Advanced Invention

Will the Japanese be the first to elevate to space?

One of the most promising technologies for the aspiring outer-space commuter is the space elevator. The concept, like quite a few others, was pressed into the public imagination by Arthur C. Clarke, who in his 1979 novel The Fountains of Paradise described a incredibly thin, incredibly strong carbon filament with one end anchored on Earth and the other extending up to a satellite in geostationary orbit. Now, a group of Japanese scientists are convinced that they can build a space elevator more quickly and cheaply than has been believed possible.

TOKYO (AFP) - Japanese researchers say they have developed a rubber that is able to conduct electricity well, paving the way for robots with stretchable “e-skin” that can feel heat and pressure like humans.

The material is the first in the world to solve the problems faced by metals — which are conductive but do not stretch — and rubber, which hardly transmits electricity, according to the team at the University of Tokyo.

The new technology is flexible like ordinary rubber but boasts conductivity some 570 times as high as commercially available rubbers filled with carbon particles, said the team led by Takao Someya at the university’s School of Engineering.

A New Jersey resident generates and stores all the power he needs with solar panels and hydrogen

EAST AMWELL, N.J.—Mike Strizki has not paid an electric, oil or gas bill—nor has he spent a nickel to fill up his Mercury Sable—in nearly two years. Instead, the 51-year-old civil engineer makes all the fuel he needs using a system he built in the capacious garage of his home, which employs photovoltaic (PV) panels to turn sunlight into electricity that is harnessed in turn to extract hydrogen from tap water.

Although the device cost $500,000 to construct, and it is unlikely it will ever pay off financially (even with today’s skyrocketing oil and gas prices), the civil engineer says it is priceless in terms of what it does buy: freedom from ever paying another heating or electric bill, not to mention keeping a lid on pollution, because water is its only by-product.

“The ability to make your own fuel is priceless,” says the man known as “Mr. Gadget” to his friends. He boasts a collection of hydrogen-powered and electric vehicles, including a hydrogen-run lawn mower and car (the Sable, which he redesigned and named the “Genesis”) as well as an electric racing boat, and even an electric motorcycle. “All the technology is off-the-shelf. All I’m doing is putting them together.”

“I’m a self-sufficiency guy,” he adds. Strizki, a civil engineer, has been interested in alternative energy sources since 1997 when he began working on vehicles fueled by alternative means during his tenure with the New Jersey Department of Transportation.

Strizki’s two-story colonial on an 11-acre (4.5 hectare) plot 12 miles (19 kilometers) north of Trenton is the nation’s first private hydrogen-powered house, which he now shares with his wife, two dogs and a cat. (His two daughters and son, all in their 20s, have left the nest.) It has been running entirely on electricity generated from the sun and stored hydrogen since October 2006, when Strizki—in a project that his wife Ann fully supports—built an off-grid energy system with $100,000 of his own cash and $400,000 in grants from the New Jersey Board of Public Utilities, along with technology from companies such as Sharp, Swagelok and Proton Energy Systems.

A massive neutrino observatory deep underground near Sudbury, Ontario, Canada

Some have been heralded as the largest undertakings since the building of the pyramids.

Others have been likened to a new set of wonders of the world.

From a science perspective at least, here are our picks for the largest projects on Earth: running, under construction, and on the drawing-board…

1. Large Hadron collider at CERN

Billed as the world’s largest science project, the LHC was unveiled to unearth the so-called “God particle”. Early blogs and articles surmised that the device wielded so much energy that it might create a black hole (though scientifically inaccurate, it hinted at the awesome energy waiting to be unleashed.)

Here’s how it works: Two beams of subatomic particles called ‘hadrons’ (protons or lead ions) travel in opposite directions inside the circular accelerator, picking up more and more energy with every lap. Physicists from around the world will then use the LHC to recreate the conditions found just after the Big Bang by smashing the two beams head-on at very high energy and they analysing the collisions. (more…)
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2. Next-stop, cold fusion?: The International Thermonuclear Experimental Reactor (ITER)

This first-ever demo-level fusion reactor will be built in southern France and promises to deliver the world’s first sustained fusion reactions; In layman’s terms: more bang for your buck. And at a projected cost of CDN $14.4 billion, it better.

When the eight-year construction project is complete (scheduled for late 2015), ITER will generate 500 MW of fusion power for extended periods of time.

For those not in the physics know-how, fusion is exceptionally difficult to achieve - and is the subjects of many controversial experiments. That fusion reproduces our sun’s energy, without the greenhouse gas emissions and radioactive waste of other methods.

3. The finished International Space Station, circa 2011

When completed in 2010 (though that will likely slip to 2011) the International Space Station will be the largest multinational engineering project of all time.

With an estimated final pricetag of a tenth of a trillion dollars, the finished structure - with its outstretched solar arrays - will be the size of a football field. A far cry from the Mir space station, which had interior space comparable to the space shuttle.

Though pundits have cast doubts in recent years over the ISS’s ability to perform useful science experiments, the addition of the outpost’s second major lab (the Japanese Kibo module, along with the U.S. Destiny lab) will allow a crew of 3-6 people to conduct experiments only possible from orbit that will benefit life on Earth, as well as serving as a jumping-off point for missions to the Moon and, eventually, Mars.

4. A 3,000-foot-tall “Solar tower” in the Australian outback

Dubbed the “Solar Mission Project”, this scientific feat takes solar energy to new heights.

Solar tower technology employs the sun’s radiation to heat a large body of air, which is then forced by laws of physics (hot air rises) to move in the form of a hot wind through large turbines to generate electricity.

When complete in the far western New South Wales region of the Australian outback, it will stand a full-kilometre (3,280 feet).

When fully-functioning, will generate up to 200 MW of clean emission-free electricity - enough to power about 200,000 homes.