In his celebrated lecture at the APS meeting in 1959, Richard Feynman pondered the potential of miniaturization in the physical sciences and proposed a variety of new nano-tools. Since then, many of these predictions have become reality including the development and application of nanofluidics. This timely book fills a gap in the current reference literature in this exciting and growing field and is dedicated to the field of nanofluidics with a focus on bioanalytical applications. These nanoscale analytical instruments employ micromachined features and are able to manipulate fluid samples with high precision and efficiency. The book is written at a level accessible to experts and non-experts alike and is essential reading for all advanced nanobiotechnology courses within academic institutions.
The Nanoscience and Nanotechnology Series provides a comprehensive resource of books covering key topics such as the synthesis, characterisation, performance and properties of nanostructured materials and technologies and their applications.
This book is a compendium of the finest research in nanoplasmonic sensing done around the world in the last decade. It describes basic theoretical considerations of nanoplasmons in the dielectric environment, gives examples of the multitude of applications of nanoplasmonics in biomedical and chemical sensing, and provides an overview of future trends in optical and non-optical nanoplasmonic sensing. Specifically, readers are guided through both the fundamentals and the latest research in the two major fields nanoplasmonic sensing is applied to – bio- and chemo-sensing – then given the state-of-the-art recipes used in nanoplasmonic sensing research.
Taking you to the forefront of the emerging field of Nanofluidics, this cutting-edge book details the physics and applications of fluid flow in nanometer scale channels. You gain a solid understanding of the fundamental aspects of transport processes and force interactions in microscale. Moreover, this unique resource presents the latest research on nanoscale transport phenomena. You find a comprehensive overview of fabrication technologies for nanotechnologies, including detailed technology recipes and parameters. The book concludes with a look at future trends and the possible directions this new field could take.
Multidisciplinary Microfluidic and Nanofluidic Lab-on-a-Chip: Principles and Applications provides chemists, biophysicists, engineers, life scientists, biotechnologists, and pharmaceutical scientists with the principles behind the design, manufacture, and testing of life sciences microfluidic systems. This book serves as a reference for technologies and applications in multidisciplinary areas, with an emphasis on quickly developing or new emerging areas, including digital microfluidics, nanofluidics, papers-based microfluidics, and cell biology. The book offers practical guidance on how to design, analyze, fabricate, and test microfluidic devices and systems for a wide variety of applications including separations, disease detection, cellular analysis, DNA analysis, proteomics, and drug delivery. Calculations, solved problems, data tables, and design rules are provided to help researchers understand microfluidic basic theory and principles and apply this knowledge to their own unique designs. Recent advances in microfluidics and microsystems for life sciences are impacting chemistry, biophysics, molecular, cell biology, and medicine for applications that include DNA analysis, drug discovery, disease research, and biofluid and environmental monitoring. - Provides calculations, solved problems, data tables and design rules to help understand microfluidic basic theory and principles - Gives an applied understanding of the principles behind the design, manufacture, and testing of microfluidic systems - Emphasizes on quickly developing and emerging areas, including digital microfluidics, nanofluidics, papers-based microfluidics, and cell biology
Mikro- und Nanotechnik haben Wissenschaft und Forschung revolutioniert. In Zukunft werden sie auch den Alltag verändern. Nun liegt der erste Band einer neuen Buchreihe vor: Advanced Micro and Nano Systems 1. Henry Baltes und seine Co-Autoren knüpfen mit AMN an die Sensors Update-Reihe an. Das Autorenteam wurde um weitere Experten erweitert. AMN wird zwei Mal pro Jahr mit einem neuen Band die aktuellen Entwicklungen in der Mikro- und Nano-Welt begleiten. Die Erforschung und der Einsatz von Mikro- und Nanosystemen sind eines der brandaktuellen Themen im Wissenschaftsbereich. Die Forschungsergebnisse werden mehr und mehr auch konkret umgesetzt. Damit werden Mikro- und Nanotechnologie zu Wirtschaftsfaktoren. Aktuelle Entwicklungen, neue Technologien, Nano-Bauelemente und Systeme im Mikromaßstab - Advanced Micro and Nano Systems, die neue Buchreihe, wird Spiegel der spannenden und faszinierenden Mikro- und Nano-Welt sein. Zweimal pro Jahr wird es einen neuen AMN-Band geben. Die Autoren sind ausgewiesene Spezialisten. Zu den Herausgebern zählt Henry Baltes, Professor an der ETH Zürich. Er zeichnete bereits für die Bände der Sensors Update-Reihe verantwortlich. Die Artikel ermöglichen Neueinsteigern einen ersten Zugriff auf die Materie. Fachleute erhalten einen umfassenden Überblick. Anspruch der Herausgeber ist es, nicht nur die theoretischen Grundlagen von Mikro- und Nanosystemen zu reflektieren, sondern immer auch praktische Möglichkeiten und die Grenzen der Anwendung im Blick zu haben. Die AMN-Bände sind Handbücher und Nachschlagewerke in einem. Die Reihe richtet sich an Vertreter unterschiedlicher Fachrichtungen: Biologie, Chemie, Mathematik, Sensorindustrie und Materialwissenschaften.
This book presents a detailed overview of the design, formatting, application, and development of microfluidic chips in the context of cell biology research, enumerating each element involved in microfluidics-based cell analysis, discussing its history, status quo, and future prospects, It also offers an extensive review of the research completed in the past decade, including numerous color figures. The individual chapters are based on the respective authors' studies and experiences, providing tips from the frontline to help researchers overcome bottlenecks in their own work. It highlights a number of cutting-edge techniques, such as 3D cell culture, microfluidic droplet technique, and microfluidic chip-mass spectrometry interfaces, offering a first-hand impression of the latest trends in the field and suggesting new research directions. Serving as both an elementary introduction and advanced guidebook, the book interests and inspires scholars and students who are currently studying microfluidics-based cell analysis methods as well as those who wish to do so.
From the reviews: "...A class in nanoscale science and technology is daunting for the educator, who must organize a large collection of materials to cover the field, and for the student, who must absorb all the new concepts. This textbook is an excellent resource that allows students from any engineering background to quickly understand the foundations and exciting advances of the field. The example problems with answers and the long list of references in each chapter are a big plus for course tutors. The book is organized into seven sections. The first, nanoscale fabrication and characterization, covers nanolithography, self-assembly, and scanning probe microscopy. Of these, we enjoyed the section on nanolithography most, as it includes many interesting details from industrial manufacturing processes. The chapter on self-assembly also provides an excellent overview by introducing six types of intermolecular interactions and the ways these can be employed to fabricate nanostructures. The second section covers nanomaterials and nanostructures. Out of its 110 pages, 45 are devoted to carbon nanotubes. Fullerenes and quantum dots each have their own chapter that focuses on the properties and applications of these nanostructures. Nanolayer, nanowire, and nanoparticle composites of metals and semiconductors are briefly covered (just 12 pages), with slightly more discussion of specific applications. The section on nanoscale electronics begins with a history of microelectronics before discussing the difficulties in shrinking transistor size further. The discussion of problems (leakage current, hot electrons, doping fluctuations, etc.) and possible solutions (high- k dielectrics, double-gate devices) could easily motivate deeper discussions of nanoscale electrical transport. A chapter on molecular electronics considers transport through alkanes, molecular transistors, and DNA in a simple, qualitative manner we found highly instructive. Nanoscale magnetic systems are examined in the fourth section. The concept of quantum computation is nicely presented, although the discussion of how this can be achieved with controlled spin states is (perhaps necessarily) not clear. We found the chapter on magnetic storage to be one of the most lucid in the book. The giant magnetoresistive effect, operation of spin valves, and issues in magnetic scaling are easier to understand when placed in the context of the modern magnetic hard disk drive. Micro- and nanoelectromechanical systems are covered with an emphasis on the integration of sensing, computation, and communication. Here, the student can see advanced applications of lithography. The sixth section, nanoscale optoelectronics, describes quantum dots, organic optoelectronics, and photonic crystals. The chapter on organic optoelectronics is especially clear in its discussion of the fundamentals of this complicated field. The book concludes with an overview of nanobiotechnology that covers biomimetics, biomolecular motors, and nanofluidics. Because so many authors have contributed to this textbook, it suffers a bit from repetition. However, this also allows sections to be omitted without any adverse effect on student comprehension. We would have liked to see more technology to balance the science; apart from the chapters on lithography and magnetic storage, little more than an acknowledgment is given to commercial applications. Overall, this book serves as an excellent starting point for the study of nanoscale science and technology, and we recommend it to anyone with a modest scientific background. It is also a great vehicle to motivate the study of science at a time when interest is waning. Nanotechnology educators should look no further." (MATERIALS TODAY, June 2005)
For the past decade, new research fields utilizing microfluidics have been formed. General micro-integration methods were proposed, and the supporting fundamental technologies were widely developed. These methodologies have made various applications in the fields of analytical and chemical synthesis, and their superior performances such as rapid, simple, and high efficient processing have been proved. Recently, the space is further downscaling to 101 103nm scale (we call the space extended-nano space). The extended-nano space located between the conventional nanotechnology (100 101nm) and microtechnology (>1 m), and the research tools are not well established. In addition, the extended-nano space is a transient space from single molecules to bulk condensed phase, and fluidics and chemistry are not unknown. For these purposes, basic methodologies were developed, and new specific phenomena in fluidics and chemistry were found. These new phenomena were applied to unique chemical operations such as concentration and ion selection. The new research fields which are now being created are quite different from those in microspace. Unique devices are also increasingly being reported. In this book, we describe the fundamental technologies for extended-nano space and show the unique liquid properties found in this space and applications for single molecule or cell analysis. The research area is very new and hence, exciting. In contrast to other specialized areas, the research fields require wide knowledge (chemistry, fluidics, mechanics, photonics, biology etc.) and state-of-the-art technologies (bottom-up and top-down fabrication for various hard and soft materials, precise fluidic control, single molecule detection methods, and particle surface modification methods etc.), which have not been not covered by conventional review papers or books. Therefore, researchers or students new to the field need a new book covering these fields including recent research topics, applications and problems to be solved in the future. Our motivation is to summarize the state-of-the-art technologies for research and demonstrate new chemistry and fluidics in extended-nano space for students and researchers in academia or industry. We also emphasize the potential large impact microfluidic technologies have on chemistry and biochemistry.
Nanotechnology, especially microfabrication, has been affecting every facet of traditional scientific disciplines. The first book on the application of microfluidic reactors in nanotechnology, Microfluidic Devices in Nanotechnology provides the fundamental aspects and potential applications of microfluidic devices, the physics of microfluids, specific methods of chemical synthesis of nanomaterials, and more. As the first book to discuss the unique properties and capabilities of these nanomaterials in the miniaturization of devices, this text serves as a one-stop resource for nanoscientists interested in microdevices.
