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Загальна кiлькiсть документiв : 17
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1.


    Tedenac, Jean-Claude.
    Multicomponent Silicides for Thermoelectric Materials [[electronic resource] :] : phase Stabilities, Synthesis, and Device Tailoring / / Jean-Claude. Tedenac ; . - 1st ed. 2017. - [S. l. : s. n.]. - IX, 46 p. 26 illus., 18 illus. in color. - Б. ц.
    Зміст:
Chapter 1. Abstract --
Chapter 2. Introduction --
Chapter 3. Review of materials --
Chapter 4. Properties of compounds --
Chapter 5. The thermodynamic approach in thermoelectric materials --
Chapter 6. Silicides and other thermoelectric materials --
Chapter 7. Conclusion --
Chapter 8. Databases.
Рубрики: Ceramics.
   Glass.
   Composites (Materials).
   Composite materials.
   Energy harvesting.
   Thermodynamics.
   Heat engineering.
   Heat transfer.
   Mass transfer.
   Inorganic chemistry.
   Optical materials.
   Electronic materials.
   Sustainable development.
   Ceramics, Glass, Composites, Natural Materials.
   Energy Harvesting.
   Engineering Thermodynamics, Heat and Mass Transfer.
   Inorganic Chemistry.
   Optical and Electronic Materials.
   Sustainable Development.
Анотація: This book provides a comprehensive review of the current state of the art in silicon compounds for thermoelectric applications. Silicides are materials with good initial thermoelectric properties, which can be enhanced through tuning of their micro- and macrostructure. These compounds present various conduction mechanisms and complex band structures. Moreover, some are isotropic, and others anisotropic, which is highly beneficial for device tailoring. Silicides are a particularly attractive material for sensors, thermoelectric generators, and other applications because they are environmentally friendly, abundant, and low cost. This concise volume covers fundamentals and applications for an audience of materials scientists, chemists, solid-state physicists, and engineers.

Перейти: https://doi.org/10.1007/978-3-319-58268-9

Дод.точки доступу:
Tedenac, Jean-Claude. \.\; SpringerLink (Online service)
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2.


    Visy, Csaba.
    In situ Combined Electrochemical Techniques for Conducting Polymers [[electronic resource] /] : монография / Csaba. Visy ; . - 1st ed. 2017. - [S. l. : s. n.]. - XI, 68 p. - Б. ц.
    Зміст:
Brief introduction to the field of conducting polymers and allied areas --
Redox transformation of CPs, and the coupled phenomena (changes in: mass, volume, conductance, color, morphology etc.) --
Overview of in situ electrochemical methods to follow the redox transformations --
Combined in situ methods.
Рубрики: Electrochemistry.
   Polymers  .
   Analytical chemistry.
   Energy harvesting.
   Electrochemistry.
   Polymer Sciences.
   Analytical Chemistry.
   Energy Harvesting.
Анотація: This book outlines methods to improve functioning of these polymer based devices – in particular, the multi-faceted cognition of these materials. In situ electrochemical techniques are studied to elucidate redox switching between non-conducting and conducting states. The book examines the advantages of combinations of in situ electrochemical techniques in a hyphenated mode for analyzing conducting polymers.

Перейти: https://doi.org/10.1007/978-3-319-53515-9

Дод.точки доступу:
Visy, Csaba. \.\; SpringerLink (Online service)
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3.


   
    Advanced Nanomaterials in Biomedical, Sensor and Energy Applications [[electronic resource] /] : монография / ed.: Chattopadhyay, Jayeeta., Srivastava, Rohit. - 1st ed. 2017. - [S. l. : s. n.]. - X, 96 p. 64 illus. - Б. ц.
    Зміст:
Chapter 1. Design and Fabrication of Nanomaterials Based Device for Pressure Sensor Applications --
Chapter 2. Graphene Oxide: Structural Updates and Enzyme Mimetic Properties for Biomedical Applications --
Chapter 3. Harvesting clean energy through H2 Production using Cobalt-Boride based nano-catalyst --
Chapter 4. Plasmonic effect of Au nanoparticles deposited using spray technique on the performance of solar cell --
Chapter 5. Hollow Carbon Nano-Spheres: A Step towards Energy Applications.
Рубрики: Nanochemistry.
   Biomedical engineering.
   Energy harvesting.
   Nanotechnology.
   Nanochemistry.
   Biomedical Engineering and Bioengineering.
   Energy Harvesting.
   Nanotechnology.
Анотація: This book is aimed at all those who are interested to understand the current research going on in nanomaterial science from the perspectives of biomedical, sensorial and energy applications including all aspects of physical chemist, chemical engineers and material scientist. Nanoscience and nanotechnology are at the forefront of modern research. The fast growing economy in this area requires experts with outstanding knowledge of nanoscience in combination with the skills to apply this knowledge in new products. A multidisciplinary scientific education is crucial to provide industry and research institutes with top quality experts who have a generic background in the different sub disciplines such as electronics, physics, chemistry, material science, biotechnology. The book covers recent advancement in nanoscience and nanotechnology particularly highlights the utilization of different types of nanomaterials in biomedical field, sensor and in the energy application. On the other hand, it leads the reader to the most significant recent developments in research. It provides a broad and in-depth coverage of the nanoscale materials and its depth significant applications. .

Перейти: https://doi.org/10.1007/978-981-10-5346-7

Дод.точки доступу:
Chattopadhyay, Jayeeta. \ed.\; Srivastava, Rohit. \ed.\; SpringerLink (Online service)
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4.


   
    Smart Polymer Nanocomposites [[electronic resource] :] : energy Harvesting, Self-Healing and Shape Memory Applications / / ed. Ponnamma, Deepalekshmi. [et al.]. - 1st ed. 2017. - [S. l. : s. n.]. - XI, 397 p. 183 illus., 131 illus. in color. - Б. ц.
    Зміст:
Polymer Composites: Perspectives for Energy Harvesting, Self-healing and Shape Memory --
Energy harvesting with crystalline polymer composites: cellulose, and PVDF composites --
Energy harvesting using conductive polymer composites --
Application of poly (3-hexylthiophene) P3HT composites for energy harvesting --
Energy harvesting with poly(fluorene-co-thiophene) and perflouro polymer composites --
Elastomer composites in energy harvesting: poly (dimethylsiloxane), polyurethane composites --
Poly-?-benzyl-L-glutamate, poly(methyl methacrylate) composites and their application for energy harvesting --
Self-healing materials from elastomeric composites --
Self-healing materials from crystalline polymer composites --
Thermoplastic polymer composites as self-healing materials --
Application of conductive polymer composites as self-healing materials --
Self-healing of biopolymers and their composites --
Shape memory materials from elastomeric composites --
Conductive polymer composites: Perspectives as shape memory materials --
Thermoplastic polymer composites as shape memory materials --
Crystalline polymer composites as shape memory materials.
Рубрики: Polymers  .
   Nanotechnology.
   Energy harvesting.
   Nanochemistry.
   Nanoscale science.
   Nanoscience.
   Nanostructures.
   Polymer Sciences.
   Nanotechnology.
   Energy Harvesting.
   Nanotechnology and Microengineering.
   Nanochemistry.
   Nanoscale Science and Technology.
Анотація: This book covers smart polymer nanocomposites with perspectives for application in energy harvesting, as self-healing materials, or shape memory materials. The book is application-oriented and describes different types of polymer nanocomposites, such as elastomeric composites, thermoplastic composites, or conductive polymer composites. It outlines their potential for applications, which would meet some of the most important challenges nowadays: for harvesting energy, as materials with the capacity to self-heal, or as materials memorizing a given shape. The book brings together these different applications for the first time in one single platform. Chapters are ordered both by the type of composites and by the target applications. Readers will thus find a good overview, facilitating a comparison of the different smart materials and their applications. The book will appeal to scientists in the fields of chemistry, material science and engineering, but also to technologists and physicists, from graduate student level to researcher and professional. .

Перейти: https://doi.org/10.1007/978-3-319-50424-7

Дод.точки доступу:
Ponnamma, Deepalekshmi. \ed.\; Sadasivuni, Kishor Kumar. \ed.\; Cabibihan, John-John. \ed.\; Al-Maadeed, Mariam Al-Ali. \ed.\; SpringerLink (Online service)
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5.


    Pardo Echarte, Echarte, Manuel Enrique.
    Oil and Gas Exploration in Cuba [[electronic resource] :] : geological-Structural Cartography using Potential Fields and Airborne Gamma Spectrometry / / Echarte, Manuel Enrique. Pardo Echarte, Cobiella Reguera, Jorge Luis. ; . - 1st ed. 2017. - [S. l. : s. n.]. - XIV, 76 p. 48 illus., 45 illus. in color. - Б. ц.
    Зміст:
Foreword --
Abstract --
Chapter 1. The State of Art --
Chapter 2. Overview of the Geology of Cuba --
Chapter 3. Tectonic-Structural Regionalization With Purposes of Hydrocarbon Exploration and Mapping of Potential New Oil-gas Goals --
Chapter 4. Geological-structural mapping of weathered igneous and metamorphic rock units.
Рубрики: Structural geology.
   Energy harvesting.
   Remote sensing.
   Spectroscopy.
   Structural Geology.
   Energy Harvesting.
   Remote Sensing/Photogrammetry.
   Spectroscopy/Spectrometry.
Анотація: A summary of the results achieved in the geological-structural mapping, by potential fields and airborne gamma spectrometry data, of the units of igneous and metamorphic rocks in the western regions (Havana-Matanzas), central (Cienfuegos, Villa Clara-Sancti Spiritus) and central-eastern (Camaguey-Las Tunas-Holguin) of Cuba is presented. In addition, the structural- tectonic regionalization with hydrocarbon exploration purposes, focusing mapping of possible new oil-gas targets in the regions of Land Blocks 9, 23 and 17-18 are detailed in this volume. In certain case study locations (Majaguillar, North Motembo, Guamutas and Maniabon) reconnaissance work by a profile of Redox Complex (complex of unconventional geophysical-geochemical exploration techniques) was performed with positive results. In an attempt to contribute to the geological-structural mapping of the metamorphic massif Isla de la Juventud, with emphasis on acid magmatism, the gravi-magnetometric data is used. According to the results, the presumed post metamorphic granitic bodies of low density are located, mainly, in the central and southwestern part of the massif. The granitic bodies apparently were introduced through the system of longitudinal faults (syn metamorphic) and transverse (post metamorphic) at the end of the process multyfolding and metamorphism of the massif sequences, taking a leading role the deep longitudinal fracture zones of sublatitudinal direction in the central and southern part of the massif. On the map of the magnetic field vertical derivative  the anomalies, basically, reflected the direction and limits of the folded tectonic structure, the development area of volcanogenic rocks, the presumed development zones of migmatitic rocks and tectonised rocks in North and center of the massif, respectively, and the prevailing direction of the main tectonic dislocations.

Перейти: https://doi.org/10.1007/978-3-319-56744-0

Дод.точки доступу:
Cobiella Reguera, Jorge Luis.; Pardo Echarte, Manuel Enrique. \.\; SpringerLink (Online service)
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6.


    Hou, Shaocong.
    Fiber Solar Cells [[electronic resource] :] : materials, Processing and Devices / / Shaocong. Hou ; . - 1st ed. 2017. - [S. l. : s. n.]. - XI, 114 p. 76 illus., 53 illus. in color. - Б. ц.
    Зміст:
Overview of Solar Photovoltaic technology --
Film deposition on a wire/fiber via in-situ Joule heating process --
Fiber solar cells utilizing polymer fibers --
Carbon fibers as versatile substrates for fiber solar cells --
Graphene electrocatalysts for fiber dye-sensitized solar cells --
Architectures and working principles of fiber solar cells --
Conclusion.
Рубрики: Renewable energy resources.
   Energy harvesting.
   Optical materials.
   Electronic materials.
   Lasers.
   Photonics.
   Nanotechnology.
   Electrochemistry.
   Renewable and Green Energy.
   Energy Harvesting.
   Optical and Electronic Materials.
   Optics, Lasers, Photonics, Optical Devices.
   Nanotechnology.
   Electrochemistry.
Анотація: This thesis presents the fundamental research and latest findings on novel flexible/wearable photovoltaic technology, and comprehensively summarizes the rapid developments in flexible photovoltaics, from traditional planar solar cells to fiber solar cells. It discusses the rational design of fiber solar cell materials, electrodes and devices, as well as critical factors including cost, efficiency, flexibility and stability . Furthermore, it addresses fundamental theoretical principles and novel fabrication technologies and their potential applications. The book provides practical information for university researchers and graduate students interested in flexible fiber photovoltaics, and inspires them to design other novel flexible/wearable electronics and textiles.

Перейти: https://doi.org/10.1007/978-981-10-2864-9

Дод.точки доступу:
Hou, Shaocong. \.\; SpringerLink (Online service)
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7.


    Dhakar, Lokesh.
    Triboelectric Devices for Power Generation and Self-Powered Sensing Applications [[electronic resource] /] : монография / Lokesh. Dhakar ; . - 1st ed. 2017. - [S. l. : s. n.]. - XXXII, 123 p. 101 illus., 93 illus. in color. - Б. ц.
    Зміст:
Introduction --
Overview of Energy Harvesting Technologies --
Study of Effect of Topography on Triboelectric Nanogenerator Performance Using Patterned Arrays --
Skin Based Self-Powered Wearable Sensors and Nanogenerators --
Large Scale Fabrication of Triboelectric Energy Harvesting and Sensing Applications --
Triboelectric Mechanism for Bidirectional Tactile Sensing and Energy Harvesting --
Conclusion and Recommendations for Future Work.
Рубрики: Energy harvesting.
   Renewable energy resources.
   Materials science.
   Force and energy.
   Energy Harvesting.
   Renewable and Green Energy.
   Energy Materials.
Анотація: This thesis describes the working design principles of triboelectric mechanism-based devices. It presents an extensive study undertaken to explain the effect of surface topographies on the performance of triboelectric nanogenerators. It demonstrates the application of triboelectric mechanisms in the area of physical sensing such as force sensing and pressure sensing. It also discusses the major fabrication methods/techniques that can be used to realize these devices. It is a valuable reference resource for graduate students, researchers and scientists interested in exploring the potential of triboelectric mechanisms for energy harvesting and other applications.

Перейти: https://doi.org/10.1007/978-981-10-3815-0

Дод.точки доступу:
Dhakar, Lokesh. \.\; SpringerLink (Online service)
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8.


   
    Energy Harvesting and Energy Efficiency [[electronic resource] :] : technology, Methods, and Applications / / ed. Bizon, Nicu. [et al.]. - 1st ed. 2017. - [S. l. : s. n.]. - XXVI, 661 p. 440 illus., 106 illus. in color. - Б. ц.
    Зміст:
Energy saving and efficient energy use by power electronics systems --
Energy harvesting sources and power interfaces–a review --
Micro-scale energy harvesting for battery less information technologies --
Efficient energy harvesting systems for vibration and wireless sensor applications --
Nonlinear problems in piezoelectric harvesters under magnetic field --
Energy harvesting from the photo voltaic hybrid power source based on xtremum seeking control schemes --
Energy efficiency of the photo voltaic systems.
Рубрики: Energy harvesting.
   Nanotechnology.
   Renewable energy resources.
   Thermodynamics.
   Heat engineering.
   Heat transfer.
   Mass transfer.
   Energy Harvesting.
   Nanotechnology and Microengineering.
   Renewable and Green Energy.
   Engineering Thermodynamics, Heat and Mass Transfer.
Анотація: This book presents basic and advanced concepts for energy harvesting and energy efficiency, as well as related technologies, methods, and their applications. The book provides up-to-date knowledge and discusses the state-of-the-art equipment and methods used for energy harvesting and energy efficiency, combining theory and practical applications. Containing over 200 illustrations and problems and solutions, the book begins with overview chapters on the status quo in this field. Subsequent chapters introduce readers to advanced concepts and methods. In turn, the final part of the book is dedicated to technical strategies, efficient methods and applications in the field of energy efficiency, which also makes it of interest to technicians in industry. The book tackles problems commonly encountered using basic methods of energy harvesting and energy efficiency, and proposes advanced methods to resolve these issues. All the methods proposed have been validated through simulation and experimental results. These “hot topics” will continue to be of interest to scientists and engineers in future decades and will provide challenges to researchers around the globe as issues of climate change and changing energy policies become more pressing. Here, readers will find all the basic and advanced concepts they need. As such, it offers a valuable, comprehensive guide for all students and practicing engineers who wishing to learn about and work in these fields. .

Перейти: https://doi.org/10.1007/978-3-319-49875-1

Дод.точки доступу:
Bizon, Nicu. \ed.\; Mahdavi Tabatabaei, Naser. \ed.\; Blaabjerg, Frede. \ed.\; Kurt, Erol. \ed.\; SpringerLink (Online service)
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9.


   
    Solar Drying Technology [[electronic resource] :] : concept, Design, Testing, Modeling, Economics, and Environment / / ed.: Prakash, Om., Kumar, Anil. - 1st ed. 2017. - [S. l. : s. n.]. - XXV, 633 p. 343 illus., 90 illus. in color. - Б. ц.
    Зміст:
Introduction to Solar Drying --
Design of various Solar Drying System --
Analysis of the Various type of Solar Dryer --
Performance Analysis of solar dryer in no-load --
Performance Analysis of solar dryer in load condition --
Energy Analysis of the Solar Dryer Author --
Economic Analysis of the Solar Dryer --
Environmental Analysis of the Solar Dryer --
Application of Soft computing if Solar drying --
Application of PCM in Solar drying --
Exergy Analysis of the Solar dryer.
Рубрики: Renewable energy resources.
   Energy systems.
   Energy harvesting.
   Renewable and Green Energy.
   Energy Systems.
   Energy Harvesting.
Анотація: This book offers a comprehensive reference guide to the latest developments and advances in solar drying technology, covering the concept, design, testing, modeling, and economics of solar drying technologies, as well as their impact on the environment. The respective chapters are based on the latest studies conducted by reputed international researchers in the fields of solar energy and solar drying. Offering a perfect blend of research and practice explained in a simple manner, the book represents a valuable resource for researchers, students, professionals, and policymakers working in the field of solar drying and related agricultural applications.

Перейти: https://doi.org/10.1007/978-981-10-3833-4

Дод.точки доступу:
Prakash, Om. \ed.\; Kumar, Anil. \ed.\; SpringerLink (Online service)
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10.


   
    Applications in Electronics Pervading Industry, Environment and Society [[electronic resource] :] : APPLEPIES 2015 / / ed. De Gloria, Alessandro. - 1st ed. 2017. - [S. l. : s. n.]. - IX, 236 p. 140 illus., 111 illus. in color. - Б. ц.
    Зміст:
A Wireless Personal Sensor Node for Real Time Dosimetry of Interventional Radiology Operators --
A New FPGA-based Architecture for Iterative and Space-variant Image Processing --
Embedded Electronic Systems for Tactile Data Processing --
Microwave Imaging for Breast Cancer Detection: A COTS-Based Prototype --
A SystemVerilog-UVM Methodology for the Design, Simulation and Veri?cation of Complex Readout Chips in High Energy Physics Applications --
Embedded System for In-Line Characterization of Industrial Fluids --
A Low Cost, Portable Device for Breath Analysis and Self-Monitoring, the Wize Sni?er.
Рубрики: Electronics.
   Microelectronics.
   Robotics.
   Automation.
   Biomedical engineering.
   Energy harvesting.
   Electronics and Microelectronics, Instrumentation.
   Robotics and Automation.
   Biomedical Engineering and Bioengineering.
   Energy Harvesting.
Анотація: This book provides a thorough overview of cutting-edge research on electronics applications relevant to industry, the environment, and society at large. It covers a broad spectrum of application domains, from automotive to space and from health to security, while devoting special attention to the use of embedded devices and sensors for imaging, communication and control. The book is based on the 2015 ApplePies Conference, held in Rome, which brought together researchers and stakeholders to consider the most significant current trends in the field of applied electronics and to debate visions for the future. Areas addressed by the conference included information communication technology; biotechnology and biomedical imaging; space; secure, clean and efficient energy; the environment; and smart, green and integrated transport. As electronics technology continues to develop apace, constantly meeting previously unthinkable targets, further attention needs to be directed toward the electronics applications and the development of systems that facilitate human activities. This book, written by industrial and academic professionals, represents a valuable contribution in this endeavor.

Перейти: https://doi.org/10.1007/978-3-319-47913-2

Дод.точки доступу:
De Gloria, Alessandro. \ed.\; SpringerLink (Online service)
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11.


   
    Shock & Vibration, Aircraft/Aerospace, Energy Harvesting, Acoustics & Optics, Volume 9 [[electronic resource] :] : proceedings of the 35th IMAC, A Conference and Exposition on Structural Dynamics 2017 / / ed.: Harvie, Julie M., Baqersad, Javad. - 1st ed. 2017. - [S. l. : s. n.]. - IX, 341 p. 285 illus., 250 illus. in color. - Б. ц.
    Зміст:
Chapter 1.Scaling up of the Impedance-Matched Multi-Axis Test (IMMAT) Technique --
Chapter 2.6-DOF Shaker Test Input Derivation from Field Test --
Chapter 3. Frequency Based Spatial Damping Identification – Theoretical and Experimental Comparison --
Chapter 4.Controlability of Aerospace Static Mechanical Loading Coupled with Dynamic Forces --
Chapter 5.Identification of Full-field Dynamic Loads on Structures Using Computer Vision and Unsupervised Machine Learning --
Chapter 6.Research of Under-Sampling Technique for Digital Image Correlation in Vibration Measurement --
Chapter 7.Nonlinear Dynamic Analysis of a Thermally Buckled Aircraft Panel using NNMs --
Chapter 8.Empirically-Derived, Constitutive Damping Model for Cellular Silicone --
Chapter 9.Simultaneous Qualification Testing of Multiple Components and the Influence of Closely Spaced Vibration Modes --
Chapter 10. Extraction of Full-field Structural Dynamics from Digital Video Measurements in Presence of Large Rigid Body Motion --
Chapter 11.Efficient Full-field Operational Modal Analysis using Silicon Retina Imager Measurements --
Chapter 12.Hydro-Mechanical Coupling in Unstable Aircraft Braking Systems --
Chapter 13.Energy Based Representation of 6-Dof Shaker Shock Low-Cycle Fatigue Tests --
Chapter 14.Experimental Execution of 6DOF Tests Derived from Field Tests --
Chapter 15.Vibration of Cracked Timoshenko Beams Made of Functionally Graded Material --
Chapter 16.Eliminating Blur in Small Unmanned Aircraft Imaging Systems --
Chapter 17.Experimental Modal Analysis of an Aircraft Fuselage Panel --
Chapter 18.Nonlinear Vibrations of a Functionally Graded Material Microbeam with Geometric Nonlinearity --
Chapter 19.Method to Predict the Shock Response Spectrum Shape from Frequency Response Functions --
Chapter 20.Investigation and Application of Digital Image Correlation Technology in Vibration Measurement Based on two Cameras --
Chapter 21.A Mission Synthesis Procedure for Sine-on-Random Excitations in a Helicopter Application --
Chapter 22.A Multi-View Digital Image Correlation for Extracting Mode Shapes of a Tire --
Chapter 23.Modal Expansion using Strain Mode Shapes --
Chapter 24.Vibration Suppression of MR Sandwich Beams Based on Fuzzy Logic --
Chapter 25.Logic Analytical Modeling of a Piezoelectric Energy Harvesters Under Random Base Excitation --
Chapter 26.Driving Point FRF Fixture Evaluation for Shock Testing --
Chapter 27.Nonlinear Transverse Vibrations of a Beam with Multiple Breathing Edge Cracks --
Chapter 28.TESS Lens-Bezel Assembly Modal Testing --
Chapter 29.Vibration Suppression in Metastructures Using Zigzag Inserts Optimized by Genetic Algorithms --
Chapter 30.Experimental Modal Analysis on Vibration Data Measured by Digital Image Correlation --
Chapter 31.Rolling Bearing Diagnostics by means of EMD-Based Independent Component Analysis on Vibration and Acoustic Data --
Chapter 32.Flutter and Limit Cycle Oscillation Suppression Using Linear and Nonlinear Tuned Vibration Absorbers --
Chapter 33.A Montecarlo Approach to Test the Modes of Vibration of a 6-DoF Parallel Kinematic Simulator --
Chapter 34.Equating Severity in Qualification Testing --
Chapter 35.Design of an Assembly for Nonlinear Vibration Reduction --
Chapter 36.A Numerical Approach to System Model Identification of Random Vibration Test.
Рубрики: Vibration.
   Dynamical systems.
   Dynamics.
   Aerospace engineering.
   Astronautics.
   Acoustical engineering.
   Energy harvesting.
   Vibration, Dynamical Systems, Control.
   Aerospace Technology and Astronautics.
   Engineering Acoustics.
   Energy Harvesting.
Анотація: Shock & Vibration, Aircraft/Aerospace and Energy Harvesting, Volume 9: Proceedings of the 35th IMAC, A Conference and Exposition on Structural Dynamics, 2017, the ninth volume of ten from the Conference brings together contributions to this important area of research and engineering. The collection presents early findings and case studies on fundamental and applied aspects of Shock & Vibration, Aircraft/Aerospace and Energy Harvesting including papers on: Shock & Vibration Testing Aircraft/Aerospace Applications Optical Techniques: Digital Image Correlation Vibration Suppression & Control Damage Detection Energy Harvesting .

Перейти: https://doi.org/10.1007/978-3-319-54735-0

Дод.точки доступу:
Harvie, Julie M. \ed.\; Baqersad, Javad. \ed.\; SpringerLink (Online service)
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12.


    Ostasevicius, Vytautas.
    Biomechanical Microsystems [[electronic resource] :] : design, Processing and Applications / / Vytautas. Ostasevicius, Janusas, Giedrius. [et al.] ; . - 1st ed. 2017. - [S. l. : s. n.]. - X, 282 p. 266 illus., 151 illus. in color. - Б. ц.
    Зміст:
Introduction --
Development of Microsystems Multi Physics Investigation Methods --
MEMS applications for obesity prevention --
MOEMS-assisted radial pulse measurement system development --
Microsystems for the Effective Technological Processes.
Рубрики: Biomedical engineering.
   Energy harvesting.
   Nanotechnology.
   Mechatronics.
   Biomedical Engineering and Bioengineering.
   Energy Harvesting.
   Nanotechnology and Microengineering.
   Mechatronics.
Анотація: This book presents the most important aspects of analysis of dynamical processes taking place on the human body surface. It provides an overview of the major devices that act as a prevention measure to boost a person‘s motivation for physical activity. A short overview of the most popular MEMS sensors for biomedical applications is given. The development and validation of a multi-level computational model that combines mathematical models of an accelerometer and reduced human body surface tissue is presented. Subsequently, results of finite element analysis are used together with experimental data to evaluate rheological properties of not only human skin but skeletal joints as well. Methodology of development of MOEMS displacement-pressure sensor and adaptation for real-time biological information monitoring, namely “ex vivo” and “in vitro” blood pulse type analysis, is described. Fundamental and conciliatory investigations, achieved knowledge and scientific experience about biologically adaptive multifunctional nanocomposite materials, their properties and synthesis compatibility, periodical microstructures, which may be used in various optical components for modern, productive sensors‘ formation technologies and their application in medicine, pharmacy industries and environmental monitoring, are presented and analyzed. This book also is aimed at research and development of vibrational energy harvester, which would convert ambient kinetic energy into electrical energy by means of the impact-type piezoelectric transducer. The book proposes possible prototypes of devices for non-invasive real-time artery pulse measurements and micro energy harvesting.

Перейти: https://doi.org/10.1007/978-3-319-54849-4

Дод.точки доступу:
Janusas, Giedrius.; Palevicius, Arvydas.; Gaidys, Rimvydas.; Jurenas, Vytautas.; Ostasevicius, Vytautas. \.\; SpringerLink (Online service)
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13.


   
    Engineering Applications of Nanotechnology [[electronic resource] :] : from Energy to Drug Delivery / / ed.: Korada, Viswanatha Sharma., Hisham B Hamid, Nor. - 1st ed. 2017. - [S. l. : s. n.]. - VI, 334 p. 87 illus. - Б. ц.
    Зміст:
Stability of nanofluids --
Influence of Certain Parameters on Properties of Nanofluids Dispersed with Spherical Particles --
Heat transfer enhancement with nanofluids for automotive cooling --
to Ionanofluids Applications and Challenges Nanofluids to Ionanofluids: Applications and Challenges Transparent Carbon nanotubes (CNTs) as antireflection and self-cleaning solar cells coating --
Nanofluids For Enhanced Solar Thermal Energy Conversion --
Thin film hydrodynamic bearing analysis using nanoparticle additive lubricants --
Mechanism of Heat Transfer with Nanofluids for the Application in Oil Wells --
Zinc Oxide Nanoparticles for Enhanced Oil Recovery --
Conclusions --
References.
Рубрики: Nanotechnology.
   Tribology.
   Corrosion and anti-corrosives.
   Coatings.
   Engineering—Materials.
   Energy harvesting.
   Nanotechnology and Microengineering.
   Tribology, Corrosion and Coatings.
   Materials Engineering.
   Energy Harvesting.
Анотація: This book focuses on the use of nanotechnology in several fields of engineering. Among others, the reader will find valuable information as to how nanotechnology can aid in extending the life of component materials exposed to corrosive atmospheres, in thermal fluid energy conversion processes, anti-reflection coatings on photovoltaic cells to yield enhanced output from solar cells, in connection with friction and wear reduction in automobiles, and buoyancy suppression in free convective heat transfer. Moreover, this unique resource presents the latest research on nanoscale transport phenomena and concludes with a look at likely future trends.

Перейти: https://doi.org/10.1007/978-3-319-29761-3

Дод.точки доступу:
Korada, Viswanatha Sharma. \ed.\; Hisham B Hamid, Nor. \ed.\; SpringerLink (Online service)
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14.


    Di Paolo Emilio, Paolo Emilio, Maurizio.
    Microelectronic Circuit Design for Energy Harvesting Systems [[electronic resource] /] : монография / Paolo Emilio, Maurizio. Di Paolo Emilio ; . - 1st ed. 2017. - [S. l. : s. n.]. - XXII, 169 p. 133 illus., 33 illus. in color. - Б. ц.
    Зміст:
Introduction --
The fundamentals of Energy Harvesting --
Input Energy --
Electromagnetic transducers --
Piezoelectric transducers --
Thermoelectric transducers --
Electrostatic transducers --
Powering microsystem --
Low power circuits --
Low-power solutions for biomedical / mobile devices --
Applications of Energy Harvesting --
Index.
Рубрики: Electronic circuits.
   Energy harvesting.
   Electronics.
   Microelectronics.
   Circuits and Systems.
   Energy Harvesting.
   Electronics and Microelectronics, Instrumentation.
Анотація: This book describes the design of microelectronic circuits for energy harvesting, broadband energy conversion, new methods and technologies for energy conversion. The author also discusses the design of power management circuits and the implementation of voltage regulators. Coverage includes advanced methods in low and high power electronics, as well as principles of micro-scale design based on piezoelectric, electromagnetic and thermoelectric technologies with control and conditioning circuit design. Provides a single-source reference to energy harvesting and its applications; Serves as a practical guide to microelectronics design for energy harvesting, with application to mobile power supplies; Enables readers to develop energy harvesting systems for wearable/mobile electronics.

Перейти: https://doi.org/10.1007/978-3-319-47587-5

Дод.точки доступу:
Di Paolo Emilio, Maurizio. \.\; SpringerLink (Online service)
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15.


    Schuster, Christian Stefano.
    Diffractive Optics for Thin-Film Silicon Solar Cells [[electronic resource] /] : монография / Christian Stefano. Schuster ; . - 1st ed. 2017. - [S. l. : s. n.]. - XX, 114 p. 56 illus., 11 illus. in color. - Б. ц.
    Зміст:
Introduction --
Nanostructures for Enhanced Light-Trapping in Thin-Film Silicon Solar Cells --
Fabrication and Characterisation of Diffractive Nanostructures --
Achievements --
Conclusions and Outlook.
Рубрики: Lasers.
   Photonics.
   Energy harvesting.
   Optical materials.
   Electronic materials.
   Nanoscale science.
   Nanoscience.
   Nanostructures.
   Optics, Lasers, Photonics, Optical Devices.
   Energy Harvesting.
   Optical and Electronic Materials.
   Nanoscale Science and Technology.
Анотація: This thesis introduces a figure of merit for light trapping with photonic nanostructures and shows how different light trapping methods compare, irrespective of material, absorber thickness or type of nanostructure. It provides an overview of the essential aspects of light trapping, offering a solid basis for future designs. Light trapping with photonic nanostructures is a powerful method of increasing the absorption in thin film solar cells. Many light trapping methods have been studied, but to date there has been no comprehensive figure of merit to compare these different methods quantitatively. This comparison allows us to establish important design rules for highly performing structures; one such rule is the structuring of the absorber layer from both sides, for which the authors introduce a novel and simple layer-transfer technique. A closely related issue is the question of plasmonic vs. dielectric nanostructures; the authors present an experimental demonstration, aided by a detailed theoretical assessment, highlighting the importance of considering the multipass nature of light trapping in a thin film, which is an essential effect that has been neglected in previous work and which allows us to quantify the parasitic losses. .

Перейти: https://doi.org/10.1007/978-3-319-44278-5

Дод.точки доступу:
Schuster, Christian Stefano. \.\; SpringerLink (Online service)
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16.


    Morgan, Sarah Elizabeth.
    Ultrafast Quantum Effects and Vibrational Dynamics in Organic and Biological Systems [[electronic resource] /] : монография / Sarah Elizabeth. Morgan ; . - 1st ed. 2017. - [S. l. : s. n.]. - XV, 110 p. 72 illus., 65 illus. in color. - Б. ц.
    Зміст:
Introduction --
Methods --
2D Spectroscopy of Pentacene Thin Films --
Time-frequency Analysis for 2D Spectroscopy of PSII --
Nonlinear Network Model of Energy Transfer and Localisation in FMO --
Conclusions.
Рубрики: Spectroscopy.
   Microscopy.
   Biophysics.
   Biological physics.
   Bioorganic chemistry.
   Energy harvesting.
   Atomic structure  .
   Molecular structure .
   Surfaces (Physics).
   Interfaces (Physical sciences).
   Thin films.
   Spectroscopy and Microscopy.
   Biological and Medical Physics, Biophysics.
   Bioorganic Chemistry.
   Energy Harvesting.
   Atomic/Molecular Structure and Spectra.
   Surface and Interface Science, Thin Films.
Анотація: This thesis focuses on theoretical analysis of the sophisticated ultrafast optical experiments that probe the crucial first few picoseconds of quantum light harvesting, making an important contribution to quantum biology, an exciting new field at the intersection of condensed matter, physical chemistry and biology. It provides new insights into the role of vibrational dynamics during singlet fission of organic pentacene thin films, and targeting the importance of vibrational dynamics in the design of nanoscale organic light harvesting devices, it also develops a new wavelet analysis technique to probe vibronic dynamics in time-resolved nonlinear optical experiments. Lastly, the thesis explores the theory of how non-linear “breather” vibrations are excited and propagate in the disordered nanostructures of photosynthetic proteins.   .

Перейти: https://doi.org/10.1007/978-3-319-63399-2

Дод.точки доступу:
Morgan, Sarah Elizabeth. \.\; SpringerLink (Online service)
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17.


    Swift, Gregory W.
    Thermoacoustics [[electronic resource] :] : a Unifying Perspective for Some Engines and Refrigerators / / Gregory W. Swift ; . - 2nd ed. 2017. - [S. l. : s. n.]. - XXI, 326 p. 132 illus., 26 illus. in color. - Б. ц.
    Зміст:
Preface --
About the Author --
List of Symbols --
1 Introduction --
2 Background --
3 Simple Oscillations --
4 Waves --
5 Power --
6 Efficiency --
7 Beyond Rott's Thermoacoustics --
8 Hardware --
9 Measurements --
Appendix A Common Pitfalls --
Appendix B DeltaEC Files --
Bibliography --
Author Index --
Subject Index.
Рубрики: Acoustics.
   Thermodynamics.
   Heat engineering.
   Heat transfer.
   Mass transfer.
   Energy harvesting.
   Acoustical engineering.
   Acoustics.
   Engineering Thermodynamics, Heat and Mass Transfer.
   Energy Harvesting.
   Engineering Acoustics.
   Thermodynamics.
Анотація: This updated new edition provides an introduction to the field of thermoacoustics. All of the key aspects of the topic are introduced, with the goal of helping the reader to acquire both an intuitive understanding and the ability to design hardware, build it, and assess its performance. Weaving together intuition, mathematics, and experimental results, this text equips readers with the tools to bridge the fields of thermodynamics and acoustics. At the same time, it remains firmly grounded in experimental results, basing its discussions on the distillation of a body of experiments spanning several decades and countries. The book begins with detailed treatment of the fundamental physical laws that underlie thermoacoustics. It then goes on to discuss key concepts, including simple oscillations, waves, power, and efficiency. The remaining portions of the book delve into more advanced topics and address practical concerns in applications chapters on hardware and m easurements. With its careful progression and end-of-- Chapter exercises, this book will appeal to graduate students in physics and engineering as well as researchers and practitioners in either acoustics or thermodynamics looking to explore the possibilities of thermoacoustics. This revised and expanded second edition has been updated with an eye to modern technology, including computer animations and DeltaEC examples. Written by the undisputed leader in thermoacoustics Represents a gateway into the field of thermoacoustics for engineers and acousticians alike Bridges the fields of acoustics and thermodynamics, opening up new technological possibilities Contains access to computer animations and DeltaEC examples.

Перейти: https://doi.org/10.1007/978-3-319-66933-5

Дод.точки доступу:
Swift, Gregory W. \.\; SpringerLink (Online service)
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