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Issue no. 14, 2007
Published: Apr 20, 2007 |
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 Creepy-crawly robot to mend a broken heart | | Scientists create ultra-hard material | | Mobile phones 'killing bees' | | How to find Earth's alien twin | | 'Smart dust' to explore planets | | Nanolamp lights up | | Ultrasound portraits |
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| Creepy-crawly robot to mend a broken heart |
A robot developed by researchers at Carnegie Mellon University may soon
be set loose inside the chests of heart patients. Resembling a robotic
caterpillar, it will crawl across the surface of their beating heart,
delivering treatment without the need for major surgery.
The device, called HeartLander, can be inserted using minimally invasive
keyhole surgery. Once in place, it will attach itself to the heart and
begin inching its way across the outside of the organ, injecting drugs
or attaching medical devices. In tests on live pigs, the HeartLander has
fitted pacemaker leads and injected dye into the heart.
The 20-millimetre-long robot has two suckers for feet, each pierced with
20 holes connected to a vacuum line, which hold it onto the outside of
the heart. By moving its two body segments back and forth relative to
one another it can crawl across the heart at up to 18 centimetres per
minute. This back-and-forth movement is generated by pushing and pulling
wires that run back to motors outside the patient's body. Surgeons keep
track of the device using X-ray video or a magnetic tracker, and control
its movements via a joystick. |
| New Scientist magazine
Apr 18, 2007 |
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| Scientists create ultra-hard material |
A super-hard material that is tough enough to scratch diamond could be
made cheaply and easily, according to researchers at the University of
California. The material is made from the metal rhenium and the element
boron and resembles both a metal and a crystal in structure.
Covalent bonds — strong bonds formed when atoms share their electrons —
increase a material's hardness. The researchers introduced boron atoms
between the atoms of rhenium to form short stiff covalent bonds. The
resulting material, rhenium diboride, had been made for other reasons
before, but no one realised quite how hard it was.
The material has a hardness of about 48 gigapascals (GPa). That sounds
low compared with the 70-100 GPa strength of diamond, but it is
comparable to the strength of the current second-place holder, boron
nitride. And the new material is made quite easily in the lab, under
ambient pressure. There are hints that it could be even harder than
their measurements suggest: the team found that in some circumstances it
could actually scratch diamond. That is probably because the material
seems to show a different hardness when tested from different angles. |
| Nature / Science / New Scientist
Apr 19, 2007 |
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| Mobile phones 'killing bees' |
Researchers at Langer University in Koblenz, Germany, say that mobile
phones and other radio-emitting devices could be killing bees. The study
suggests that the radio waves scramble bees' internal navigation
systems, leaving them unable to find their hives.
The study looked at Colony Collapse Disorder (CCD), a syndrome first
noticed in the US, in which colonies of bees suddenly disappear. Bee
numbers in the US have fallen by two thirds and CCD has now been seen in
Europe.
But there are other reasons for the decline in bee numbers. Increased
use of organophosphate pesticides seriously damaged European bee stocks
a decade ago, and predators and fungal infections have also been cited
as reasons for declining numbers.
Bees are vital to humans, since they pollinate over 80 per cent of the
world's crops. In many cases bees have also been domesticated to the
point where they can no longer live without human support. |
| VNUnet UK
Apr 17, 2007 |
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| How to find Earth's alien twin |
For the first time, researchers have successfully demonstrated in the
laboratory that a space telescope rigged with special masks and mirrors
could snap a photo of an Earth-like planet orbiting a nearby star. The
accomplishment marks a step forward for missions like the proposed
Terrestrial Planet Finder, designed to hunt for an Earth twin that might
harbour alien life.
Trying to see an exoplanet - a planet orbiting a star other than the sun
- is a daunting task, because its relatively dim glow is easily
overpowered by the intense glare of its much bigger, brighter parent
star. Now, NASA researchers have shown that a fairly basic coronagraph -
an instrument used to 'mask' a star's glare - paired with an adjustable
mirror, could enable a space telescope to image a distant planet 10
billion times fainter than its central star.
The study describes the system, called the High Contrast Imaging
Testbed, and how the technique could be used with a telescope in space
to see alien planets. The lab experiment used a laser as a simulated
star, with fainter copies of the star serving as 'planets'. |
| Daily Telegraph
Apr 12, 2007 |
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| 'Smart dust' to explore planets |
Tiny 'smart' devices that can be borne on the wind like dust particles
could be carried in space probes to explore other planets, according to
engineers at the University of Glasgow. Smart dust could be packed into
the nose cones of planetary probes and then released into the
atmospheres of planets, where they would be carried on the wind. For a
planet like Mars, smart dust particles would each have to be the size of
a grain of sand.
By applying a voltage to alter the shape of the polymer sheath
surrounding the chip, dust particle could be steered towards a target,
even in high winds. The polymer sheath surrounding the computer chip
could be made to wrinkle or flatten out. Wrinkling the plastic sheath
would increase the drag on the particle, lifting it higher on the wind.
Flattening out the sheath would cause the particle to plummet.
Wireless networking would allow these particles to form swarms.
Mathematical simulations have shown that a swarm of 50 dust particles
can organise themselves into a star formation, even in turbulent wind.
The ability to fly in formation would allow the processing of data to be
spread, or 'distributed' between all the chips, and a collective signal
to be beamed back to a 'mothership'. |
| BBC News
Apr 18, 2007 |
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| Nanolamp lights up |
An interdisciplinary team of researchers at Cornell University in the US
has built one of the smallest organic light-emitting devices to date.
The microscopic 'nanolamp' is made of synthetic nanofibres just 200nm
wide and could find applications in flexible electronics, which are
increasingly being made smaller, and sensors.
The fibres are made of a compound based on the metal ruthenium and are
smaller than the wavelength of light they emit. Such a localised light
source could be useful in applications ranging from sensing and
microscopy to flat-panel displays and lab-on-a-chip devices.
Using a technique called electrospinning, the researchers spun the
fibres from a mixture of the metal complex, ruthenium tris-bipyridine,
and the polymer, polyethylene oxide. The fibres emitted orange light
when excited by low voltage of about 3–4V applied through micropatterned
electrodes, rather like a tiny light bulb.
The new work shows that these light-emission devices can be made using
relatively simple fabrication methods. Compared with conventional
high-resolution lithography techniques, in which devices are attached
onto pieces of silicon, electrospinning is much simpler. |
| Nanotechweb / Nano Letters
Apr 12, 2007 |
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| Ultrasound portraits |
The first image most parents have of their baby is a grainy ultrasound
splodge that requires a remarkable stretch of the imagination to pass
for their progeny. Newer machines can produce 3D images of babies by
computing how light reflects off their features and generating the
appropriate highlights and shadows to give an impression of a 3D face.
The only trouble with these images is that they still look frighteningly
clinical and far from cute.
Siemens hopes to change all this by making 3D pictures look much better.
An ultrasound scan still takes place in the normal way but, once the 3D
shape of the baby's face has been calculated, Siemens plans to
manipulate the image to make it look more like an artist's illustration
than a photograph.
The technique works by analysing the pixels in an image and then
manipulating it in a predetermined way, like adding effects in graphics
software packages such as Photoshop, to change the overall appearance.
In this way, every parent's first image of their baby will be more
aesthetically pleasing. |
| New Scientist
Apr 16, 2007 |
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