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Author: Shuo Wang
Publisher:
ISBN: 9781658412209
Category :
Languages : en
Pages :
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Book Description
Three-dimensional (3D) printing has been an active area of research and development due to its capability to produce 3D objects by design. 3D printers are commercially available with resolution as high as micrometers. Further miniaturization to reach nanometer scale would require development of materials, instruments, and methodology to attain required spatial precision. This dissertation reports our recent progress in facilitating the development of 3D micro- and nano-printing technologies using atomic force microscopy (AFM)-based methods. Followed by introduction and description of techniques utilized in this dissertation, Chapter 3 describes a new 3D nanoprinting method via direct delivery based on an integrated atomic force microscopy (AFM) and microfluidic platform. This platform combines the high spatial precision of AFM with the direct delivery capability of microfluidics. Designed structures were printed layer-by-layer with intra- and inter-layer alignment reaching nanometer precision. The resulting 3D structures demonstrate high degree control over spatial and material delivery. Chapter 4 describes a new algorithm developed to enable construction and display of layer-by-layer 3D structures from scanning probe microscopy (SPM) images. The algorithm enables alignment of SPM images acquired during layer-by-layer deposition and removal of redundant features to faithfully construct the deposited 3D structures. The display uses a "see-through" strategy to make the structure of each layer to be visible. The results demonstrate high spatial accuracy and algorithm versatility. To the best of our knowledge, this represents the first report to enable SPM technology for 3D imaging construction and display. The detailed algorithm is provided to facilitate usage of the same approach in any SPM software. These new capabilities support wide application of SPM that require 3D image reconstruction and display, such as 3D nanoprinting, and 3D additive and subtractive manufacturing and imaging. Chapter 5 presents a new chemistry, referred to as "controlled assembly" developed based on our 3D printing technology. In this work, delivery of sub-fL solution onto a designed surface was achieved using our AFM/microfluidic platform, the rapid evaporation of solvent leads to assemblies of solute molecules. Controlled molecular assembly has previously been demonstrated using macromolecules in 0 dimension (0D). In this work, we pushed the limit of this control into smaller molecules using a tetrazine derivative (MW of 8.1 kD, hydrodynamic radius around 1.5 nm), and using patterned surfaces to further control the solution distribution. Control over molecular assemblies in both 0D and 1D cases were demonstrated. The three technology developments, collectively, bring us much closer to realize 3D nanoprinting with advanced applications such as in nanophotonics, nanoelectronics, micro- and nano-fluidic devices, new nanocomposite materials, and tissue engineering. In Chapter 6, production of custom-designed micro-droplets networks is demonstrated by delivery of water molecule in oil. Cell-sized micro droplets by design is easily produced and directly delivered to the designed locations under our setup. Further changes of the droplet network can also be achieved if necessary by moving individual droplets using the same probe to designated locations. This new method paves the way to study and prepare networks of bio-compartment and artificial cells, and contributes to a fundamental study to facilitate 3D nanoprinting in liquid phase. Finally, summary and future perspectives are provided in Chapter 7.
Author: Shuo Wang
Publisher:
ISBN: 9781658412209
Category :
Languages : en
Pages :
Get Book Here
Book Description
Three-dimensional (3D) printing has been an active area of research and development due to its capability to produce 3D objects by design. 3D printers are commercially available with resolution as high as micrometers. Further miniaturization to reach nanometer scale would require development of materials, instruments, and methodology to attain required spatial precision. This dissertation reports our recent progress in facilitating the development of 3D micro- and nano-printing technologies using atomic force microscopy (AFM)-based methods. Followed by introduction and description of techniques utilized in this dissertation, Chapter 3 describes a new 3D nanoprinting method via direct delivery based on an integrated atomic force microscopy (AFM) and microfluidic platform. This platform combines the high spatial precision of AFM with the direct delivery capability of microfluidics. Designed structures were printed layer-by-layer with intra- and inter-layer alignment reaching nanometer precision. The resulting 3D structures demonstrate high degree control over spatial and material delivery. Chapter 4 describes a new algorithm developed to enable construction and display of layer-by-layer 3D structures from scanning probe microscopy (SPM) images. The algorithm enables alignment of SPM images acquired during layer-by-layer deposition and removal of redundant features to faithfully construct the deposited 3D structures. The display uses a "see-through" strategy to make the structure of each layer to be visible. The results demonstrate high spatial accuracy and algorithm versatility. To the best of our knowledge, this represents the first report to enable SPM technology for 3D imaging construction and display. The detailed algorithm is provided to facilitate usage of the same approach in any SPM software. These new capabilities support wide application of SPM that require 3D image reconstruction and display, such as 3D nanoprinting, and 3D additive and subtractive manufacturing and imaging. Chapter 5 presents a new chemistry, referred to as "controlled assembly" developed based on our 3D printing technology. In this work, delivery of sub-fL solution onto a designed surface was achieved using our AFM/microfluidic platform, the rapid evaporation of solvent leads to assemblies of solute molecules. Controlled molecular assembly has previously been demonstrated using macromolecules in 0 dimension (0D). In this work, we pushed the limit of this control into smaller molecules using a tetrazine derivative (MW of 8.1 kD, hydrodynamic radius around 1.5 nm), and using patterned surfaces to further control the solution distribution. Control over molecular assemblies in both 0D and 1D cases were demonstrated. The three technology developments, collectively, bring us much closer to realize 3D nanoprinting with advanced applications such as in nanophotonics, nanoelectronics, micro- and nano-fluidic devices, new nanocomposite materials, and tissue engineering. In Chapter 6, production of custom-designed micro-droplets networks is demonstrated by delivery of water molecule in oil. Cell-sized micro droplets by design is easily produced and directly delivered to the designed locations under our setup. Further changes of the droplet network can also be achieved if necessary by moving individual droplets using the same probe to designated locations. This new method paves the way to study and prepare networks of bio-compartment and artificial cells, and contributes to a fundamental study to facilitate 3D nanoprinting in liquid phase. Finally, summary and future perspectives are provided in Chapter 7.
Author: Bharat Bhushan
Publisher: Springer
ISBN: 9783662506011
Category :
Languages : en
Pages : 844
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Book Description
This book presents the physical and technical foundation of the state of the art in applied scanning probe techniques. It constitutes a timely and comprehensive overview of SPM applications. The chapters in this volume relate to scanning probe microscopy techniques, characterization of various materials and structures and typical industrial applications, including topographic and dynamical surface studies of thin-film semiconductors, polymers, paper, ceramics, and magnetic and biological materials. The chapters are written by leading researchers and application scientists from all over the world and from various industries to provide a broader perspective.
Author: Logan Swartz
Publisher:
ISBN: 9780438627529
Category :
Languages : en
Pages :
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Book Description
Three dimensional (3D) printing has been an active area of research and development due to its capability to produce 3D objects by design. Miniaturization and improvement of spatial resolution are major challenges in current 3D printing technology development. This dissertation reports advances in bringing 3D nanolithography to the nanometer scale using scanning probe microscopy (SPM). SPM uses nanometer scale sharp tips to probe localized tip material interactions at the atomic and/or molecular level. Taking advantage of the interactions to instead print materials, in conjunction with SPM’s nanometer precision piezo based positioning systems and local surface chemistry, we have been able to develop methods to advance 3D printing to 3D nanolithography/nanoprinting. Three methods were developed. The first presented culminated in the first patented, 3D nanoprinter. It involves directly delivering polyelectrolyte complex materials layer-by-layer using an atomic force microscopy (AFM) probe. This enabled creation of 3D nanostructures with nanometer precision in all three dimensions. The second method describes development of a new technique for near-field scanning optical microscopy (NSOM) nanolithography. NSOM lithography uses an SPM probe as a local light source to break the diffraction limit to perform photolithography. We have created new versions of these probes by developing ways to attach fluorescent nanoparticles to the end of AFM probes. Then using the probes, we developed a method for nanoparticle modified probe NSOM nanolithography. The third method is a convenient way to modify with in situ control AFM probes to have a flat surface/plateau at their end. These plateau probes, mounted on an AFM, are useful for compression studies to measure the created nanostructures’ nanomechanical properties. Also plateau probes provides a uniform surface to attach nanoparticles in order to create new probes for the nanoparticle modified probe NSOM nanolithography method, ensuring the attached particles are the furthest protrusion of the tips.
Author: Bharat Bhushan
Publisher: Springer Science & Business Media
ISBN: 3642254136
Category : Science
Languages : en
Pages : 634
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Book Description
This book presents the physical and technical foundation of the state of the art in applied scanning probe techniques. It constitutes a timely and comprehensive overview of SPM applications. The chapters in this volume relate to scanning probe microscopy techniques, characterization of various materials and structures and typical industrial applications, including topographic and dynamical surface studies of thin-film semiconductors, polymers, paper, ceramics, and magnetic and biological materials. The chapters are written by leading researchers and application scientists from all over the world and from various industries to provide a broader perspective.
Author: Ernst Meyer
Publisher: Springer Science & Business Media
ISBN: 3662098016
Category : Science
Languages : en
Pages : 215
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Book Description
Written by three leading experts in the field, this textbook describes and explains all aspects of the scanning probe microscopy. Emphasis is placed on the experimental design and procedures required to optimize the performance of the various methods. Scanning Probe Microscopy covers not only the physical principles behind scanning probe microscopy but also questions of instrumental designs, basic features of the different imaging modes, and recurring artifacts. The intention is to provide a general textbook for all types of classes that address scanning probe microscopy. Third year undergraduates and beyond should be able to use it for self-study or as textbook to accompany a course on probe microscopy. Furthermore, it will be valuable as reference book in any scanning probe microscopy laboratory. Novel applications and the latest important results are also presented, and the book closes with a look at the future prospects of scanning probe microscopy, also discussing related techniques in nanoscience. Ideally suited as an introduction for graduate students, the book will also serve as a valuable reference for practising researchers developing and using scanning probe techniques.
Author: Joao Francisco Ventrici de Souza
Publisher:
ISBN: 9780355461411
Category :
Languages : en
Pages :
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Book Description
Three-dimension (3D) printers are commercially available with resolution as high as micrometers. Further miniaturization would require development of both materials, instruments, as well as methodology in order to attain required spatial precision to reach nanometer scale. This dissertation reports our recent progress in producing 3D nanostructures using an atomic force microscopy (AFM) based methods. First, we use AFM to investigate and to better understanding the tip-molecular and molecule-molecules interactions using bilayer systems to begin the studies. The structure, phase behavior and properties of cellular membranes are determined by their composition which includes phospholipids, sphingolipids, sterols, and proteins with various level of glycosylation. Due to the intricate nature of cellular membranes, a plethora of in vitro studies have been carried out with model membrane platforms that capture specific properties such as fluidity and permeability, but vastly simplify the membrane composition in order to focus in detail on a single property or function. Supported lipid bilayer (SLB) systems are one such platform and this work focuses specifically on the characterization and engineering of SLB systems. A number of characterization methods which take advantage of the flat orientation of SLBs are described and references which go into more depth are included. This dissertation reports quantity and compares the quality of the resulting SLBs in correlation with a variety of gel and fluid compositions, preparation techniques and parameters, to generate general rules of thumb to guide preparation of designed SLB systems. Finally, our approaches to reduce morphologic defects are delineated. Secondly, we use modified AFM technology for both printing and characterization. By putting molecules to the AFM tips, then transfer them to surfaces via scanning, nanometer scale lines, cross-grids, and pyramids were constructed following designed geometry and size. The products were also characterized in situ using AFM to demonstrate the fidelity and spatial precision. Another approach taken in this dissertation towards the 3D nanoprinting goal is the direct delivery via combining AFM with microfluidic probes. Direct writing methods are a convenient way to produce 3D structures. The capability to extrude materials through a nozzle makes this method compatible with a wide range of inks. Although this method has been routinely used in the fabrication of structures on the microscale, the new challenge is to achieve 3D printing on the nanoscale. This dissertation reports the miniaturization of 3D structure production to line widths of 130 nm and heights of 3.1 nm. Three layered grids and custom designed objects were printed with the direct delivery of ultraviolet curable polymer. using a modified atomic force microscope (AFM). The enabling aspects of 3D nanoprinting should have significant impact on a broad range of applications including tissue engineering, biomaterials, biomimetics, nanophotonics materials, and nanodevices.
Author: Seizo Morita
Publisher: Springer Science & Business Media
ISBN: 3540343156
Category : Technology & Engineering
Languages : en
Pages : 207
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Book Description
Scanning tunneling microscopy has achieved remarkable progress and become the key technology for surface science. This book predicts the future development for all of scanning probe microscopy (SPM). Such forecasts may help to determine the course ultimately taken and may accelerate research and development on nanotechnology and nanoscience, as well as all in SPM-related fields in the future.
Author: Ajit Behera
Publisher: CRC Press
ISBN: 1000637573
Category : Technology & Engineering
Languages : en
Pages : 343
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Book Description
Examining smart 3D printing at the nanoscale, this book discusses various methods of fabrication, the presence of inherent defects and their annihilation, property analysis, and emerging applications across an array of industries. The book serves to bridge the gap between the concept of nanotechnology and the tailorable properties of smart 3D-print products. FEATURES Covers surface and interface analysis and smart technologies in 3D nanoprinting Details different materials, such as polymers, metals, semiconductors, glassceramics, and composites, as well as their selection criteria, fabrication, and defect analysis at nanoscale Describes optimization and modeling and the effect of machine parameters on 3D-printed products Discusses critical barriers and opportunities Explores emerging applications in manufacturing industries, such as aerospace, healthcare, automotive, energy, construction, and defense Smart 3D Nanoprinting: Fundamentals, Materials, and Applications is aimed at advanced students, researchers, and industry professionals in materials, manufacturing, chemical, and mechanical engineering. This book offers readers a comprehensive overview of the properties, opportunities, and applications of smart 3D nanoprinting.
Author: Dalia G. Yablon
Publisher: John Wiley & Sons
ISBN: 111872304X
Category : Technology & Engineering
Languages : en
Pages : 337
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Book Description
Describes new state-of-the-science tools and their contribution to industrial R&D With contributions from leading international experts in the field, this book explains how scanning probe microscopy is used in industry, resulting in improved product formulation, enhanced processes, better quality control and assurance, and new business opportunities. Readers will learn about the use of scanning probe microscopy to support R&D efforts in the semiconductor, chemical, personal care product, biomaterial, pharmaceutical, and food science industries, among others. Scanning Probe Microscopy in Industrial Applications emphasizes nanomechanical characterization using scanning probe microscopy. The first half of the book is dedicated to a general overview of nanomechanical characterization methods, offering a complete practical tutorial for readers who are new to the topic. Several chapters include worked examples of useful calculations such as using Hertz mechanics with and without adhesion to model a contact, step-by-step instructions for simulations to guide cantilever selection for an experiment, and data analysis procedures for dynamic contact experiments. The second half of the book describes applications of nanomechanical characterization in industry, including: New formulation development for pharmaceuticals Measurement of critical dimensions and thin dielectric films in the semiconductor industry Effect of humidity and temperature on biomaterials Characterization of polymer blends to guide product formulation in the chemicals sector Unraveling links between food structure and function in the food industry Contributions are based on the authors' thorough review of the current literature as well as their own firsthand experience applying scanning probe microscopy to solve industrial R&D problems. By explaining the fundamentals before advancing to applications, Scanning Probe Microscopy in Industrial Applications offers a complete treatise that is accessible to both novices and professionals. All readers will discover how to apply scanning probe microscopy to build and enhance their R&D efforts.
Author: Sergei V. Kalinin
Publisher: Springer Science & Business Media
ISBN: 144197167X
Category : Technology & Engineering
Languages : en
Pages : 563
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Book Description
The goal of this book is to provide a general overview of the rapidly developing field of novel scanning probe microscopy (SPM) techniques for characterization of a wide range of functional materials, including complex oxides, biopolymers, and semiconductors. Many recent advances in condensed matter physics and materials science, including transport mechanisms in carbon nanostructures and the role of disorder on high temperature superconductivity, would have been impossible without SPM. The unique aspect of SPM is its potential for imaging functional properties of materials as opposed to structural characterization by electron microscopy. Examples include electrical transport and magnetic, optical, and electromechanical properties. By bringing together critical reviews by leading researchers on the application of SPM to to the nanoscale characterization of functional materials properties, this book provides insight into fundamental and technological advances and future trends in key areas of nanoscience and nanotechnology.
