Menu

Blog

Archive for the ‘nanotechnology’ category: Page 272

Jul 11, 2016

Atomic bits despite zero-point energy? Jülich scientists explore novel ways of developing stable nanomagnets

Posted by in categories: computing, mobile phones, nanotechnology, particle physics, quantum physics

Stable nanomagnets that ultimately improves data storage on the smallest of devices.


Abstract: So-called “zero-point energy” is a term familiar to some cinema lovers or series fans; in the fictional world of animated films such as “The Incredibles” or the TV series “Stargate Atlantis”, it denotes a powerful and virtually inexhaustible energy source. Whether it could ever be used as such is arguable. Scientists at Jülich have now found out that it plays an important role in the stability of nanomagnets. These are of great technical interest for the magnetic storage of data, but so far have never been sufficiently stable. Researchers are now pointing the way to making it possible to produce nanomagnets with low zero-point energy and thus a higher degree of stability (Nano Letters, DOI: 10.1021/acs.nanolett.6b01344).

Since the 1970s, the number of components in computer chips has doubled every one to two years, their size diminishing. This development has made the production of small, powerful computers such as smart phones possible for the first time. In the meantime, many components are only about as big as a virus and the miniaturization process has slowed down. This is because below approximately a nanometre, a billionth of a meter in size, quantum effects come into play. They make it harder, for example, to stabilise magnetic moments. Researchers worldwide are looking for suitable materials for magnetically stable nanomagnets so that data can be stored safely in the smallest of spaces.

Continue reading “Atomic bits despite zero-point energy? Jülich scientists explore novel ways of developing stable nanomagnets” »

Jul 11, 2016

Nanotech ‘tattoo’ can map emotions and monitor muscle activity

Posted by in category: nanotechnology

Um nova “tatuagem eletrônica”, desenvolvido pela Universidade de Tel Aviv, que pode medir a atividade de pesquisadores células musculares e nervosas está pronta para revolucionar a medicina, reabilitação, e até mesmo de negócios e pesquisa de marketing.

Read more

Jul 11, 2016

‘Nano scalpel’ allows structuring of samples with nanometre precision

Posted by in categories: biological, nanotechnology

A new “nano scalpel” enables scientists at DESY to prepare samples or materials with nanometre precision while following the process with a scanning electron microscope. The Focused Ion Beam, or FIB, microscope which has now gone into service also allows a detailed view of the inner structure of materials. The device was purchased by the University of Bayreuth, as part of a joint research project on the DESY campus funded by the Federal Ministry of Research. The FIB will be operated at the DESY NanoLab jointly with the University of Bayreuth.

“The microscope is not only able to examine microscopic defects, cracks or point-like corrosion sites underneath the surfaces of , but also to machine the surface of samples with extremely high precision, on a nanometre scale,” explains Maxim Bykov, project scientist from the University of Bayreuth. A nanometre is a millionth of a millimetre. The can be used to remove material as though it were a microscopic milling machine; as a result, the combined ion beam and electron microscope is particularly interesting for a wide range of applications in nanotechnology, materials science and biology.

“Apart from examining the structure of materials, the ability of the ion beam to remove material also leads to a wide range of different applications,” says Natalia Dubrovinskaia who is a professor at the University of Bayreuth and in charge of the joint research project (No. 05K13WC3). One example is the preparation of tiny diamond anvils, which are used to hold samples during ultra high-pressure experiments. The diamonds used for this are so small that there is no other way of preparing them. The ion beam allows so-called double-staged diamond anvil cells to be prepared with nanometre precision. The ultra high-pressure experiments are carried out at DESY’s Extreme Conditions Beamline (ECB) P02.2, headed by DESY scientist Hanns-Peter Liermann.

Continue reading “‘Nano scalpel’ allows structuring of samples with nanometre precision” »

Jul 11, 2016

Nano-tech: How your DNA can enhance the power of computing

Posted by in categories: biotech/medical, computing, nanotechnology

I am glad others are seeing the light.


It holds the key to the future of bio-technology and computing.

Read more

Jul 11, 2016

Researchers develop faster, precise silica coating process for quantum dot nanorods

Posted by in categories: mobile phones, nanotechnology, quantum physics

Faster and better method around Q-dots development which ultimately extends the quality of Quantum Dots plus mass production of Q-Dots is much faster through this new method. Hoping this causes the costs of new cameras, phone displays, monitors/ video displays are now able to be created more cheaply and in larger quantities.


Materials researchers at North Carolina State University have fine-tuned a technique that enables them to apply precisely controlled silica coatings to quantum dot nanorods in a day — up to 21 times faster than previous methods. In addition to saving time, the advance means the quantum dots are less likely to degrade, preserving their advantageous optical properties.

Quantum dots are nanoscale semiconductor materials whose small size cause them to have electron energy levels that differ from larger-scale versions of the same material. By controlling the size of the quantum dots, researchers can control the relevant energy levels — and those energy levels give quantum dots novel optical properties. These characteristics make quantum dots promising for applications such as opto-electronics and display technologies.

Continue reading “Researchers develop faster, precise silica coating process for quantum dot nanorods” »

Jul 8, 2016

Tiny Hydraulic ‘Nano-Press’ Crushes Things Out of This Dimension

Posted by in categories: materials, nanotechnology

It could be used to make new 2D materials, but this one probably won’t go viral.

Read more

Jul 8, 2016

A Flexible Evolving Approach To Computing

Posted by in categories: computing, nanotechnology, singularity

To truly reach a fully connected world/ singularity we have to move tech into more and more bio-computing world. I do believe QC will assist us in getting the fundamental infrastructure we need for singularity.


We already must deal with computers too much rather than too little, and there is already lots of advanced computing done also for example in materials science and nanotechnology, for example molecular dynamics (MD) and Monte Carlo simulations.[2] The molecular biologist’s programs for predicting protein folding can also count as nanotechnology. Nevertheless, all of our previous articles concluded that we need more computing, and several mentioned statistics. This would sound predictable if coming from a statistical physicist with a background in computing, advertising his skills. However, we mean a more efficient computing rather than simply more.

We started the type of computing we do only recently and for reasons not yet mentioned: Given complex nano-micro compounds, materials’ characterization is difficult due to the three-dimensional complexity of the structures. We originally integrated image analysis with simulation in order to derive 3D structure from 2D images (SEM) and projections (TEM).[3,4] The most fruitful result was however the insight into how easy it is to create adaptable software that analyzes images and keeps track of all the data, calculating anything desired such as comparisons with numerical simulations, all in one integrated system.[5,6] Many of the previously discussed issues, for example error reporting, are thereby basically already automatically solved!

Adapting software sounds prohibitively difficult: Who in my lab can modify software? Nowadays everybody! Today, programming is done partially graphically, for example with LabView™, where no programming language appears anymore. We work with Mathematica and therefore with programming code, but we mostly just download parts of code and adapt them playfully until they behave as desired. To whomever such does not count as the ability to program, we cannot program!

Continue reading “A Flexible Evolving Approach To Computing” »

Jul 8, 2016

Researchers improve catalyst efficiency for clean industries: Method reduces use of expensive platinum

Posted by in categories: nanotechnology, particle physics

Nice.


Abstract: Researchers have developed a way to use less platinum in chemical reactions commonly used in the clean energy, green chemicals, and automotive industries, according to a paper in Science.

Led by the University of New Mexico in collaboration with Washington State University, the researchers developed a unique approach for trapping platinum atoms that improves the efficiency and stability of the reactions.

Continue reading “Researchers improve catalyst efficiency for clean industries: Method reduces use of expensive platinum” »

Jul 8, 2016

New record in microwave detection

Posted by in categories: computing, nanotechnology, quantum physics

Aalto University scientists have broken the world record by fourteen fold in the energy resolution of thermal photodetection.

The record was made using a partially superconducting microwave detector. The discovery may lead to ultrasensitive cameras and accessories for the emerging quantum computer.

Artistic image of a hybrid superconductor-metal microwave detector

Continue reading “New record in microwave detection” »

Jul 7, 2016

Fantastic voyage to the nanoverse one step closer

Posted by in categories: biotech/medical, engineering, nanotechnology, particle physics, robotics/AI

Robots so small they can enter the bloodstream and perform surgeries are one step closer, a research team from Monash University has discovered.

Led by Dr Zhe Liu, the Monash Engineering team has focused on graphene oxide — which is a single atom thick — as an effective shape memory material.

Graphene has captured world scientific and industrial interest for its miracle properties, with potential applications across energy, medicine, and even biomedical nano-robots.

Continue reading “Fantastic voyage to the nanoverse one step closer” »