characteristics. An in-depth understanding of nanostructure characteristics and LDI mechanisms thus paves the way for more effective, rational design and development of nanostructures with improved LDI capabilities. Further, with a focus on multiple cascades in nanostructure functions in response to laser pulse stimuli, this book provides detailed, step-by-step procedures to design and construct a nanophotonic, LDI-active platform, which may serve as a roadmap for graduate students in the field of mass spectrometry. Readers, including graduate students, researchers, and experts working in the related areas of mass spectrometry, nanophotonics, and material science and material engineering, will find a wealth of useful information in this book.

Key topics include optimizing production processes, implementing visual control and management systems. Emphasis is placed on the sustainable development of production systems, the application of additive manufacturing, the implementation of cleaner production methods, and the utilization of waste materials for sustainable production practices.

The book presents new advances in the field of manufacturing technologies. It focuses on the design and engineering of manufacturing processes; additive manufacturing and reverse engineering; assembly, disassembly and circular processes; system simulation, optimization and digital manufacturing; and materials processing technology.