This curriculum vitae summarizes Pierfrancesco Zilio's professional experience and education. He has worked as a post-doctoral fellow and junior researcher conducting theoretical and numerical modeling of nanostructures. His research has focused on topics like plasmonics, nano-optics, and their applications. He holds a PhD in physics from Padova University, where he researched surface plasmon polariton propagation for nano-optics applications.
During the last decades a large effort has been invested in the development of a new
discipline devoted to benefit from optical excitations in materials where metals are
key element (Plasmonics). We will make an introduction on this topic below, but let’s
anticipate that two application areas are sensing and information technologies.
The following height extended abstracts, presented during the one-day NANOMAGMA
Symposium (Bilbao, Spain – April 13, 2011 reflects some of the latest developments on magneto-plasmonics.
In 2010 and 2011, the nanoICT project (EU/ICT/FET Coordination Action) launched
two calls for exchange visits for PhD students with the following main objectives: 1.
To perform joint work or to be trained in the leading European industrial and academic research institutions; 2. To enhance long-term collaborations within the ERA; 3. To
generate high-skilled personnel and to facilitate technology transfer;
The first outcome report was published in the issue 22 (August 2011) and this edition
contains four new articles providing insights in relevant fi elds for nanoICT.
We would like to thank all the authors who contributed to this issue as well as the European Commission for the financial support (projects nanoICT No. 216165 and NANOMAGMA No. FP7-214107-2).
Dr. Antonio Correia Editor - Phantoms Foundation
The Extended Nijboer-Zernike diffraction theory provides an analytic solution to the diffraction integral that describes image formation by optical systems. This thesis presents the ENZ theory as well as two of its applications. First, an ENZ imaging model is constructed that accurately simulates image formation with few approximations. Second, it is shown that the aberrations of an optical system can be determined from intensity measurements of a point object image alone, providing an alternative to interferometric methods. Examples illustrate the potential of the ENZ formalism for simulating and analyzing advanced optical imaging systems with high accuracy.
This curriculum vitae summarizes the qualifications and experience of Giovanni Crupi. Crupi received his Ph.D. in 2006 from the University of Messina in Italy, with a thesis on the characterization and modeling of advanced microwave transistors. He has since held various research positions, including positions at the University of Leuven in Belgium and the University of Ferrara in Italy. Crupi has published over 40 papers in international journals and conferences, and his work focuses on analytical modeling and characterization of advanced microwave devices. He currently works as a contract researcher at the University of Messina.
The document provides a vision for the future of ubiquitous sensor networks and introduces Quantum-Pi, a company developing quantum tunneling sensor technologies. Quantum-Pi was founded in 1999 and has developed nano-electro-mechanical sensors for applications such as oil/gas, security, medicine, aviation and more. The document discusses Quantum-Pi's devices, collaborations, facilities, and the market potential for its quantum tunneling linear encoder and dynamic sensor products. It presents the technological principles behind quantum tunneling sensors and examples of prototypes fabricated at research institutions.
Thomas Michael Wood has extensive experience in optics research, having held several postdoctoral research positions between 2013 and present focused on topics like graphene photonics, photonic components for communications, and organic light emitters. He received his PhD in Physics from Aix-Marseille University in 2013 with a focus on guided optics techniques for gas sensing applications.
For many decades, nanotechnology has been developed with cooperation from researchers in several fields of studies including physics, chemistry, biology, material science, engineering, and computer science. Nanotechnology is engineering at the molecular (groups of atoms) level. It is the collective term for a range of technologies, techniques and processes that involve the manipulation of matter at the smallest scale (from 1 to 100 nm2).The nanotechnology provides better future for human life in various fields. In future nanotechnology provides economy, ecofriendly and efficient technology which removes all difficult predicaments which is faced by us in today life scenario. Nanotechnology is the technology of preference to make things small, light and cheap, nanotechnology based manufacturing is a method conceived for processing and rearranging of atoms to fabricate custom products.
The nanotechnology applications have three different categories nanosystems, nanomaterials and nanoelectronics. The impact of the nanotechnology occurred on computing and data storage, materials and manufacturing, health and medicine, energy and environment, transportation, national security and space exploration. There are many applications of nanotechnology which are exciting in our life such as nanopowder, nanotubes, membrane filter, quantum computers etc.
But there are several problems which are occurred with the exploration of the nanotechnology such as the wastes released while making the materials for nanotechnology are released into the atmosphere and can even penetrate human and animal cells and effect their performance, agricultural countries will lose their income as nanotechnology will take over, if any damage is done at the molecular level then it is not possible to revert it.
Evolution of nanotechnology in electronics (seminar report) -codewithgauriGaurav Pandey
Nanotechnology is engineering and manufacturing at the molecular scale, thereby taking more advantage of the unique properties that exist at that scale.
A Nanometre is a unit of length in the metric system, equal to one billionth of a metre(10-9).Can be used across all the other science fields, such as chemistry, biology, physics, materials science, and engineering.
www.blog.codewithgauri.tech
During the last decades a large effort has been invested in the development of a new
discipline devoted to benefit from optical excitations in materials where metals are
key element (Plasmonics). We will make an introduction on this topic below, but let’s
anticipate that two application areas are sensing and information technologies.
The following height extended abstracts, presented during the one-day NANOMAGMA
Symposium (Bilbao, Spain – April 13, 2011 reflects some of the latest developments on magneto-plasmonics.
In 2010 and 2011, the nanoICT project (EU/ICT/FET Coordination Action) launched
two calls for exchange visits for PhD students with the following main objectives: 1.
To perform joint work or to be trained in the leading European industrial and academic research institutions; 2. To enhance long-term collaborations within the ERA; 3. To
generate high-skilled personnel and to facilitate technology transfer;
The first outcome report was published in the issue 22 (August 2011) and this edition
contains four new articles providing insights in relevant fi elds for nanoICT.
We would like to thank all the authors who contributed to this issue as well as the European Commission for the financial support (projects nanoICT No. 216165 and NANOMAGMA No. FP7-214107-2).
Dr. Antonio Correia Editor - Phantoms Foundation
The Extended Nijboer-Zernike diffraction theory provides an analytic solution to the diffraction integral that describes image formation by optical systems. This thesis presents the ENZ theory as well as two of its applications. First, an ENZ imaging model is constructed that accurately simulates image formation with few approximations. Second, it is shown that the aberrations of an optical system can be determined from intensity measurements of a point object image alone, providing an alternative to interferometric methods. Examples illustrate the potential of the ENZ formalism for simulating and analyzing advanced optical imaging systems with high accuracy.
This curriculum vitae summarizes the qualifications and experience of Giovanni Crupi. Crupi received his Ph.D. in 2006 from the University of Messina in Italy, with a thesis on the characterization and modeling of advanced microwave transistors. He has since held various research positions, including positions at the University of Leuven in Belgium and the University of Ferrara in Italy. Crupi has published over 40 papers in international journals and conferences, and his work focuses on analytical modeling and characterization of advanced microwave devices. He currently works as a contract researcher at the University of Messina.
The document provides a vision for the future of ubiquitous sensor networks and introduces Quantum-Pi, a company developing quantum tunneling sensor technologies. Quantum-Pi was founded in 1999 and has developed nano-electro-mechanical sensors for applications such as oil/gas, security, medicine, aviation and more. The document discusses Quantum-Pi's devices, collaborations, facilities, and the market potential for its quantum tunneling linear encoder and dynamic sensor products. It presents the technological principles behind quantum tunneling sensors and examples of prototypes fabricated at research institutions.
Thomas Michael Wood has extensive experience in optics research, having held several postdoctoral research positions between 2013 and present focused on topics like graphene photonics, photonic components for communications, and organic light emitters. He received his PhD in Physics from Aix-Marseille University in 2013 with a focus on guided optics techniques for gas sensing applications.
For many decades, nanotechnology has been developed with cooperation from researchers in several fields of studies including physics, chemistry, biology, material science, engineering, and computer science. Nanotechnology is engineering at the molecular (groups of atoms) level. It is the collective term for a range of technologies, techniques and processes that involve the manipulation of matter at the smallest scale (from 1 to 100 nm2).The nanotechnology provides better future for human life in various fields. In future nanotechnology provides economy, ecofriendly and efficient technology which removes all difficult predicaments which is faced by us in today life scenario. Nanotechnology is the technology of preference to make things small, light and cheap, nanotechnology based manufacturing is a method conceived for processing and rearranging of atoms to fabricate custom products.
The nanotechnology applications have three different categories nanosystems, nanomaterials and nanoelectronics. The impact of the nanotechnology occurred on computing and data storage, materials and manufacturing, health and medicine, energy and environment, transportation, national security and space exploration. There are many applications of nanotechnology which are exciting in our life such as nanopowder, nanotubes, membrane filter, quantum computers etc.
But there are several problems which are occurred with the exploration of the nanotechnology such as the wastes released while making the materials for nanotechnology are released into the atmosphere and can even penetrate human and animal cells and effect their performance, agricultural countries will lose their income as nanotechnology will take over, if any damage is done at the molecular level then it is not possible to revert it.
Evolution of nanotechnology in electronics (seminar report) -codewithgauriGaurav Pandey
Nanotechnology is engineering and manufacturing at the molecular scale, thereby taking more advantage of the unique properties that exist at that scale.
A Nanometre is a unit of length in the metric system, equal to one billionth of a metre(10-9).Can be used across all the other science fields, such as chemistry, biology, physics, materials science, and engineering.
www.blog.codewithgauri.tech
This document provides a seminar report on nanotechnology submitted by Sanchit Sharma for their B.Tech degree. The report acknowledges those who provided guidance, including their lecturer Mrs. Shabnam Khan. It then provides an abstract that discusses nanotechnology engineering at the molecular level between 1-100 nm, and how it provides applications across fields like computing, materials, health, energy and more. However, it also notes challenges like waste and potential health effects. The full report then discusses the history, concepts, tools, future applications and exciting current uses of nanotechnology.
The document discusses nanoelectronics and its contributions to electronics. It describes how nanoelectronics allows improving electronic components through approaches like reducing transistor sizes, increasing memory density, and improving display screens. Specific nanotechnologies discussed include nanofabrication, molecular electronics, and nanowires. The document also provides examples of emerging nanoelectronic devices like single electron transistors and nanoelectromechanical systems. Overall, the document outlines how nanotechnology at the atomic scale can revolutionize electronics.
Flavio Mor is a physicist and engineer from Switzerland with expertise in Brownian motion, photonic force microscopy, second-harmonic generation, and upconversion photoluminescence. He has a PhD in physics from EPFL and has worked as a post-doctoral researcher and assistant at EPFL. His research focuses on developing luminescent probes for near-field investigations and probing hydrodynamic effects using Brownian motion. He has published several papers in the field and presented his work at various conferences.
This document is a technical seminar report submitted by Arun.R.Nair in partial fulfillment of the requirements for a Master of Technology degree in Computer Science and Technology from GITAM University in Hyderabad, India during the 2013-2014 academic year. The report covers nanotechnology and includes chapters on the history, concepts, approaches, tools, applications of nanotechnology in various fields like biotechnology, medicine, electronics, and implications of nanotechnology. It also includes acknowledgments, an abstract, table of contents, references and has been certified by seminar instructors from the university's department of computer science.
Nanotechnology involves controlling and modifying matter at the atomic and molecular scale, between 1 to 100 nanometers. It is already being used to make products lighter, stronger, faster, smaller, and more durable. Nanotechnology has applications in many fields including information technology, biotechnology, materials engineering, medicine, energy, and defense. It is used in products like wound dressings, water filters, paints, cosmetics, and computer memory as well as medical diagnostics, displays, sensors, and solid state lighting.
Introduction to Nanotechnology K.A. Dimuthu DharshanaDimuthu Darshana
This document discusses nanotechnology and its applications. It begins with an introduction to nanotechnology, defining it as the control of matter at an atomic and molecular scale. It then discusses several current and future applications of nanotechnology in medicine, electronics, computing, manufacturing, space exploration, and more. Some key points include how nanotechnology can help deliver drugs precisely to diseased cells, potentially cure cancer without surgery or chemotherapy, enable ubiquitous computing, and make satellites and spacesuits lighter and stronger. The document concludes with references to online sources for further information.
Photonics communication [communication application of nano technology]jayarajchinna
Photonics communication uses nano-sized particles and photonic crystals to route information using light instead of electrical signals. This allows information to be transmitted nearly instantaneously. The document discusses how nano-lasers and photonic band gaps can be used to control and direct photons for optical switching. Nanotechnology enables building devices that manipulate individual photons to route data at speeds approaching the speed of light through fiber optic networks.
This document discusses the history and impact of nanotechnology. It begins by discussing Richard Feynman's 1959 lecture where he proposed building things at the atomic scale from the bottom up. Nanotechnology allows manipulating individual atoms and molecules to create novel materials and devices much smaller than previously possible. Examples of nanotechnology applications include more powerful computers, new medical technologies like targeted drug delivery, and more efficient energy and environmental technologies like solar cells. The document also discusses tools used in nanotechnology like electron microscopes and examples of nanomaterials like carbon nanotubes.
Dr. Ara V. Nefian is seeking a challenging research position in areas including computer vision, 3D reconstruction, robotics, and signal processing. She has over 10 years of research experience and 40 peer-reviewed publications. Her education includes a PhD in Electrical Engineering from Georgia Tech, focusing on face detection and recognition using HMMs. Her professional experience includes senior research roles at Carnegie Mellon, Nokia, Ooyala, and Intel, where she led teams and projects in areas like 3D terrain reconstruction, Mars surface reconstruction, pipeline threat detection, and web image clustering. She has 20 patents filed and 10 issued in areas like face recognition, audio-visual processing, and machine learning.
Advanced Materials International Forum, Bari 18-19 settembre, conferenza internazionale dedicata ai materiali avanzati e alle loro possibili applicazioni nei settori industriali, con un focus particolare sui trasporti (aerospazio, automotive, navale e cantieristico).
This document lists the author's awards, scholarships, publications, patents and conference presentations. It shows that the author has received several best presentation awards between 2009-2012 from various conferences for work related to near-field scanning optical microscopy and nano-materials characterization. The author has also received scholarships from Inha University from 2008-2010. The document lists 14 peer-reviewed journal publications and 14 patents by the author. It also lists 24 international conference proceedings with presentations by the author on topics related to nano-optics and nanotechnology.
This document lists the speaker's awards, scholarships, publications, patents, and conference presentations. It shows that the speaker has received several best presentation awards between 2009-2012 from conferences in Korea and internationally. They have also received scholarships from Inha University from 2008-2010. The speaker has 14 pending patents and over 20 peer-reviewed journal publications. They have presented their work at numerous international conferences between 2011-2012.
Nanotechnology involves engineering functional systems at the molecular scale using techniques and tools to construct items from the bottom up. It uses nanofabrication to manipulate and integrate atoms and is of interest to computer engineers as it enables super-high density microprocessors and memory chips. There are two approaches - top-down uses larger tools like lithography to create smaller devices, while bottom-up relies on molecular recognition and self-assembly of smaller building blocks. Current applications include using carbon nanotubes as transistors for faster and more efficient computers, as well as research into quantum computing using qubits to store and transmit data exponentially faster than silicon.
UPES Nanotechnology Seminar Report 2013UPES Dehradun
This document summarizes a two-day international seminar on nanotechnology in conventional and alternative energy held in August 2013 at the University of Petroleum & Energy Studies (UPES) campus in Dehradun, India. Over 200 participants from academia, industry, and research organizations attended. The seminar included sessions on nanotechnology applications in energy, the global development of nanotechnology, partnerships between academia, business and government, and innovation and entrepreneurship in nanotechnology. Presentations were given by researchers from India, the US, South Korea and other countries. Several poster awards were also given out. The seminar aimed to further collaboration on nanotechnology for energy and make the event an annual occurrence.
Nanotechnologies promise new solutions for several applications in biomedical, industrial
and military fields. At nano-scale, a nano-machine can be considered as the most basic functional
unit. Nano-machines are tiny components consisting of an arranged set of molecules,
which are able to perform very simple tasks. Nanonetworks.
Nanotechnology involves manipulating materials at the atomic and molecular scale. It allows materials to be constructed with great precision at the nanoscale level. While nanotechnology offers many potential benefits, there are also risks to consider regarding its impact on human health and the environment. Due to their small size, nanoparticles may enter the human body and accumulate in organs, with unknown health effects. They also pose challenges for detection and removal from the environment. Overall, nanotechnology is an emerging field that will likely play a large role in many industries and daily life in the future.
Nanotechnology refers to the manipulation of matter at the atomic and molecular scale. It promises faster, smaller, and more energy efficient computers through the use of carbon nanotubes to replace silicon transistors. This could lead to computers that are twice as fast but half the size within the next decade. Other applications of nanotechnology in computing include using quantum dots for quantum computing, DNA logic gates for DNA computing, and non-volatile RAM to allow for more portable devices without backup batteries. Overall, nanotechnology has the potential to revolutionize computing through the development of new nanomaterials and fabrication techniques at the atomic scale.
The document discusses using photonics for high speed computing and deep space travel. It describes how photonics can replace electrons for faster computing by taking advantage of light speed. Photonic transistors could process information much faster than electronic ones. Photonics also have applications for deep space communication, navigation, sensing and protective coatings that could enable future human exploration of Mars. In summary, photonics offers advantages over electronics for both extremely fast computing and enabling future space missions.
The document summarizes an inaugural meeting for AWARENESS partners held on December 14-15, 2010 in Amsterdam. It includes the following:
- Introductions of the various projects involved in AWARENESS including ASCENS, EPiCS, RECOGNITION, SAPERE, and SYMBRION.
- An overview of the objectives and activities of the AWARE coordination action, which aims to encourage cooperation between projects, improve visibility, support training, and expand knowledge in the area of self-awareness in autonomous systems.
- Details of the agenda for the two day meeting and descriptions of the main activities to be undertaken by AWARE, such as workshops, research exchanges, newsletters
The document provides a summary of commodity prices and trading information. It includes the following key points:
- Gold prices were steady in Asia as investors look to Chinese New Year demand. Other metals like silver and copper saw small declines.
- Crude oil prices rebounded ahead of data on US stockpiles that will influence the market.
- Natural gas prices fell over 2% on Tuesday.
- The document provides support and resistance levels for various commodities as well as margin requirements for commodity futures on the MCX exchange in India.
Dispositivos de entrada y salida de informaciónmscnw
Los dispositivos de entrada y salida permiten la comunicación entre un sistema informático como una computadora y el mundo exterior o entre sistemas. Estos dispositivos incluyen teclados, mouse, pantallas y otros que permiten introducir y mostrar información.
This document provides a seminar report on nanotechnology submitted by Sanchit Sharma for their B.Tech degree. The report acknowledges those who provided guidance, including their lecturer Mrs. Shabnam Khan. It then provides an abstract that discusses nanotechnology engineering at the molecular level between 1-100 nm, and how it provides applications across fields like computing, materials, health, energy and more. However, it also notes challenges like waste and potential health effects. The full report then discusses the history, concepts, tools, future applications and exciting current uses of nanotechnology.
The document discusses nanoelectronics and its contributions to electronics. It describes how nanoelectronics allows improving electronic components through approaches like reducing transistor sizes, increasing memory density, and improving display screens. Specific nanotechnologies discussed include nanofabrication, molecular electronics, and nanowires. The document also provides examples of emerging nanoelectronic devices like single electron transistors and nanoelectromechanical systems. Overall, the document outlines how nanotechnology at the atomic scale can revolutionize electronics.
Flavio Mor is a physicist and engineer from Switzerland with expertise in Brownian motion, photonic force microscopy, second-harmonic generation, and upconversion photoluminescence. He has a PhD in physics from EPFL and has worked as a post-doctoral researcher and assistant at EPFL. His research focuses on developing luminescent probes for near-field investigations and probing hydrodynamic effects using Brownian motion. He has published several papers in the field and presented his work at various conferences.
This document is a technical seminar report submitted by Arun.R.Nair in partial fulfillment of the requirements for a Master of Technology degree in Computer Science and Technology from GITAM University in Hyderabad, India during the 2013-2014 academic year. The report covers nanotechnology and includes chapters on the history, concepts, approaches, tools, applications of nanotechnology in various fields like biotechnology, medicine, electronics, and implications of nanotechnology. It also includes acknowledgments, an abstract, table of contents, references and has been certified by seminar instructors from the university's department of computer science.
Nanotechnology involves controlling and modifying matter at the atomic and molecular scale, between 1 to 100 nanometers. It is already being used to make products lighter, stronger, faster, smaller, and more durable. Nanotechnology has applications in many fields including information technology, biotechnology, materials engineering, medicine, energy, and defense. It is used in products like wound dressings, water filters, paints, cosmetics, and computer memory as well as medical diagnostics, displays, sensors, and solid state lighting.
Introduction to Nanotechnology K.A. Dimuthu DharshanaDimuthu Darshana
This document discusses nanotechnology and its applications. It begins with an introduction to nanotechnology, defining it as the control of matter at an atomic and molecular scale. It then discusses several current and future applications of nanotechnology in medicine, electronics, computing, manufacturing, space exploration, and more. Some key points include how nanotechnology can help deliver drugs precisely to diseased cells, potentially cure cancer without surgery or chemotherapy, enable ubiquitous computing, and make satellites and spacesuits lighter and stronger. The document concludes with references to online sources for further information.
Photonics communication [communication application of nano technology]jayarajchinna
Photonics communication uses nano-sized particles and photonic crystals to route information using light instead of electrical signals. This allows information to be transmitted nearly instantaneously. The document discusses how nano-lasers and photonic band gaps can be used to control and direct photons for optical switching. Nanotechnology enables building devices that manipulate individual photons to route data at speeds approaching the speed of light through fiber optic networks.
This document discusses the history and impact of nanotechnology. It begins by discussing Richard Feynman's 1959 lecture where he proposed building things at the atomic scale from the bottom up. Nanotechnology allows manipulating individual atoms and molecules to create novel materials and devices much smaller than previously possible. Examples of nanotechnology applications include more powerful computers, new medical technologies like targeted drug delivery, and more efficient energy and environmental technologies like solar cells. The document also discusses tools used in nanotechnology like electron microscopes and examples of nanomaterials like carbon nanotubes.
Dr. Ara V. Nefian is seeking a challenging research position in areas including computer vision, 3D reconstruction, robotics, and signal processing. She has over 10 years of research experience and 40 peer-reviewed publications. Her education includes a PhD in Electrical Engineering from Georgia Tech, focusing on face detection and recognition using HMMs. Her professional experience includes senior research roles at Carnegie Mellon, Nokia, Ooyala, and Intel, where she led teams and projects in areas like 3D terrain reconstruction, Mars surface reconstruction, pipeline threat detection, and web image clustering. She has 20 patents filed and 10 issued in areas like face recognition, audio-visual processing, and machine learning.
Advanced Materials International Forum, Bari 18-19 settembre, conferenza internazionale dedicata ai materiali avanzati e alle loro possibili applicazioni nei settori industriali, con un focus particolare sui trasporti (aerospazio, automotive, navale e cantieristico).
This document lists the author's awards, scholarships, publications, patents and conference presentations. It shows that the author has received several best presentation awards between 2009-2012 from various conferences for work related to near-field scanning optical microscopy and nano-materials characterization. The author has also received scholarships from Inha University from 2008-2010. The document lists 14 peer-reviewed journal publications and 14 patents by the author. It also lists 24 international conference proceedings with presentations by the author on topics related to nano-optics and nanotechnology.
This document lists the speaker's awards, scholarships, publications, patents, and conference presentations. It shows that the speaker has received several best presentation awards between 2009-2012 from conferences in Korea and internationally. They have also received scholarships from Inha University from 2008-2010. The speaker has 14 pending patents and over 20 peer-reviewed journal publications. They have presented their work at numerous international conferences between 2011-2012.
Nanotechnology involves engineering functional systems at the molecular scale using techniques and tools to construct items from the bottom up. It uses nanofabrication to manipulate and integrate atoms and is of interest to computer engineers as it enables super-high density microprocessors and memory chips. There are two approaches - top-down uses larger tools like lithography to create smaller devices, while bottom-up relies on molecular recognition and self-assembly of smaller building blocks. Current applications include using carbon nanotubes as transistors for faster and more efficient computers, as well as research into quantum computing using qubits to store and transmit data exponentially faster than silicon.
UPES Nanotechnology Seminar Report 2013UPES Dehradun
This document summarizes a two-day international seminar on nanotechnology in conventional and alternative energy held in August 2013 at the University of Petroleum & Energy Studies (UPES) campus in Dehradun, India. Over 200 participants from academia, industry, and research organizations attended. The seminar included sessions on nanotechnology applications in energy, the global development of nanotechnology, partnerships between academia, business and government, and innovation and entrepreneurship in nanotechnology. Presentations were given by researchers from India, the US, South Korea and other countries. Several poster awards were also given out. The seminar aimed to further collaboration on nanotechnology for energy and make the event an annual occurrence.
Nanotechnologies promise new solutions for several applications in biomedical, industrial
and military fields. At nano-scale, a nano-machine can be considered as the most basic functional
unit. Nano-machines are tiny components consisting of an arranged set of molecules,
which are able to perform very simple tasks. Nanonetworks.
Nanotechnology involves manipulating materials at the atomic and molecular scale. It allows materials to be constructed with great precision at the nanoscale level. While nanotechnology offers many potential benefits, there are also risks to consider regarding its impact on human health and the environment. Due to their small size, nanoparticles may enter the human body and accumulate in organs, with unknown health effects. They also pose challenges for detection and removal from the environment. Overall, nanotechnology is an emerging field that will likely play a large role in many industries and daily life in the future.
Nanotechnology refers to the manipulation of matter at the atomic and molecular scale. It promises faster, smaller, and more energy efficient computers through the use of carbon nanotubes to replace silicon transistors. This could lead to computers that are twice as fast but half the size within the next decade. Other applications of nanotechnology in computing include using quantum dots for quantum computing, DNA logic gates for DNA computing, and non-volatile RAM to allow for more portable devices without backup batteries. Overall, nanotechnology has the potential to revolutionize computing through the development of new nanomaterials and fabrication techniques at the atomic scale.
The document discusses using photonics for high speed computing and deep space travel. It describes how photonics can replace electrons for faster computing by taking advantage of light speed. Photonic transistors could process information much faster than electronic ones. Photonics also have applications for deep space communication, navigation, sensing and protective coatings that could enable future human exploration of Mars. In summary, photonics offers advantages over electronics for both extremely fast computing and enabling future space missions.
The document summarizes an inaugural meeting for AWARENESS partners held on December 14-15, 2010 in Amsterdam. It includes the following:
- Introductions of the various projects involved in AWARENESS including ASCENS, EPiCS, RECOGNITION, SAPERE, and SYMBRION.
- An overview of the objectives and activities of the AWARE coordination action, which aims to encourage cooperation between projects, improve visibility, support training, and expand knowledge in the area of self-awareness in autonomous systems.
- Details of the agenda for the two day meeting and descriptions of the main activities to be undertaken by AWARE, such as workshops, research exchanges, newsletters
The document provides a summary of commodity prices and trading information. It includes the following key points:
- Gold prices were steady in Asia as investors look to Chinese New Year demand. Other metals like silver and copper saw small declines.
- Crude oil prices rebounded ahead of data on US stockpiles that will influence the market.
- Natural gas prices fell over 2% on Tuesday.
- The document provides support and resistance levels for various commodities as well as margin requirements for commodity futures on the MCX exchange in India.
Dispositivos de entrada y salida de informaciónmscnw
Los dispositivos de entrada y salida permiten la comunicación entre un sistema informático como una computadora y el mundo exterior o entre sistemas. Estos dispositivos incluyen teclados, mouse, pantallas y otros que permiten introducir y mostrar información.
Este documento presenta cinco importantes monumentos arquitectónicos de Barcelona, incluyendo Casa Milà o La Pedrera diseñada por Antoni Gaudí y otros cuatro monumentos como el Monumento a Colón, la Sagrada Familia, Casa Batlló y el Palacio Nacional de Montjuic, todos con Gregorio Calvo Pérez como coautor.
This 25 Telegram Mews condo offers a stunning modern design with stylish finishes in a prime downtown location. The luxury unit features an open floor plan, floor-to-ceiling windows, and amenities including a 24-hour concierge. Real estate agent Ari Zadegan can provide more details about viewing this property.
Antoni Gaudí foi um famoso arquiteto catalão e figura de destaque do Modernismo catalão. Suas obras únicas revelam um estilo individual inspirado na natureza e estão localizadas principalmente em Barcelona, como a Sagrada Família, sua obra-prima inacabada. Gaudí dedicava atenção aos detalhes de suas obras, incorporando técnicas artesanais e novos materiais como o trencadís.
Music video purposes_work_sheet ben howardChristianO96
The document analyzes the purposes and benefits of music videos for artists and their target audiences. It discusses how music videos can be used to promote artists through social media platforms like Twitter, Facebook, and YouTube. This allows fans to follow and interact with artists, and provides feedback that artists and record labels can use to guide their future work. Music videos also help extend artists' income through merchandise and song sales on their websites. Record labels employ strategies like sending artists to awards shows to increase their profile and popularity. Overall, the document examines how music videos, social media, and record label support work together synergistically to benefit both artists and audiences.
This document discusses project portfolio management and collaborative decision making for IT investments. It proposes a 6-step workflow to maximize the value of projects, including defining value based on 5 pillars (strategic alignment, impact on processes, infrastructure agility, cost/benefit, and risk), defining rules and an organization decision mechanism for the project portfolio, setting service level objectives, measuring and monitoring, optimizing the portfolio, and negotiating a benefit realization plan. An example process called Rithm of Business is presented for organizing an organization decision mechanism. The goal is to move IT from a cost center to a value building center by doing more projects with less through governance and collaborative decision making.
This document discusses how podcasting can be used to grow a personal brand. It provides statistics on the growth of podcast listening and details the experience of the producer of a top 100 history podcast. The producer experienced over 120k listens in the first year. The document then outlines the three steps to podcasting - creating the podcast by choosing a topic and format, recording it with a microphone and sound editor, and promoting it on platforms, social media and other podcasts.
Pratik Motwani is a PhD candidate in electrical engineering at the University of Houston. His research focuses on developing novel metallic nano-sensors for biosensing applications. He has over 4 years of experience developing nanoscale materials and devices through cleanroom fabrication. Motwani has authored 5 publications and holds a patent related to his sensor research. He maintains a 3.78 GPA and received his bachelor's degree in electronics engineering from India with high honors.
REPORT on the Activities of Core FacilitiesCeitecNano
The document reports on the activities of core facilities for nanofabrication, nanocharacterization, and structural analysis at CEITEC. It provides a timeline of the facilities' development since 2008 and outlines their vision, staff, instruments, usage, costs, services, technological capabilities, organizational structure, and collaborations. The facilities aim to provide researchers open access to cutting-edge instrumentation through training and expert support. Summaries of several collaboration projects demonstrate how the facilities support multidisciplinary research.
Christopher Lalau-Keraly is a PhD candidate in electrical engineering at UC Berkeley studying nanophotonics. He has developed optimization software for nanophotonic devices using simulation tools and has studied phototransistors to enhance photoreceiver sensitivity. He has designed, fabricated, and characterized photoreceivers in the Berkeley cleanroom. He has published journal articles and conference papers on topics including shape optimization and photodetector design.
This thesis examines magneto impedance (MI) in thin film multi-layers for applications in sub-nano Tesla magnetic field sensors. Two such sensors are developed. The first utilizes asymmetrical MI elements combined differentially, achieving a resolution of 1 micro-oersted. The second improves low frequency sensitivity by AC biasing an MI element, achieving resolutions down to 3.73x10^-7 oersted at 1 kHz. The work investigates MI origins and characteristics in thin films, fabricating variations to optimize sensitivity, linearity, and dimensions for sensing. MI's matrix-like nature allows tailoring films for different applications. Asymmetrical effects enable linear bidirectional sensing without DC biasing.
Aili Maimaiti has experience using optical fibers and lasers to manipulate particles. She has realized optical manipulation using higher order microfiber modes for the first time and studied the spin and orbital angular momentum of microfiber modes. This research could have applications in quantum information, cold atom research, and biomedicine. She has skills in optics, lasers, microscopy, and programming languages and seeks to contribute to science and technology.
Dr. Mohan Babu Kuppam has received a PhD in physics from Grenoble University in France. He completed his PhD thesis on modeling ultrafast optoelectronic devices for RF signal processing and characterizing nanomaterials using optical and THz spectroscopy techniques. He has expertise in THz time-domain spectroscopy, optical pump-probe spectroscopy, and modeling electromagnetic devices. He has published several papers in these areas and presented his research at various conferences.
This curriculum vitae outlines the educational and professional experiences of Dr. Felice Pignatiello. They include a Master's degree in laser spectroscopy, work developing laser systems for printing applications, and project management. Their roles have involved the development of laser technologies, including low power lasers for computer-to-plate applications and high power lasers. They have also conducted research on laser spectroscopy and optical sensing techniques. Currently, they work on optoelectronic projects for printing and collaborate on a project using UV illumination for medical applications.
Giuseppe Garozzo has worked in various roles related to process development and integration for companies such as STMicroelectronics, Numonyx, and Micron since 1998. He has specialized in dry etching processes for materials such as dielectrics, metals, and phase change materials. Currently, he works on tasks related to dielectric etching, dual damascene integration, and back-end process transfer at Micron. He also collaborates on modeling of etching processes and has participated in several European projects.
This curriculum vitae summarizes Francesco Conti's education and work experience. He has a PhD in theoretical physics from the University of Pavia and currently works as a Quantitative Risk Analyst for UniCredit Group. He has extensive experience developing financial models and risk management methodologies using C++, Python, and other programming languages.
This curriculum vitae summarizes the professional experience and qualifications of Andrea Gabrielli. It lists his work history including research positions in Italy and France from 1998 to present. It also provides details of his education including a PhD in Physics from the University of Rome in 1998. The CV lists over 100 publications in scientific journals with a total impact factor of over 300 and nearly 2000 citations. It highlights his research interests and experience in complex systems, networks, and statistical physics applied to diverse fields.
Baishakhi Mazumder is an Indian citizen currently pursuing a PhD in physics at the University of Rouen in France. Her thesis focuses on understanding the physics of field evaporation of poor conducting materials using laser assisted atom probe tomography. She has over 7 years of experience in materials characterization and nanoscience research. Her work involves characterization techniques including atom probe tomography, scanning electron microscopy, transmission electron microscopy and atomic force microscopy.
Cristian Randieri has an extensive background in engineering, computer science, and research. He received his PhD in Engineering in Computer Science and Telecommunications from Catania University in 2004. Since then, he has held several research and teaching positions, including at CERN, various Italian universities, and as the founder and CEO of his own company Intellisystem Technologies. He has significant experience leading research and development projects in areas like remote monitoring, automation, and video surveillance for applications in industrial plants, hospitals, and more.
Dr. Gernot S. Pomrenke presents an overview of his program, Photonics and Optoelectronics, at the AFOSR 2013 Spring Review. At this review, Program Officers from AFOSR Technical Divisions will present briefings that highlight basic research programs beneficial to the Air Force.
This document provides a summary of the professional experience of Lavinia Elena Nistor, Ph.D. It outlines her work in research and development roles focused on non-volatile memory technologies like resistive RAM and phase change RAM. Some of her responsibilities included writing documentation, characterizing deposited alloys, and developing sputtering processes. She also has experience with magnetic random access memory projects involving characterization of magnetic tunnel junctions and translating results into tool and process solutions. Her education includes a PhD in Materials Science and experience in related research internships and associations.
IoT and Physics - from a simple pendulum to cosmic raysMilan Milošević
This document discusses using Internet of Things (IoT) technologies in physics education and research. It describes using sensors to study simple pendulums and creating an IoT-enabled double pendulum experiment. Citizen science projects detecting cosmic rays with smartphones and Raspberry Pi kits are also summarized. The document envisions expanding IoT applications to measure radiation and particles, helping more people experience and learn physics concepts.
Fritz Diorico is a Filipino physicist currently working as a project research assistant at the Atominstitut Technische Universität Wien in Vienna, Austria. He received his PhD in Physics from TU Wien in 2016, where he worked on combining ultracold atomic physics and superconductivity. He holds an Erasmus Mundus Masters of Science in Photonics from 2009-2010. His research interests include quantum optics, photonics, cryogenic systems, and ultracold atomic/molecular physics.
This curriculum vitae summarizes the educational and professional experience of Christopher Shearwood. He received a PhD in Solid State Physics from the University of Leeds in 1988. Since 1998, he has been an Associate Professor at Nanyang Technological University where he teaches and conducts research related to materials science and engineering. He has over 40 publications and 2 patents related to his work developing microelectromechanical systems and studying materials properties.
1. Le Van Hai is a postdoc researcher in Japan with experience in materials science, semiconductor processing, and device fabrication.
2. He has experience fabricating some of the world's smallest Fe-FET transistors and the first 64 kb Fe-NAND flash memory array.
3. He holds a PhD in applied physics from Osaka University where he worked on improving ferroelectric memory properties through surface treatments and developing a tunable photonic crystal filter using PLZT thin films.
I have had extensive work experience as an accomplished researcher with over 7 years’ experience in the field of Photo Physics (Laser), Physical Chemistry and Material Science
My key areas of expertise include, but are not limited to the following;
A solid background in the development and controlling of complex improvised experimental setups for optical and industrial applications, with parallel electronic support and opto-electronic synchronization where needed. Indicatively, I mention the modified fluorescent microscope for the single molecule detection (UTexas, Austin) and the experimental technique of determining the parameters of water vapor transmission through the membranes operating in controlled temperature and humidity conditions (FORTH/ICE-HT).
Having a well-deserved reputation on non-conventional materials analysis methods (single molecule spectroscopy) gained in the lab of the UTexas equipped with advanced infrastructure, I think that gave me strong skills for managing and solving scientific and industrial problems under the pressure of a highly competitive environment. In addition, the research experience in a wide range of applications will provide a solid basis to address scientific problem analysis and investigation of divergences in the transfer of research knowledge to innovative material technologies and the development of sensors.
Possessing a convincing track record on the assertion (novel ideas and writing of proposals) and on the scientific support (experiments, results dissemination, presentations in review meetings and international conferences) of research projects.
I believe that my skills, experience, and reputation for excellence can greatly enhance the interest of relative companies. I have a proven track record of responsibility, integrity and commitment to companies objectives. I am comfortable working independently or as part of a team.