NEMS (nanoelectromechanical systems) integrate electrical and mechanical functionality on the nanoscale, taking miniaturization a step further than MEMS (microelectromechanical systems). NEMS enable the integration of sensors, actuators, and other technologies through precision engineering at the sub-micrometer level. Approaches to fabricating NEMS include top-down methods using lithography and bottom-up methods relying on self-assembly of molecules. NEMS have applications in areas like nanobiotechnology, displays, and sensing and could further reduce device sizes and improve performance using materials like carbon. The development of NEMS promises new technological capabilities through continued miniaturization.
MEMS is a technique of combining electrical and mechanical components together on a chip. It produces a system of miniature dimensions i.e the system having thickness less than the thickness of human hair. The components are integrated on a single chip using micro fabrication technology which allows the microsystem to both sense & control the environment.
Nanoelectronics refer to the use of nanotechnology in electronic components. The term covers a diverse set of devices and materials, with the common characteristic that they are so small that inter-atomic interactions and quantum mechanical properties need to be studied extensively.
It was a review project that is typically more focused on mechanical parts and microfabrication technologies made suitable for biological applications.
The interdisciplinary nature of bio-MEMS combines material sciences, clinical sciences, medicine, surgery, electrical engineering, mechanical engineering, optical engineering, chemical engineering and biomedical engineering.
Some of its major applications include genomics, proteomics, molecular diagnostics, point-of-care diagnostics, tissue engineering and implantable microdevices. MEMS techniques were originally developed in the microelectronics industry.
MEMS are a class of miniature devices and systems fabricated by micromachining processes. MEMS devices have critical dimensions in the range of 100nm to 1000um (or 1mm).
MEMS technology is a precursor to the relatively more popular field of Nanotechnology, which refers to science, engineering and technology below 100nm down to the atomic scale.
Occasionally, MEMS devices with dimensions in the millimetre-range are referred to as meso-scale MEMS devices. as drug delivery systems improve, the components of the systems continue to decrease in size.
Currently, most drug delivery systems are based upon devices and drug carrier elements that are on a micro-scale. Many of the future and developing technologies are based on the nano-scale.
MEMS is a technique of combining electrical and mechanical components together on a chip. It produces a system of miniature dimensions i.e the system having thickness less than the thickness of human hair. The components are integrated on a single chip using micro fabrication technology which allows the microsystem to both sense & control the environment.
Nanoelectronics refer to the use of nanotechnology in electronic components. The term covers a diverse set of devices and materials, with the common characteristic that they are so small that inter-atomic interactions and quantum mechanical properties need to be studied extensively.
It was a review project that is typically more focused on mechanical parts and microfabrication technologies made suitable for biological applications.
The interdisciplinary nature of bio-MEMS combines material sciences, clinical sciences, medicine, surgery, electrical engineering, mechanical engineering, optical engineering, chemical engineering and biomedical engineering.
Some of its major applications include genomics, proteomics, molecular diagnostics, point-of-care diagnostics, tissue engineering and implantable microdevices. MEMS techniques were originally developed in the microelectronics industry.
MEMS are a class of miniature devices and systems fabricated by micromachining processes. MEMS devices have critical dimensions in the range of 100nm to 1000um (or 1mm).
MEMS technology is a precursor to the relatively more popular field of Nanotechnology, which refers to science, engineering and technology below 100nm down to the atomic scale.
Occasionally, MEMS devices with dimensions in the millimetre-range are referred to as meso-scale MEMS devices. as drug delivery systems improve, the components of the systems continue to decrease in size.
Currently, most drug delivery systems are based upon devices and drug carrier elements that are on a micro-scale. Many of the future and developing technologies are based on the nano-scale.
MEMS technology consist of micro electronic elements actuators, sensors and mechanical structures built onto a substrate which is usually “Silicon”. They are developed using microfabrication techniques : deposition, patterning, etching.
The most common forms of MEMS production are :
Bulk micromachine, surface micromachine etc.
The benefits of this small scale integrated device brings the technology of nanometers to a vast no. of devices.
Micro-Electro-Mechanical Systems, or MEMS, is a technology that in its most general form can be defined as miniaturized mechanical and electro-mechanical elements that are made using the techniques of micro fabrication. The critical physical dimensions of MEMS devices can vary from well below one micron on the lower end of the dimensional spectrum, all the way to several millimeters.
MEMS or Micro-Electro Mechanical System is a technique of combining Electrical and Mechanical components together on a chip, to produce a system of miniature dimensions. MEMS is the integration of a number of micro-components on a single chip which allows the microsystem to both sense and control the environment.
MEMS = Micro Electro Mechanical System
Any engineering system that performs electrical (switching ,deciding) and mechanical functions (sensing,moving,heating) with components in micrometers is a MEMS.
MEMS technology consist of micro electronic elements actuators, sensors and mechanical structures built onto a substrate which is usually “Silicon”. They are developed using microfabrication techniques : deposition, patterning, etching.
The most common forms of MEMS production are :
Bulk micromachine, surface micromachine etc.
The benefits of this small scale integrated device brings the technology of nanometers to a vast no. of devices.
Micro-Electro-Mechanical Systems, or MEMS, is a technology that in its most general form can be defined as miniaturized mechanical and electro-mechanical elements that are made using the techniques of micro fabrication. The critical physical dimensions of MEMS devices can vary from well below one micron on the lower end of the dimensional spectrum, all the way to several millimeters.
MEMS or Micro-Electro Mechanical System is a technique of combining Electrical and Mechanical components together on a chip, to produce a system of miniature dimensions. MEMS is the integration of a number of micro-components on a single chip which allows the microsystem to both sense and control the environment.
MEMS = Micro Electro Mechanical System
Any engineering system that performs electrical (switching ,deciding) and mechanical functions (sensing,moving,heating) with components in micrometers is a MEMS.
One-Dimensional Carbon Nanostructures—From Synthesis to Nano-electromechanica...Mariana Amorim Fraga
The fundamental properties of one-dimensional (1D) carbon nanostructures and their promising technological applications have stimulated significant research in different areas. Because of their outstanding electrical and mechanical properties, these nanostructures have emerged as a new class of sensor material with real potential for a variety of nano-electromechanical systems (NEMS). Several studies have shown that the performance of a NEMS device is significantly affected by the material properties of the nanostructures used to build it. For this reason, a section of this review is devoted to the synthesis and properties of 1D carbon nanostructures including nanotubes, nanofibers, and nanowires. Thereafter, some NEMS-based sensors using 1D carbon nanostructures are introduced and issues related to their fabrication processes are addressed. The goal of this brief review is to outline the benefits of the use of 1D carbon nanostructures, the current status of development and challenges to enable their widespread application as sensing elements in NEMS devices.
pp. 39-56
S&M1299
http://dx.doi.org/10.18494/SAM.2017.1366
Online Published: January 25, 2017
Paul Ahern - Overview of Micro & Nano TransducersPaul Ahern
Abstract— The aim of this paper is to present a review of current transducer technology, fabrication methods and materials pertinent to the nanotechnology and MEMS era. We begin with an introduction to the concept of a transducer and the historical context, and then review some specific application classes of transducers where nanotechnology has already, or has the possibility in the future, to have an impact on the transducer device market. This review highlights the advantages of these MEMS approaches to promote new transducer types, especially those related to nanotechnology, and possible future research directions are discussed.
JMeter webinar - integration with InfluxDB and GrafanaRTTS
Watch this recorded webinar about real-time monitoring of application performance. See how to integrate Apache JMeter, the open-source leader in performance testing, with InfluxDB, the open-source time-series database, and Grafana, the open-source analytics and visualization application.
In this webinar, we will review the benefits of leveraging InfluxDB and Grafana when executing load tests and demonstrate how these tools are used to visualize performance metrics.
Length: 30 minutes
Session Overview
-------------------------------------------
During this webinar, we will cover the following topics while demonstrating the integrations of JMeter, InfluxDB and Grafana:
- What out-of-the-box solutions are available for real-time monitoring JMeter tests?
- What are the benefits of integrating InfluxDB and Grafana into the load testing stack?
- Which features are provided by Grafana?
- Demonstration of InfluxDB and Grafana using a practice web application
To view the webinar recording, go to:
https://www.rttsweb.com/jmeter-integration-webinar
Kubernetes & AI - Beauty and the Beast !?! @KCD Istanbul 2024Tobias Schneck
As AI technology is pushing into IT I was wondering myself, as an “infrastructure container kubernetes guy”, how get this fancy AI technology get managed from an infrastructure operational view? Is it possible to apply our lovely cloud native principals as well? What benefit’s both technologies could bring to each other?
Let me take this questions and provide you a short journey through existing deployment models and use cases for AI software. On practical examples, we discuss what cloud/on-premise strategy we may need for applying it to our own infrastructure to get it to work from an enterprise perspective. I want to give an overview about infrastructure requirements and technologies, what could be beneficial or limiting your AI use cases in an enterprise environment. An interactive Demo will give you some insides, what approaches I got already working for real.
Generating a custom Ruby SDK for your web service or Rails API using Smithyg2nightmarescribd
Have you ever wanted a Ruby client API to communicate with your web service? Smithy is a protocol-agnostic language for defining services and SDKs. Smithy Ruby is an implementation of Smithy that generates a Ruby SDK using a Smithy model. In this talk, we will explore Smithy and Smithy Ruby to learn how to generate custom feature-rich SDKs that can communicate with any web service, such as a Rails JSON API.
Neuro-symbolic is not enough, we need neuro-*semantic*Frank van Harmelen
Neuro-symbolic (NeSy) AI is on the rise. However, simply machine learning on just any symbolic structure is not sufficient to really harvest the gains of NeSy. These will only be gained when the symbolic structures have an actual semantics. I give an operational definition of semantics as “predictable inference”.
All of this illustrated with link prediction over knowledge graphs, but the argument is general.
Elevating Tactical DDD Patterns Through Object CalisthenicsDorra BARTAGUIZ
After immersing yourself in the blue book and its red counterpart, attending DDD-focused conferences, and applying tactical patterns, you're left with a crucial question: How do I ensure my design is effective? Tactical patterns within Domain-Driven Design (DDD) serve as guiding principles for creating clear and manageable domain models. However, achieving success with these patterns requires additional guidance. Interestingly, we've observed that a set of constraints initially designed for training purposes remarkably aligns with effective pattern implementation, offering a more ‘mechanical’ approach. Let's explore together how Object Calisthenics can elevate the design of your tactical DDD patterns, offering concrete help for those venturing into DDD for the first time!
GDG Cloud Southlake #33: Boule & Rebala: Effective AppSec in SDLC using Deplo...James Anderson
Effective Application Security in Software Delivery lifecycle using Deployment Firewall and DBOM
The modern software delivery process (or the CI/CD process) includes many tools, distributed teams, open-source code, and cloud platforms. Constant focus on speed to release software to market, along with the traditional slow and manual security checks has caused gaps in continuous security as an important piece in the software supply chain. Today organizations feel more susceptible to external and internal cyber threats due to the vast attack surface in their applications supply chain and the lack of end-to-end governance and risk management.
The software team must secure its software delivery process to avoid vulnerability and security breaches. This needs to be achieved with existing tool chains and without extensive rework of the delivery processes. This talk will present strategies and techniques for providing visibility into the true risk of the existing vulnerabilities, preventing the introduction of security issues in the software, resolving vulnerabilities in production environments quickly, and capturing the deployment bill of materials (DBOM).
Speakers:
Bob Boule
Robert Boule is a technology enthusiast with PASSION for technology and making things work along with a knack for helping others understand how things work. He comes with around 20 years of solution engineering experience in application security, software continuous delivery, and SaaS platforms. He is known for his dynamic presentations in CI/CD and application security integrated in software delivery lifecycle.
Gopinath Rebala
Gopinath Rebala is the CTO of OpsMx, where he has overall responsibility for the machine learning and data processing architectures for Secure Software Delivery. Gopi also has a strong connection with our customers, leading design and architecture for strategic implementations. Gopi is a frequent speaker and well-known leader in continuous delivery and integrating security into software delivery.
UiPath Test Automation using UiPath Test Suite series, part 3DianaGray10
Welcome to UiPath Test Automation using UiPath Test Suite series part 3. In this session, we will cover desktop automation along with UI automation.
Topics covered:
UI automation Introduction,
UI automation Sample
Desktop automation flow
Pradeep Chinnala, Senior Consultant Automation Developer @WonderBotz and UiPath MVP
Deepak Rai, Automation Practice Lead, Boundaryless Group and UiPath MVP
Essentials of Automations: Optimizing FME Workflows with ParametersSafe Software
Are you looking to streamline your workflows and boost your projects’ efficiency? Do you find yourself searching for ways to add flexibility and control over your FME workflows? If so, you’re in the right place.
Join us for an insightful dive into the world of FME parameters, a critical element in optimizing workflow efficiency. This webinar marks the beginning of our three-part “Essentials of Automation” series. This first webinar is designed to equip you with the knowledge and skills to utilize parameters effectively: enhancing the flexibility, maintainability, and user control of your FME projects.
Here’s what you’ll gain:
- Essentials of FME Parameters: Understand the pivotal role of parameters, including Reader/Writer, Transformer, User, and FME Flow categories. Discover how they are the key to unlocking automation and optimization within your workflows.
- Practical Applications in FME Form: Delve into key user parameter types including choice, connections, and file URLs. Allow users to control how a workflow runs, making your workflows more reusable. Learn to import values and deliver the best user experience for your workflows while enhancing accuracy.
- Optimization Strategies in FME Flow: Explore the creation and strategic deployment of parameters in FME Flow, including the use of deployment and geometry parameters, to maximize workflow efficiency.
- Pro Tips for Success: Gain insights on parameterizing connections and leveraging new features like Conditional Visibility for clarity and simplicity.
We’ll wrap up with a glimpse into future webinars, followed by a Q&A session to address your specific questions surrounding this topic.
Don’t miss this opportunity to elevate your FME expertise and drive your projects to new heights of efficiency.
Slack (or Teams) Automation for Bonterra Impact Management (fka Social Soluti...Jeffrey Haguewood
Sidekick Solutions uses Bonterra Impact Management (fka Social Solutions Apricot) and automation solutions to integrate data for business workflows.
We believe integration and automation are essential to user experience and the promise of efficient work through technology. Automation is the critical ingredient to realizing that full vision. We develop integration products and services for Bonterra Case Management software to support the deployment of automations for a variety of use cases.
This video focuses on the notifications, alerts, and approval requests using Slack for Bonterra Impact Management. The solutions covered in this webinar can also be deployed for Microsoft Teams.
Interested in deploying notification automations for Bonterra Impact Management? Contact us at sales@sidekicksolutionsllc.com to discuss next steps.
Epistemic Interaction - tuning interfaces to provide information for AI supportAlan Dix
Paper presented at SYNERGY workshop at AVI 2024, Genoa, Italy. 3rd June 2024
https://alandix.com/academic/papers/synergy2024-epistemic/
As machine learning integrates deeper into human-computer interactions, the concept of epistemic interaction emerges, aiming to refine these interactions to enhance system adaptability. This approach encourages minor, intentional adjustments in user behaviour to enrich the data available for system learning. This paper introduces epistemic interaction within the context of human-system communication, illustrating how deliberate interaction design can improve system understanding and adaptation. Through concrete examples, we demonstrate the potential of epistemic interaction to significantly advance human-computer interaction by leveraging intuitive human communication strategies to inform system design and functionality, offering a novel pathway for enriching user-system engagements.
Transcript: Selling digital books in 2024: Insights from industry leaders - T...BookNet Canada
The publishing industry has been selling digital audiobooks and ebooks for over a decade and has found its groove. What’s changed? What has stayed the same? Where do we go from here? Join a group of leading sales peers from across the industry for a conversation about the lessons learned since the popularization of digital books, best practices, digital book supply chain management, and more.
Link to video recording: https://bnctechforum.ca/sessions/selling-digital-books-in-2024-insights-from-industry-leaders/
Presented by BookNet Canada on May 28, 2024, with support from the Department of Canadian Heritage.
Accelerate your Kubernetes clusters with Varnish CachingThijs Feryn
A presentation about the usage and availability of Varnish on Kubernetes. This talk explores the capabilities of Varnish caching and shows how to use the Varnish Helm chart to deploy it to Kubernetes.
This presentation was delivered at K8SUG Singapore. See https://feryn.eu/presentations/accelerate-your-kubernetes-clusters-with-varnish-caching-k8sug-singapore-28-2024 for more details.
2. What is NEMS?
The term Nanoelectromechanical systems
or NEMS is used to describe devices
integrating electrical and mechanical
functionality on the nanoscale.
NEMS form the logical next miniaturization
step from so-called microelectromechanical
systems, or MEMS devices.
3. NEMS - Definition
NEMS is the integration of sensors, actuators,
electronics, photonics, energy, fluidics,
chemistry, and biology into a meaningful
system enabled by sub micrometer science
and engineering precision.
4. Nanowires
Nanowires such as nanoLED arrays might enable a
new class of nanodisplays.
But consider fabricating nanowires out of dissimilar
materials such as gallium arsenic on silicon.
The ability to realize vertical nanowires composed of
metals, semiconductors, and insulators on silicon
and other substrates will enable new types of high
performance, heterogeneous micro- and
nanosystems.
And they can be formed without the usual
considerations of lattice strain matching that occurs
in microscale dimensions.
6. NEMS in Nano Biotechnology
NEMS will also enable other important new
opportunities in the emerging field of
nanobiotechnology.
The ultrasensitive detection method could replace
complicated optical fluorophore tags and optical
readout methods routinely used by molecular
biologists with a simple electrically measured
parameter—frequency.
A biocantilever diving board fabricated by Professor
Michael Roukes at CalTech has shown the ability to
detect small mass changes as low as 7 zeptograms,
which is roughly the mass of a single protein
molecule!
7. Nanoassembly
The most important area of NEMS opportunity
arises— programmable self-assembly for
heterogeneous nanointegration.
It is simply called as nanoassembly––a new
manufacturing paradigm that allows for the
directed self-assembly of components into
precise locations on a substrate.
Nanoassembly might also be used to build
systems on non-planar or 3D surfaces where
traditional monolithic integration has failed.
8. Approaches to miniaturization
Two complementary approaches to
fabrication of NEMS systems can be found.
The top-down approach
The bottom-up approach
9. Top-down approach
The top-down approach uses the traditional
microfabrication methods, i.e. optical and
electron beam lithography, to manufacture
devices.
Typically, devices are fabricated from metallic
thin films or etched semiconductor layers.
10. Bottom-up approach
Bottom-up approaches, in contrast, use the
chemical properties of single molecules to
cause single-molecule components to
(a) self-organize or self-assemble into some useful
conformation, or
(b) rely on positional assembly
This allows fabrication of much smaller
structures, albeit often at the cost of limited
control of the fabrication process.
11. Future of NEMS
NEMS devices, if implemented into everyday
technologies, could further reduce the size of
modern devices and allow for better
performing sensors.
Carbon based materials have served as prime
materials for NEMS use, because of their
highlighted mechanical and electrical
properties.
12. Conclusion
In summary, the MEMS revolution that began
at DARPA in the early 1990s will continue to
bring new and more powerful microsystems
to the commercial world and defense
community.
Therefore, there is no doubt that the Age of
NEMS will produce exciting new capabilities
we are only now beginning to imagine.
