In this section you can list your problem - solving abilities and your knowledge of the tools and
materials used in the field.
Index Editors are required to possess a solid knowledge of the methods and
materials used in the field.
Not exact matches
According to Bartel, SDM's customers, especially those
in the aerospace and medical
fields, are asking for and
using aluminum and titanium, lightweight metals with considerable
material strength.
If one considers only the forms
in which it was transmitted, the methods
used by the legalists, the
material of its content, and the restricted
field of its application as the whole
field of positive law, then its role is quite limited.
® Eagle products are valued leaders
in every
field, whether they are
used for foodservice, industrial
material handling, retail display, cleanroom, healthcare or pharmaceutical applications.
That partnership also gives Boston Beer the ability to
use the Red Sox logo
in marketing
materials, as well as a large Samuel Adams sign
in right
field, replacing a Budweiser logo that towered above Fenway Park for nine years.
This includes learning to
use many more hands - on
materials and activities (that are not practical
in a large classroom with many children and only one adult), checking the regulations
in your area, finding out about home school groups, places to visit for your
field trips, etc..
By 3 - D printing a deformable
material containing iron particles
in a lattice structure, their metamaterials can be compressed
using a magnetic
field.
The model derives from a general lattice
field theory, which is typically
used to describe the quantum behavior of electrons
in magnetic and electronic
materials.
Nanoplasmonic
materials have attracted the attention of biologists, chemists, physicists and
material scientists, with possible
uses in a diverse array of
fields, such as biosensing, data storage, light generation and solar cells.
Surprisingly, Jarillo - Herrero and colleagues report, the same
material can also be nudged into becoming an insulator —
in which electrons are stuck
in place — by
using an electric
field to remove electrons from the
material.
Respondents
in this year's survey pointed to five main causes of the
field's less than favorable reputation: drug and product recalls such as the withdrawal of Avandia; safety issues such as the discovery of problems with raw
material from China
used in medical products; scandals, including evidence that pharmaceutical companies have failed to release data from trials whose results cast doubts on their drugs» safety and efficacy; lawsuits brought against companies that failed to warn patients of problems with their products; and ethical issues such as kickbacks for physicians promoting specific medications.
The resulting disordered atomic network and its physical properties resemble those seen
in some glassy
materials, which has led many
in the
field to
use them
in nuclear research.
The findings, which report the
use of magnetic permeability - how easily a magnetic
field will magnetize a
material - are published today, Friday 11th September,
in the Journal of Physics D: Applied Physics.
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.
The team
used the strain induced by an electric
field applied to a piezoelectric
material (which deforms mechanically
in response to an electric
field) to manipulate the chirality of the domain wall.
The problem is solved by
using magnetic
fields, which confine and thermally insulate the charged particles
in the fuel, keeping them away from
material surfaces.
Because of the high magnetic
field required to produce the magnetoresistance effect, Kobayashi says, the
material isn't ready to be
used in data storage devices.
High - pressure synthesis (over 10 GPa) is not a commonly
used method
in the
field of
materials science, write the researchers
in their study published
in the Journal of the American Chemical Society.
«If we can understand how to take this tool box and
use it
in the design of new structures or the synthesis of new
materials, that opens a whole new
field of chemistry that so far has been dark to us, because we did not know how to actually visualize what is going on.»
Using this
material, the researchers were able to analyse
in detail the response of rhodopsin, the pigment protein underlying vision, and phosphodiesterase, and for this reason they believe it can be useful
in the
field of optogenetics
in the future.
Since the operating temperature for fusion is
in the hundreds of millions degrees Celsius, hotter than any known
material can withstand, engineers found they could contain a plasma — a neutral electrically conductive, high - energy state of matter — at these temperatures
using magnetic
fields.
The traditional approach is to observe a «residual» effect
in the
material's response (hysteresis loop)
using a SPM, for example, the
material retains residual electric polarization after removal of an external electric
field.
However,
in reality this synthesis method could be
used for a wide range of
materials outside the biomedical
field.»
Now, an international theory and computational team led by Cesare Franchini from the University of Vienna, find that multiple quantum interactions can coexist
in a single real
material and show how an electric
field can be
used to control them.
«We can now take linear nano -
materials and direct how they are organized
in two dimensions,
using a DNA origami platform to create any number of shapes,» explains NYU Chemistry Professor Nadrian Seeman, the paper's senior author, who founded and developed the
field of DNA nanotechnology, now pursued by laboratories around the globe, three decades ago.
Furthermore, the researchers from Aalto University and University of Jyväskylä have recently shown how DNA origamis can be
used in efficient fabrication of custom - shaped metal nanoparticles that could be
used in various
fields of
material sciences.
Generally speaking, magnetic
fields can be
used to change the magnetization of a magnetic
material, much like a bar magnet can magnetize an otherwise nonmagnetic sewing needle, and can even reverse its magnetization completely
in some cases.
Capture of all the transmitted electrons allows quantitative measurement of
materials properties, such as internal electric and magnetic
fields, which are important for
use of the
materials in memory and electronics applications.
Andrews says the team's research marks an important turning point
in the
field because it represents a significant advance toward solving the cathode problem while also highlighting the inherent advantages of
using much more imaginative, metastable
materials like this new form of vanadium pentoxide.
Although computer models of archaeological sites are ideal software tools for managing spatially referenced data and commonly
used to yield insights which contribute to the protection of heritage
materials, some scientists question their credibility, calling for these long - term trends be «ground truthed»
in order to ensure that calculated rates of change reflect observed phenomena «
in the
field».
The
materials and elements
used to form these structures allow us forecast new trends
in solotronics - a
field of experimental electronics and spintronics of the future, based on operations occurring on a single - atom level.
For example, VTT succeeded
in using a permalloy ink to print a magnetically anisotropic
material, which can be
used in the manufacture of magnetic
field sensors.
However, chemical engineers at the University of Guadalajara (UdeG),
in Mexico, developed a new technology based on thermosensitive nanoparticles (nano - hydrogels) to
use these
materials in the
field of biomedicine, as an alternative to achieve controlled release of anticancer drugs.
Because the process of solidifying metals produces branch - like internal micro-patterns that disturb the chemical homogeneity of cast
materials, having a better understanding of the bias
field's role
in their formation opens pathways for engineers to make improvements
in cast and welded
materials commonly
used in everything from automobiles and airplanes to medical instruments.
From hosting a webinar series on the
use of specific scientific methods to support human rights research, to the development of teaching
materials to integrate human rights into STEM curricula, from assessing the extent to which marginalized populations are represented
in STEM
fields, to cultivating a human rights interest group within a member organization, there are many ways
in which Coalition members can further the mission of the Coalition within their communities, organizations and
in collaboration with others.
Professor Alvaro Mata, from Queen Mary's School of Engineering and
Materials Science, said: «The technique opens the possibility to design and create biological scenarios like complex and specific cell environments, which can be
used in different
fields such as tissue engineering by creating constructs that resemble tissues or
in vitro models that can be
used to test drugs
in a more efficient manner.»
Better MRI scanners could result from a trick
in which a magnetic
field springs up from nowhere,
using materials famous for their link to invisibility cloaks
Budker, who works on sensitive magnetic
field detectors, and Folman, who builds «atom chips» to probe and manipulate atoms, focused
in this work on
using these magnetometers to study new
materials.
ARL created a generalized model
using an energetic formulation approach, which was key
in identifying two important mechanisms for enabling high bending motion
in soft biological actuators: (i) tuning physical properties (mechanical and geometric) via exploiting the interplay between the
materials and dynamic nonlinearities to augment the motion; and (ii) highlighting the electromechanical coupling between the electrical
field and nonlinear structural stiffness through the distributive actuation circuitries.
In the paper, they describe the
use of band engineering and multi strain
field fluctuation to enhance the figure of merit for the
material.
Using a method that they published earlier this year, the team arranged metal - oxide nanosheets into a single plane within a material by using a magnetic field and then fixed them in place using a procedure called light - triggered in - situ vinyl polymerization, which essentially uses light to congeal a substance into a hydr
Using a method that they published earlier this year, the team arranged metal - oxide nanosheets into a single plane within a
material by
using a magnetic field and then fixed them in place using a procedure called light - triggered in - situ vinyl polymerization, which essentially uses light to congeal a substance into a hydr
using a magnetic
field and then fixed them
in place
using a procedure called light - triggered in - situ vinyl polymerization, which essentially uses light to congeal a substance into a hydr
using a procedure called light - triggered
in - situ vinyl polymerization, which essentially
uses light to congeal a substance into a hydrogel.
Apart from their application
in the
field of food containers, the proteins obtained can be
used to produce biocompatible
materials.
«One of the challenges
in this
field,» said the researcher Pedro Guerrero, «is to obtain
materials that can be processed
using additive manufacturing, 3D printing.
Part of the funding will be
used to train the next generation of
materials scientists familiar with the challenges of growing high quality crystals
in this rapidly expanding
field.
He also has several patents awarded or pending, served on numerous scientific advisory and review committees, organized several national and international conferences (including the 2006
Materials Research Society Fall meeting with more 5000 attendees), and edited 6 books in the field of materials characterization using synchrotron r
Materials Research Society Fall meeting with more 5000 attendees), and edited 6 books
in the
field of
materials characterization using synchrotron r
materials characterization
using synchrotron radiation.
Nadrian C. Seeman, of New York University
in the U.S., is the founding father of structural DNA nanotechnology, a
field that exploits the structural properties of DNA to
use it as a raw
material for the next generation of nanoscale circuits, sensors, and biomedical devices.
In a new development, Technische Universität Wien has managed to
use electrical
fields to control the magnetic oscillations of certain ferrous
materials.
It plans to
use newly available superconducting
materials and technology that can create magnetic
fields four times stronger than any
in use now.
PNNL researchers will
use it to make measurements and gain understanding never before possible
in fields such as synthesis of
materials and biomedical studies.