Relevant bibliographies by topics / Micro/nano-technology

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  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Micro/nano-technology'

Author: Grafiati
Published: 4 June 2021
Last updated: 21 June 2025

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Journal articles on the topic "Micro/nano-technology"

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Tang, Fei, and Sishen Xie. "Preface: Micro-Nano Technology." AIP Advances 4, no. 3 (2014): 031201. http://dx.doi.org/10.1063/1.4870333.

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Tang, Fei, and Sishen Xie. "Preface: Micro-Nano Technology." AIP Advances 5, no. 4 (2015): 041201. http://dx.doi.org/10.1063/1.4919284.

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YANG, Ming. "Technology on Nano/Micro Manufacturing." Journal of the Japan Society for Technology of Plasticity 52, no. 600 (2011): 145–47. http://dx.doi.org/10.9773/sosei.52.145.

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Doumanidis, Charalabos C., and Delcie Durham. "Micro-/nano-technology special issue." Computer-Aided Design 39, no. 3 (2007): 177–78. http://dx.doi.org/10.1016/j.cad.2007.01.006.

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ASHCROFT, JARED, and BILLIE COPLEY. "Invited Letter: Micro Nano Technology Education Center." Journal of Advanced Technological Education 1, no. 1 (2022): 43–45. https://doi.org/10.5281/zenodo.6363595.

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The Micro Nano Technology Education Center is a community college led National Science Foundation Advanced Technological Education Center founded on the idea that by working together to evolve and improve community college micro and nanotechnology technical education programs, we will enhance the quality of education for MNT students who then become higher quality technicians for the MNT industry and skilled technical workforce.
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Blankenstein, G., and R. Wechsung. "Micro-nano-technology for biomedical application." NanoBiotechnology 1, no. 3 (2005): 275–76. http://dx.doi.org/10.1007/s12030-005-0038-4.

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Li, Bowen, Zhitong Xu, Gaohan Duan, et al. "The Fluidized Bed-Chemical Vapor Deposition Coating Technology of Micro-Nano Particles: Status and Prospective." Coatings 15, no. 3 (2025): 322. https://doi.org/10.3390/coatings15030322.

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Fluidized bed-chemical vapor deposition (FB-CVD) technology stands as a cross-cutting achievement of fluidized bed technology in chemical engineering and chemical vapor deposition (CVD) in materials science, finding applications in particle coating, granulation, and material preparation. As compared to conventional CVD technology, FB-CVD distinguishes itself through enhanced heat/mass transfer efficiency, achieving a uniform coating layer while maintaining low production costs. Given the related research on FB-CVD micro-nano particle coating, the mechanism of particle fluidization and chemical vapor deposition, and the difficulty of micro-nano particle agglomeration were summarized. The process intensification of micro-nano particle fluidization assisted by particle design and external force field, such as vibration field, magnetic field, and sound field, and micro-nano particle chemical vapor deposition coating were summarized. In particular, applications of FB-CVD micro-nano particle coating are introduced. Finally, the opportunities and challenges faced by FB-CVD micro-nano particle coating technology are discussed, and the development prospect of this technology is prospected. This review is beneficial for the researchers of the fluidization field, and also the particle coating technology.
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Li, G. P., and Mark Bachman. "Materials for Devices in Life Science Applications." Solid State Phenomena 124-126 (June 2007): 1157–60. http://dx.doi.org/10.4028/www.scientific.net/ssp.124-126.1157.

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The unprecedented technology advancements in miniaturizing integrated circuits, and the resulting plethora of sophisticated, low cost electronic devices demonstrate the impact that micro/nano scale engineering can have when applied only to the area of electrical and computer engineering. Current research efforts in micro/nano fabrication technology for implementing integrated devices hope to yield similar revolutions in life science fields. The integrated life chip technology requires the integration of multiple materials, phenomena, technologies, and functions at micro/nano scales. By cross linking the individual engineering fields through micro/nano technology, various miniaturized life chips will have future impacts in the application markets such as medicine and healthcare.
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Li, G. P., and Mark Bachman. "Materials for Devices Applications in Life Sciences." Materials Science Forum 510-511 (March 2006): 1066–69. http://dx.doi.org/10.4028/www.scientific.net/msf.510-511.1066.

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The unprecedented technology advancements in miniaturizing integrated circuits, and the resulting plethora of sophisticated, low cost electronic devices demonstrate the impact that micro/nano scale engineering can have when applied only to the area of electrical and computer engineering. Current research efforts in micro/nano fabrication technology for implementing integrated devices hope to yield similar revolutions in life science fields. The integrated life chip technology requires the integration of multiple materials, phenomena, technologies, and functions at micro/nano scales. By cross linking the individual engineering fields through micro/nano technology, various miniaturized life chips have been developed at UCI that will have future impacts in the application markets such as medicine and healthcare.
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FUJISHIRO, Yoshinobu, Toshio SUZUKI, Toshiaki YAMAGUCHI, Hirofumi SUMI, and Masanobu AWANO. "Nano-Composite Electrode Technology on Micro SOFC." JOURNAL OF THE JAPAN WELDING SOCIETY 84, no. 3 (2015): 193–95. http://dx.doi.org/10.2207/jjws.84.193.

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Dissertations / Theses on the topic "Micro/nano-technology"

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Dorrington, Peter. "An investigation of the UK micro- and nano- technology government intervention." Thesis, Cardiff University, 2011. http://orca.cf.ac.uk/17870/.

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This study investigates a recent UK Government Intervention established to develop Micro- and Nano- Technologies (MNTs) for technology-based economic growth. While the need for such innovation policies is well recognised, there is also a need to understand the key challenges to developing effective policy interventions for the innovation process that will create sound economic leverage (Harvey, 2010). A new method that helps us understand the innovation process at the organisational level has been developed, by working across disciplines and synthesising different methodologies. Constructs adopted from the Minnesota Innovation Research Programme (MIRP) were used to gather and analyse data. The methodological approach followed was a fusion of the Interactive Process Perspective (IPP) and Institutional Theory (IT). This method has been used to further explain the complexities of the innovation process by demonstrating the co-operation and contestation between actors from different interest groups in terms of agency and structure. Evidence of how innovation centres exhibit different characteristics relating to their local context along with the specific actors populating them is provided. Those actors bring their own institutional logics, belief systems and associated practices to their centres. The importance which the local context of an MNT Centre has within the extra-local context of the state intervention is shown to have a major bearing on its original purpose. For practitioners some important points have been raised: the intended purpose of the MNT government intervention was shown to evolve across MNT centres; the key influential actors of each centre demonstrably followed different institutional systems of reasoning, which in some cases resulted in internal conflicts. As demonstrated in this study, the ingrained institutional thinking and reasoning of actors can be difficult to change for the intended purpose of an intervention, once funding has already been awarded.
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BONANNO, ALBERTO. "Micro-for-Nano: A Low-Power Platform for Nanomaterial Integration and Nanosensors Interface on 0.13μm CMOS Technology". Doctoral thesis, Politecnico di Torino, 2014. http://hdl.handle.net/11583/2557562.

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During the last years, material science has been focused on the exploration of the material characteristics at nanoscale. In fact, some materials show different properties only if they are designed with a nanometer structure. Even if they can be used to build macro devices (e.g., tactile surface, strain sensors), the nanostructured materials can reach high sensitivity or accuracy. Thin films [1], nanoparticles [2] and nanowires composites [3] have been widely used thanks to their sensitivity to mechanical strengths [4] or light stimuli [5–7]. In these cases, a large number of nanostructured elements have been merged in a single device to transduce macro-phenomena (e.g., strain, bending, pressure, temperature). Although nanomaterials can be used for standard sensor applications, the aim of nanotechnology is to exploit the dimension of the basic elements (e.g., nanoparticles) to conceive innovative applications at nanoscale. In order to exploit the ultra-small dimension of these materials, researchers addressed the development of nanodevices including only a single nanostructured element to increase sensitivity and accuracy. Nanomaterials, such as nanowires (NWs), bridging molecules or nanoparticles, are considered the basis for a new generation of bio-sensors able to interact with gases [8, 9], molecules (e.g., DNA molecules) or other bio-substances at nanoscale. Some examples are the lab-on-chip designed to implement drug detection using functionalized CNT [10] and the Electronic Nose able to identify different gas molecules [11]. The fabrication process of a nanosensor (or nanodevice) mainly consists in the integration of nanomaterials (previously synthesized for achieving the desired functionality) with metal electrodes. The fabrication process is actually complex and implies high costs. Different techniques can be used to connect nanomaterial with metal electrodes and, then, to the custom electronic interface. The most used methods for integration involve a stochastic deposition upon interdigitated electrodes [12] or chemical processes to directly grow the nanomaterials in-situ [13] or an electrically controlled deposition of nanomaterials dissolved in liquid solution [14]. The fabricated nanodevice is a passive component and it needs to be connected to a measurement system, involving long cables and therefore high parasitics. Fundamentally, when a nanomaterial is exposed to specific molecules or physical phenomena, its resistance or capacitance changes proportionally to the sensed quantity. Thus, the larger the variation of the resistance or capacitance of nanomaterials, the higher the sensitivity to specific phenomena. The electronic interface for passive nanosensors should be able to stimulate the nanomaterial and convert the large variation of its electrical characteristics to analog or digital signals compliant with commercial electronics. The nanomaterial signal is usually a current in the pA-μA range and the noise coupling, due to long interconnections, can easily affect the whole nanodevice sensitivity. Hence, a new approach for the nanosensor fabrication and for the read-out is strictly required to cut fabrication costs and improve measurement accuracy. The electronic interface needs to be placed as close as possible to avoid interferences at the interconnection cables. Anyway, the read-out system has also to overcome flicker-noise effects during DC or low-frequency measurements. In addition to the issues related to the measurement accuracy, a single nanosensor is not sufficient to produce reliable results because of the process variation in nanomaterial synthesis and nanodevice fabrication. Thus, an array of nanosensors is strongly suggested because a large number of nanodevices compensates the defects in single nanosensor fabrication. The measurement system provides the final results performing an average calculation of the nanosensor outputs. Actually, if the final aim is a complex system as the Electronic Nose [15] (i.e., an integrated multi-sensors system) or a bio-sensors for blood analysis [16], an array of nanosensors is strictly required given that different molecules have to be detected and average measurements are mandatory. This PhD thesis reports about a flexible platform implemented in CMOS technology for conceiving a Micro-for-Nano (M4N) system where nanosensors and microelectronics coexist on the same chip. The nanomaterial integration process (Chapter 2, Chapter 3), the read-out circuits for nanosensor interface (Chapter 4, Chapter 5) and the architecture to handle large number of integrated nanosensors (Chapter 6) will be described in the following chapters. The M4N project has been developed in collaboration with the Italian Institute of Tecnology (IIT@PoliTO), which has supported all the experiments needed to set-up the integration process and to characterize the designed CMOS circuits.
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Furberg, Richard. "Enhanced Boiling Heat Transfer on a Dendritic and Micro-Porous Copper Structure." Doctoral thesis, KTH, Tillämpad termodynamik och kylteknik, 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-47538.

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A novel surface structure comprising dendritically ordered nano-particles of copper was developed during the duration of this thesis research project. A high current density electrodeposition process, where hydrogen bubbles functioned as a dynamic mask for the materials deposition, was used as a basic fabrication method. A post processing annealing treatment was further developed to stabilize and enhance the mechanical stability of the structure. The structure was studied quite extensively in various pool boiling experiments in refrigerants; R134a and FC-72. Different parameters were investigated, such as; thickness of the porous layer, presence of vapor escape channels, annealed or non-annealed structure. Some of the tests were filmed with a high speed camera, from which visual observation were made as well as quantitative bubble data extracted. The overall heat transfer coefficient in R134a was enhanced by about an order of magnitude compared to a plain reference surface and bubble image data suggests that both single- and two-phase heat transfer mechanisms were important to the enhancement. A quantitative and semi-empirical boiling model was presented where the main two-phase heat transfer mechanism inside the porous structure was assumed to be; micro-layer evaporation formed by an oscillating vapor-liquid meniscus front with low resistance vapor transport through escape channels. Laminar liquid motion induced by the oscillating vapor front was suggested as the primary single-phase heat transfer mechanism. The structure was applied to a standard plate heat exchanger evaporator with varying hydraulic diameter in the refrigerant channel. Again, a 10 times improved heat transfer coefficient in the refrigerant channel was recorded, resulting in an improvement of the overall heat transfer coefficient with over 100%. A superposition model was used to evaluate the results and it was found that for the enhanced boiling structure, variations of the hydraulic diameter caused a change in the nucleate boiling mechanism, which accounted for the largest effect on the heat transfer performance. For the standard heat exchanger, it was mostly the convective boiling mechanism that was affected by the change in hydraulic diameter. The structure was also applied to the evaporator surface in a two-phase thermosyphon with R134a as working fluid. The nucleate boiling mechanism was found to be enhanced with about 4 times and high speed videos of the enhanced evaporator reveal an isolated bubble flow regime, similar to that of smooth channels with larger hydraulic diameters. The number and frequency of the produced bubbles were significantly higher for the enhanced surface compared to that of the plain evaporator. This enhanced turbulence and continuous boiling on the porous structure resulted in decreased oscillations in the thermosyphon for the entire range of heat fluxes.<br>QC 20111111
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Portes, Marion. "Nouvelles approches pour l'étude de l'architecture et la dynamique de la sealing zone des ostéoclastes." Thesis, Toulouse 3, 2019. http://www.theses.fr/2019TOU30294.

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L'os forme un environnement cellulaire complexe, et est sujet à un renouvellement constant tout au long de l'existence. Son remodelage dépend de trois types cellulaires : les ostéoblastes, les ostéoclastes et les ostéocytes. Le rôle des ostéoblastes consiste en la construction de la nouvelle matrice osseuse, tandis que les ostéoclastes sont responsables de sa dégradation. Tout ceci se fait sous la régulation des ostéocytes. Afin de pouvoir efficacement dissoudre les parties minérales et organiques de l'os, les ostéoclastes mettent en place des domaines spécifiques de leur membrane plasmique. Cette polarisation leur permet de créer un microenvironnement confiné, favorable à la résorption. Elle est caractérisée par la formation d'une zone membranaire fortement convoluée (" ruffled border ") où le trafic vésiculaire est intense, qui est entourée d'une zone de scellement ou " sealing zone ". La sealing zone, en tant que structure à forte densité d'actine, a été caractérisée à la fin des années 80, et une vingtaine d'années plus tard des sous-unités ressemblant à des podosomes ont été identifiées à l'intérieur de cette entité. Les podosomes sont des structures d'adhérence, de taille caractéristique inférieure au micron, et présents dans les cellules hématopoiétiques. De plus, leur structure a été largement documentée à l'aide de nombreuses techniques de microscopie de super-résolution. A l'inverse, l'organisation interne de la sealing zone reste encore aujourd'hui peu décrite à une telle échelle. Au cours de cette étude, une première caractérisation quantitative à l'échelle nanoscopique de la sealing zone des ostéoclastes humains a été proposée. A l'aide d'une technique de microscopie de super-résolution de pointe, compatible avec l'observation de cellules sur os, des acquisitions sur échantillons fixés et vivants ont pu être réalisées. Ceci a notamment permis de mettre en évidence des évènements dynamiques au sein même des cœurs d'actine dans la sealing zone, jusque-là inconnus. Certaines protéines majeures de la sealing zone ont également pu être localisées en 2D. De plus, une étude de la ceinture de podosomes, homologue sur verre de la sealing zone, a permis d'établir les distributions 3D des mêmes protéines grâce à une technique de nanoscopie. Contrairement aux podosomes individuels, la mécanobiologie de la sealing zone est un domaine encore peu exploré. Ainsi, une autre partie de ce projet a été dédiée au développement d'un nouveau protocole de microscopie de force de traction. Cette alternative visait à permettre la caractérisation de forces en 3D, bénéficiant d'une très bonne résolution grâce à la technique d'observation choisie. Le travail s'est concentré sur l'évaluation de la faisabilité d'une telle méthode, compte tenu du cahier des charges imposé par l'usage de nanoscopie 3D.[...]<br>Bone is a complex biological environment, and a living tissue under constant renewal throughout life. Its remodeling process is orchestrated by three different cell types: osteoblasts, osteoclasts and osteocytes. While osteoblasts are in charge of the generation of new bone matrix, the main function of osteoclasts is to degrade it, and both activities are under the regulation of osteocytes. In order to efficiently dissolute both mineralized and organic bone components, osteoclasts compartmentalize their plasma membrane to create a resorption microenvironment. The ruffled border is the site of extensive vesicular trafficking, and the sealing zone confines the digestion site. The sealing zone has been identified in the late 80s as a dense actin structure, then in the late 2000s as composed of seemingly podosomal subunits. However, little is still known about the precise inner organization of this specific cytoskeletal arrangement. This study proposed the first quantitative nanoscale characterization of the sealing zone in human osteoclasts. It benefited from state-of-the-art super-resolution microscopy, compatible with observation of both fixed and live samples on bone. Hence, it also yielded the first assessment of the internal dynamics of single actin cores within the sealing zone. It provided the precise in-plane localization of major actin-binding proteins associated with the sealing zone. In addition, it evaluated the 3D distribution of the same proteins in the podosome belt, counterpart of the sealing zone on glass substrates. In contrast to podosomes, the mechanical properties of the sealing zone have been but poorly investigated. Thus, this work also aimed at developing a new traction force microscopy environment, allowing for 3D characterization of forces thanks to a 3D nanoscopy technique. The acute sensitivity of the observation method implied challenging technological requirements, the feasibility of which have been explored. Even if this project was not successfully achieved, it helped identifying key information in order to raise technological bolts in the future. In addition, micro- and nanotechnological resources have been applied to the development of new substrates to assess topography sensing at the nanoscale. Indeed, micron-sized lines presenting nanoscale heights were directly shaped on glass coverslips thanks to photolithography and chemical etching, and their characterization was carried out with atomic force microscopy. [...]
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Filippov, Stanislav. "Micro-photoluminescence and micro-Raman spectroscopy of novel semiconductor nanostructures." Doctoral thesis, Linköpings universitet, Funktionella elektroniska material, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-123939.

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Low-dimensional semiconductor structures, such as one-dimensional nanowires (NWs) and zerodimensional quantum dots (QDs), are materials with novel fundamental physical properties and a great potential for a wide range of nanoscale device applications. Here, especially promising are direct bandgap II-VI and III-V compounds and related alloys with a broad selection of compositions and band structures. For examples, NWs based on dilute nitride alloys, i.e. GaNAs and GaNP, provide both an optical active medium and well-shaped cavity and, therefore, can be used in a variety of advanced optoelectronic devices including intermediate band solar cells and efficient light-emitters. Self-assembled InAs QDs formed in the GaAs matrix are proposed as building blocks for entangled photon sources for quantum cryptography and quantum information processing as well as for spin light emitting devices. ZnO NWs can be utilized in a variety of applications including efficient UV lasers and gas sensors. In order to fully explore advantages of nanostructured materials, their electronic properties and lattice structure need to be comprehensively characterized and fully understood, which is not yet achieved in the case of aforementioned material systems. The research work presented this thesis addresses a selection of open issues via comprehensive optical characterization of individual nanostructures using micro-Raman ( -Raman) and micro-photoluminescence ( -PL) spectroscopies. In paper 1 we study polarization properties of individual GaNP and GaP/GaNP core/shell NWs using polarization resolved μ-PL spectroscopy. Near band-edge emission in these structures is found to be strongly polarized (up to 60% at 150K) in the orthogonal direction to the NW axis, in spite of their zinc blende (ZB) structure. This polarization response, which is unusual for ZB NWs, is attributed to the local strain in the vicinity of the N-related centers participating in the radiative recombination and to their preferential alignment along the growth direction, presumably caused by the presence of planar defects. Our findings therefore show that defect engineering via alloying with nitrogen provides an additional degree of freedom to control the polarization anisotropy of III-V nanowires, advantageous for their applications as a nanoscale source of polarized light. Structural and optical properties of novel coaxial GaAs/Ga(N)As NWs grown on Si substrates, were evaluated in papers 2-4. In paper 2 we show by using -Raman spectroscopy that, though nitrogen incorporation shortens a phonon correlation length, the GaNAs shell with [N]&lt;0.6% has a low degree of alloy disorder and weak residual strain. Additionally, Raman scattering by the GaAs-like and GaNlike phonons is found to be enhanced when the excitation energy approaches the E+ transition energy. This effect was attributed the involvement of intermediate states that were created by N-related clusters in proximity to the E+ subband. Recombination processes in these structures were studied in paper 3 by means of μ-PL, μ-PL excitation (μ-PLE), and time-resolved PL spectroscopies. At low temperatures, the alloy disorder is found to localize photo-excited carriers leading to predominance of localized exciton (LE) transitions in the PL spectra. Some of the local fluctuations in N composition are suggested to create three-dimensional confining potentials equivalent to that for QDs, based on the observation of sharp PL lines within the LE contour. In paper 4 we show that the formation of these QD-like confinement potentials is somewhat facilitated in spatial regions of the NWs with a high density of structural defects, based on correlative spatially-resolved structural and optical studies. It is also concluded the principal axis of these QD-like local potentials is mainly oriented along the growth direction and emit light that is linearly polarized in the direction orthogonal to the NW axis. At room temperature, the PL emission is found to be dominated by recombination of free carriers/excitons and their lifetime is governed by non-radiative recombination via surface states. The surface recombination is found to become less severe upon N incorporation due to N-induced modification of the surface states, possibly due to partial surface nitridation. All these findings suggest that the GaNAs/GaAs hetero-structures with the onedimensional geometry are promising for fabrication of novel optoelectronic devices on foreign substrates (e.g. Si). Fine-structure splitting (FSS) of excitons in semiconductor nanostructures has significant implications in photon entanglement, relevant to quantum information technology and spintronics. In paper 5 we study FSS in various laterally-arranged single quantum molecular structures (QMSs), including double QDs (DQDs), quantum rings (QRs), and QD-clusters (QCs), by means of polarization resolved μ-PL spectroscopy. It is found that FSS strongly depends on the geometric arrangements of the QMSs, which can effectively tune the degree of asymmetry in the lateral confinement potential of the excitons and can reduce FSS even in a strained QD system to a limit similar to strain-free QDs. Fabrication of nanostructured ZnO-based devices involves, as a compulsory step, deposition of thin metallic layers. In paper 6 we investigate impact of metallization by Ni on structural quality of ZnO NWs by means of Raman spectroscopy. We show that Ni coating of ZnO NWs causes passivation of surface states responsible for the enhanced intensity of the A1(LO) in the bare ZnO NWs. From the resonant Raman studies, strong enhancement of the multiline Raman signal involving A1(LO) in the ZnO/Ni NWs is revealed and is attributed to the combined effects of the Fröhlich interaction and plasmonic coupling. The latter effect is also suggested to allow detection of carbon-related species absorbed at the surface of a single ZnO/Ni NW, promising for utilizing such structures as efficient nano-sized gas sensors.
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Östlund, Ludwig. "Fabrication and Characterization of Micro and Nano Scale SiC UV Photodetectors." Thesis, KTH, Skolan för informations- och kommunikationsteknik (ICT), 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-52911.

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The focus of this master thesis work is on the fabrication of micro- and nano-scale metalsemiconductor-metal silicon carbide (SiC) UV photodetectors and subsequent electrical and optical evaluation of the fabricated devices. The UV photodetectors have significant potential to address the needs of many applications such as detection of corona discharge and flames, industrial machine viewing, and bacteria in water or paper mills. Micro-scale devices in 4H-SiC and 6H-SiC have been fabricated successfully with good photoresponse and low dark current. Reduction in size of the 4H-SiC UV detectors from micro-scale to nano-scale has been achieved by the use of nano imprint lithography (NIL). The performance of these nano-devices have been characterized, and experiment results reveal good photo sensitivity at very low applied biases.
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Dubey, Mukesh Kumar. "Development and performance evaluation of polytetrafluoroethylene based nano and micro-oils." Thesis, IIT Delhi, 2016. http://localhost:8080/xmlui/handle/12345678/7074.

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Badami, Muhammad Ali. "Design of a FEEP Thruster for Micro-/Nano-Satellites." Thesis, Luleå tekniska universitet, Institutionen för system- och rymdteknik, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:ltu:diva-75615.

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CubeSat development has seen a rise since the first launch in 2003 due to faster design process and low launch costs. It has played a vital role in providing access to space to small start-ups and academic organizations with low budgets. It has also enabled the testing of different upcoming technologies in space and has helped in providing hands-on experience to students taking part in design of such platforms. University of Pisa, in collaboration with SITAEL, has also taken an initiative to design and develop a CubeSat to test the FEEP thruster, design of which is presented in the thesis. A FEEP system was designed to fit within 1U dimensions and with a dry mass of approximately 820 grams. The system is based on slit emitter which provides an advantage over already available technologies in the market which uses needle emitters. Slit emitter scan achieve multiple Taylor cones without the need of clustering as used in needle emitters and also have a higher Thrust to Power Ratio. A propellant comparison was done considering all the properties required for an ideal propellant for a FEEP system. This comparison led to the selection of indium as working propellant which has an atomic mass of 114.8 u and a melting point of 156.6 °C. The FEEP system was designed keeping in mind easy assembling and modularity of thruster for ease in changing parts. The design consists of three different modules that are assembled separately and then joined together to complete the assembling of the system. The propellant tank, which also houses the emitter, has an internal volume of 32.75 cm3 and can hold approximately 240 grams of indium, which has a density of 7.31 g/cm3. During mission analysis, a 600km altitude orbit was proposed by analyzing the amount of propellant required for drag compensation and de-orbit maneuver at different altitudes with worst case values for ballistic coefficient and Thrust to Weight Ratio. At this altitude, the propellant requirement is 254.4 grams, 14.4 grams more than that of what can fit in the propellant tank of the designed thruster. However, both design of the system and mission analysis are ongoing processes and changes would be made in the future to either one or both to meet the requirements.
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WETTERBORG, MALIN. "Micro and nano sized textile topography for improved water repellence." Thesis, Högskolan i Borås, Institutionen Textilhögskolan, 2014. http://urn.kb.se/resolve?urn=urn:nbn:se:hb:diva-18006.

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Water repellent fabrics with superhydrophobic properties have been constructed during this diploma work. First the fabrics were woven using six different weft yarns creating micro roughness and then a nanoparticle and surface energy lowering treatment was made. Contact angle measurements, contact angle hysteresis measurements, roll-off angle measurements and spray tests were made on the fabrics to investigate the hydrophobicity and water repellence. Also the durability was tested to examine the fastness of the treatments. It was found that the nanoparticles boosted the hydrophobicity of the hydrophobic treatments. Also by varying the size of textile filaments in yarns, the hydrophobicity of the material was affected. In this study, it was found how small textile parameters in the fabric could be changed to increase both durability and water repellence.<br>Program: Textilingenjörsutbildningen
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Ketterl, Thomas P. "Micro- and nano-scale switches and tuning elements for microwave applications." [Tampa, Fla] : University of South Florida, 2006. http://purl.fcla.edu/usf/dc/et/SFE0001559.

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Books on the topic "Micro/nano-technology"

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Yan, Jiwang, ed. Micro and Nano Fabrication Technology. Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-13-0098-1.

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Yan, Jiwang, ed. Micro and Nano Fabrication Technology. Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-6588-0.

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Kita, Rio, and Toshiaki Dobashi, eds. Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7.

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Jefferis, David. Micro machines: Ultra-small world of nano technology science frontiers. Crabtree Pub. Co., 2006.

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Zhang, Xiao-Sheng. Micro/Nano Integrated Fabrication Technology and Its Applications in Microenergy Harvesting. Springer Berlin Heidelberg, 2016. http://dx.doi.org/10.1007/978-3-662-48816-4.

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Zhongguo wei mi na mi ji shu xue hui. Xue shu nian hui. Micro-nano technology XIII: Selected, peer reviewed papers from the13th Annual Conference of Chinese Society of Micro-Nano Technology, September 28-30, 2011, Changchow, China. Trans Tech Publications, 2012.

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Conference, Chinese Society of Micro/Nano Technology International. Micro and nano technology: Selected, peer reviewed papers from 1st international conference of Chinese Society of Micro/Nano Technology (CSMNT), Nov. 19-22, 2008, P.R. China. Trans Tech Publications, 2009.

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Chinese Society of Micro/Nano Technology. International Conference. Micro and nano technology: Selected, peer reviewed papers from 1st international conference of Chinese Society of Micro/Nano Technology (CSMNT), Nov. 19-22, 2008, P.R. China. Trans Tech Publications, 2009.

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Zhongguo wei mi na mi ji shu xue hui. Xue shu nian hui. Micro-nano technology XV: Selected, peer reviewed papers from the 15th Annual Conference and 4th International Conference of the Chinese Society of Micro-Nano Technology (CSMNT 2013), November 3-6, 2013, Tianjin, China. Trans Tech Publications Ltd., 2014.

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China) China International Nanoscience And Technology Symposium (12th 2013 Chengdu. Frontiers in micro-nano science and technology: Selected, peer reviewed papers from the 12th China International Nanoscience and Technology Symposium, Chengdu (2013) and the Nano-Products Exposition, sponsored by Chinese Society of Micro-Nano Technology, and IEEE Nanotechnology Council, (CINSTS 2013), October 27-31, 2013, Chengdu, China. Trans Tech Publ., 2014.

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Book chapters on the topic "Micro/nano-technology"

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Yang, Shuming, and Biyao Cheng. "Micro-nano-fabrication Technology." In Precision Manufacturing. Springer Nature Singapore, 2025. https://doi.org/10.1007/978-981-16-4003-2_19-1.

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Yang, Shuming, and Biyao Cheng. "Micro-nano-fabrication Technology." In Precision Manufacturing. Springer Nature Singapore, 2025. https://doi.org/10.1007/978-981-96-1035-8_19.

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Miura, Yoshiko, and Keitaro Yoshimoto. "Nano- and Micro-technology of Soft Interface." In Molecular Soft-Interface Science. Springer Japan, 2019. http://dx.doi.org/10.1007/978-4-431-56877-3_3.

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Wu, Jie, Xi Zhao, Yue-Qi Wang, and Guang-Hui Ma. "Biomedical Application of Soft Nano-/Microparticles." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_11.

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Kita, Rio, and Toshiaki Dobashi. "Introduction of Nano/Micro Science and Technology in Biorheology." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_1.

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Tomita, Naoko, and Toshiaki Dobashi. "Biorheological Aspect of Microcapsules." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_10.

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Furusawa, Kazuya. "Control of the Multi-scale Structure of Scaffolds and Its Application in Tissue Engineering." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_12.

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Sakata, Toshiya. "Sensing of Biomolecules and Cells by Semiconductor Device." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_13.

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Yamasaki, Yuichi. "From Single-Molecule DNA Imaging to Development of a Gene Delivery System." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_14.

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Okajima, Takaharu. "Atomic Force Microscopy: Imaging and Rheology of Living Cells." In Nano/Micro Science and Technology in Biorheology. Springer Japan, 2015. http://dx.doi.org/10.1007/978-4-431-54886-7_15.

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Conference papers on the topic "Micro/nano-technology"

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Xia, Zhongyi, Dimitars Jevtics, Benoit Guilhabert, et al. "Towards scalable on-chip excitation of micro- and nano-photonic emitters." In CLEO: Applications and Technology. Optica Publishing Group, 2024. http://dx.doi.org/10.1364/cleo_at.2024.atu4j.5.

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Individually addressable micro-LED-on-CMOS arrays are promising candidates for scalable on-chip excitation of micro- and nano-photonic emitters. Using this technology platform, frequency modulated excitation of waveguide-embedded nanowire devices was demonstrated at MHz rates.
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Zhang, W., C. Peng, F. Jiang, Z. Yu, and X. Jiang. "Research on terahertz near-field technology in micro-nano biological imaging." In 2024 IEEE International Conference on Plasma Science (ICOPS). IEEE, 2024. http://dx.doi.org/10.1109/icops58192.2024.10627665.

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Ma, Xiaoyu, Wei Chen, Hui Geng, et al. "The influence of preparation technology on coupling characteristics of micro-nano optical fiber devices." In Fourth International Conference on Computational Imaging (CITA 2024), edited by Xiaopeng Shao. SPIE, 2025. https://doi.org/10.1117/12.3058176.

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Guo, Xiaowei, Haotian Guo, Xinke Xu, et al. "Research progress on ultra-precision measurement technology based on line chromatic confocal sensors at micro-nano scale." In Optical Design and Testing XIV, edited by Rengmao Wu, Yongtian Wang, and Tina E. Kidger. SPIE, 2024. http://dx.doi.org/10.1117/12.3030830.

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Minev, Roussi, Nina Bencheva, and Yoana Ruseva. "Micro/nano technology challenges and training opportunities." In 2014 25th EAEEIE Annual Conference (EAEEIE). IEEE, 2014. http://dx.doi.org/10.1109/eaeeie.2014.6879384.

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"Session MNT: Micro and nano technology 1." In 2010 International Semiconductor Conference (CAS 2010). IEEE, 2010. http://dx.doi.org/10.1109/smicnd.2010.5650465.

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Wang, Hongwei. "Micro residual oil description based on high-precision micro nano CT technology." In 2022 International Conference on Wireless Communications, Electrical Engineering and Automation (WCEEA). IEEE, 2022. http://dx.doi.org/10.1109/wceea56458.2022.00064.

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Uherek, Frantisek, Daniel Donoval, and Jozef Chovan. "Extension of micro/nano-electronics technology towards photonics education." In 2009 IEEE International Conference on Microelectronic Systems Education (MSE '09). IEEE, 2009. http://dx.doi.org/10.1109/mse.2009.5270818.

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Olsson, Roy H., Maryam Ziaei-Moayyed, Bongsang Kim, et al. "Micro and nano fabricated phononic crystals: technology and applications." In 2011 IEEE International Ultrasonics Symposium (IUS). IEEE, 2011. http://dx.doi.org/10.1109/ultsym.2011.0241.

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Chen, Ziling, Jianping Zeng, Guangyi Xiao, Xiaoli Xie, and Jingyue Fang. "License plate photo recognition technology based on micro-nano filter." In Conference on Optical Sensing and Imaging Technology, edited by Dong Liu, Xiangang Luo, Yadong Jiang, and Jin Lu. SPIE, 2020. http://dx.doi.org/10.1117/12.2580091.

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Reports on the topic "Micro/nano-technology"

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Scarrott, Rory, Cathal O'Mahony, Michael Sweeney, et al. KETmaritime: Setting course to energise maritime uptake of Key Enabling Technologies. University College Cork, 2020. http://dx.doi.org/10.33178/10468.10928.

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Key Enabled Technologies(KETs) have the potential to impact on many aspects of society, whilst transforming European industrial competitiveness at the local, national, and global scales. Studies funded by the European Commission have shown that European advances in six technology areas would not only enhance the leadership and competitiveness of European business, but also drive advances across Europe’s business sectors and society. Despite their applicability across sectors, KETs represent a change, and a new manner of moving forward. Business and society view change both positively, welcoming advances in technology and new tools and products to make life somewhat easier for citizens, and negatively, recognising that with change comes risk and a reticence to change. Like society, different industrial sectors will view innovation and new technology differently. As such, each sector requires a slightly different approach to energise KET uptake into their daily operations and lives. Recognition of this reality underpinned the development of this roadmap. Stakeholders have been engaged across the Atlantic Area, through the use of online surveying, face-to-face workshops, and one-to-one interviews conducted virtually. This has enabled the authors to develop an awareness of the maritime scene and community which offers such opportunities and potential for KETs. It also provided insights into the reality of energising this uptake when framed in the context of social, financial and governance realities. Over the course of the project, the team conducted an analysis of the maritime sector, to identify and map out any KET applications that were in development. In parallel, a diverse pool of academic and commercial stakeholders identified the opportunities they could see for KET applications in the maritime sector. They also identified factors which restrict uptake, and restrain viable trans- disciplinary innovations from effectively making it to market. Stakeholder perspectives were combined with the investigative findings to develop a vision for a KET-maritime innovation ecosystem. The barriers and challenges shaped a range of proposed actions, which target different facets of the innovation ecosystem to ease growth and shape development. These actors were iteratively reviewed by stakeholders, and amended accordingly. These actions form the basis of this roadmap, a proposed path towards realising a vibrant growing KET-maritime innovation ecosystem. It contains a suite of 60 inter-linked, systemic actions, framed within 35 action areas to achieve 9 core goals, spread across 5 thematic agendas (policy, funding, building a sustainable innovation ecosystem, capacity building, and awareness raising). This envisioned KET-maritime innovation ecosystem fosters application-led innovation, and advances societal and market benefits for all. Each of the 5 thematic agendas are summarised as a policy brief, provided in the Appendices. The actions applicable to each policy brief are detailed in this report, alongside a proposed timeframe for implementation. Each action is codified, and can be traced through the iterative review process using the provenance table supplied. The potential for KET applications across the Blue Economy is extensive, and all sectors offer at least some opportunities for KETs. Within this landscape, the following sectors are identified as having strong growth potential where KET’s can help to drive that growth: Fisheries and aquaculture; Blue biotechnology; Maritime surveillance; Marine renewable energy; Ship and boat building. Within these sectors, four specific KET-maritime applications research priorities are highlighted: Advanced materials application in marine renewable energy; Photonics application in maritime surveillance; Micro- and nano-electronics in maritime surveillance; Advanced manufacturing techniques in ship and boat building. Finally, the project team would like to take this opportunity to thank all stakeholders who participated in the workshops, interviews, and review activities which culminated in this roadmap.
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