GILBERT: One of the most exciting things, from my perspective, is to
use nanoscience to reduce the complexity of our datasets.
You've been involved in designing ways to
use nanoscience tools to understand the brain better.
PhD student Joana Guerreiro has taken part in developing a sensor, which - by
using nanoscience - can measure how we experience the feeling of dryness in wine.
Not exact matches
«This is a material that we are very familiar with,» explains Professor Lieven Vandersypen of QuTech and the Kavli Institute of
Nanoscience Delft, «Silicon is widely
used in transistors and so can be found in all electronic devices.»
Researchers from IMDEA
Nanoscience, the Autonomous University of Madrid, the Madrid Institute of Materials Science (CSIC) and the University of the Basque Country describe in the journal Nature Physics this week how to create a powerful magnetic field
using this new material.
Because the DNA cages are
used as a «mold» to build the polymer particle, the particle size and number of molecular units in the polymer can be precisely controlled, says Sleiman, who holds the Canada Research Chair in DNA
Nanoscience.
«This spin - orbit interaction is a million times more intense than that inherent to graphene, which is why we obtain revolutions that could have important
uses, for example in data storage,» explains Rodolfo Miranda, Director of IMDEA
Nanoscience and head of the study.
The research team from the Centre for Photonics and Photonic Materials, and the Centre for
Nanoscience and Nanotechnology at the University of Bath,
used a special white - light laser built in - house and directed it through several optical components to put a twist on the beam.
«We've
used enzymatic production methods to create a system that not only improves the quality of the manufactured oligonucleotides but that also makes it possible to scale up production
using bacteria in order to produce large amounts of DNA copies cheaply,» says co-developer Björn Högberg at the Swedish Medical
Nanoscience Center, part of the Department of Neuroscience at Karolinska Institutet in Sweden.
These processes are very diverse and varied, and researchers have
used atomic force microscopy and similar
nanoscience tools to understand how those electrons flow at the atomic scale.
«Park Systems has invested significant resources into the new Park
Nanoscience Lab in Europe to offer the vast European scientific community a better opportunity to
use our AFM product and make side - by - side comparisons to the well - known European AFM.
NST research ranges from fundamental to
use - inspired
nanoscience with connections to industry and the Argonne applied science divisions.
«Revolutionary new microscopy technology provided thru Park Systems AFM (Atomic Force Microscopy) and new innovations in chemical and material research indicates that there is a defined opportunity to
use the advances in chemistry, materials, and
nanoscience to make valuable industry process updates.»
For the past two decades, the winners of the 2014 Kavli Prize in
Nanoscience have been
using nanotechnology to reimagine how we might see beyond this limit.
Measuring the strength of the atoms Scientists from the team led by Professor Ernst Meyer from the Swiss
Nanoscience Institute and the University of Basel's Department of Physics examined these graphene ribbons
using atomic force microscopy (AFM).
The 32 T superconducting system is made from two primary sections, an outsert section delivering 15 Tesla in a 250 mm wide bore magnet developed by Oxford Instruments
Nanoscience (OINS)
using advanced Low Temperature Superconductor (LTS) materials operating at 4.2 Kelvin and an insert section delivering 17 Tesla in 34 mm cold bore developed by our colleagues at NHMFL
using advanced High Temperature Superconductor (HTS) materials manufactured by Superpower Inc..
Researchers seeking to understand the fundamentals of properties at the nanoscale may call their work
nanoscience; those focused on effective
use of the properties may call their work nanoengineering.
Nanoscience and nanotechnology are the study and application of extremely small things and can be
used across all the other science fields, such as chemistry, biology, physics, materials science, and engineering.
GERBER: My group at the Swiss
Nanoscience Institute is
using AFM to study mutations of cancer patients in order to improve diagnosis and treatment.
McREL's NanoTeach project created high - quality PD that blended instructional strategies from Designing Effective Science Instruction (Tweed, 2009) with hands - on learning of
nanoscience and technology (NS&T) content,
using research - proven strategies and inquiry - based practices that help teachers became more confident in their ability to teach NS&T.