Category Archives: Technology

International Fulbright Science and Technology Award

The International Fulbright Science and Technology award offers 25 awards for non-USA citizens to study science and engineering in the United States. The deadline for application is 1 September 2006 (though some sources give different dates): apply online. This is the first year this award has been offered.

Eligible fields include: Aeronautics and Aeronautical Engineering, Astronomy, Biology, Chemistry, Computer Science, Engineering (computer, electrical, chemical, civil, environmental, materials, mechanical, ocean, and petroleum), Environmental Science, Geology and Atmospheric Sciences, Information Sciences, Materials Science, Mathematics, Neuroscience, Oceanography, and Physics.

I can’t find any information on it on the main state department or fulbright scholar sites. But there are a number of embassy sites that mention it and an article from Barbados.

Recharge Batteries in Seconds

MIT researchers are working on battery technology based on capacitor technology and nanotechnology.

Super Battery (video also available):

Rechargable and disposable batteries use a chemical reaction to produce energy. “That’s an effective way to store a large amount of energy,” he says, “but the problem is that after many charges and discharges … the battery loses capacity to the point where the user has to discard it.”

But capacitors contain energy as an electric field of charged particles created by two metal electrodes. Capacitors charge faster and last longer than normal batteries. The problem is that storage capacity is proportional to the surface area of the battery’s electrodes, so even today’s most powerful capacitors hold 25 times less energy than similarly sized standard chemical batteries.

The researchers solved this by covering the electrodes with millions of tiny filaments called nanotubes.

This technology has broad practical possibilities, affecting any device that requires a battery. Schindall says, “Small devices such as hearing aids that could be more quickly recharged where the batteries wouldn’t wear out; up to larger devices such as automobiles where you could regeneratively re-use the energy of motion and therefore improve the energy efficiency and fuel economy.”

Previous post: MIT Energy Storage Using Carbon Nanotubes

$100 Laptops for the World

$100 Laptop from MIT OLPC project

The MIT Media Lab is developing a $100 laptop to provide affordable and appropriate technology to all parts of the world. One Laptop per Child is a non-profit created to pursue this project (which is independent of MIT).

What is the $100 Laptop, really?
The proposed $100 machine will be a Linux-based, with a dual-mode display—both a full-color, transmissive DVD mode, and a second display option that is black and white reflective and sunlight-readable at 3× the resolution. The laptop will have a 500MHz processor and 128MB of DRAM, with 500MB of Flash memory; it will not have a hard disk, but it will have four USB ports. The laptops will have wireless broadband that, among other things, allows them to work as a mesh network; each laptop will be able to talk to its nearest neighbors, creating an ad hoc, local area network. The laptops will use innovative power (including wind-up) and will be able to do most everything except store huge amounts of data.

This is another wonderful example of engineering a better world. The challenges are still large. Making such an audacious plan work will not be easy but if they pull it off the potential benefits are enormous.

UN debut for $100 laptop for poor by Jo Twist, BBC News

Our $100 laptops will run on human power, Rediff

Smokeless Stove Uses 80% Less Fuel

Philips Smokeless Stove Uses 80% Less Fuel, Saves Lives

300 million families in the world’s poorest regions burn wood for cooking, and smoke and toxic emissions kill 1.6 million people per year.

That claim in the article is disputed by a comment on the web site. The difficulty of drawing direct causation for many medical problems makes such claims difficult to prove. A scientific paper explores the issue:

Chronic pulmonary disease in rural women exposed to biomass fumes

There is little question finding engineering solutions that serve to reduce health risks are often much better than trying to deal with the health consequences after people are sick. So providing safe drinking water, for example, will do more for health than increase spending on medical care to treat those who get sick.

Additionally the opportunities to save lives and improve health in the world often do not require cutting edge science. It is often a matter of engineering effective solutions for hundreds of millions and billions of people living without what those in the wealthy take for granted (Water and Electricity for AllSolar Powered Hearing AidAppropriate Technology).

10 Things That Will Change The Way We Live

Forbes offers a list of 10 Things That Will Change The Way We Live. Of the items 9 of 10 seem directly related to science and engineering, such as: Fuel Cells, Gene Therapy, WiMAX. The only one that doesn’t seem directly related to science and engineering is $200 a barrel oil. But even there the effect of such an future would largely depend on science and engineering solutions that would be created in such a future.

Spray-On Solar-Power Cells

Spray-On Solar-Power Cells Are True Breakthrough by Stefan Lovgren for National Geographic News:

The plastic material uses nanotechnology and contains the first solar cells able to harness the sun’s invisible, infrared rays. The breakthrough has led theorists to predict that plastic solar cells could one day become five times more efficient than current solar cell technology.

At a current cost of 25 to 50 cents per kilowatt-hour, solar power is significantly more expensive than conventional electrical power for residences. Average U.S. residential power prices are less than ten cents per kilowatt-hour, according to experts.

But that could change with the new material.

“Flexible, roller-processed solar cells have the potential to turn the sun’s power into a clean, green, convenient source of energy,” said John Wolfe, a nanotechnology venture capital investor at Lux Capital in New York City.

Concentrating Solar Collector wins UW-Madison Engineering Innovation Award

Solar Collector

An inexpensive, modular solar-energy technology that could be used to heat water and generate electricity (see photo) won $12,500 and took first place in both the Schoofs Prize for Creativity and Tong Prototype Prize competitions, held Feb. 9 and 10 during Innovation Days on the UW-Madison College of Engineering campus.

In a package about the size of a small computer desk, the winning system uses a flat Fresnel lens to collect the sun’s energy and focus it onto a copper block. Then a unique spray system removes the energy from the copper block and converts it into steam, says inventor Angie Franzke, an engineering mechanics and astronautics senior from Omro, Wisconsin. The steam either heats water for household use or powers a turbine to generate electricity.

Other 2006 Schoofs Prize for Creativity winners include:

* Second place and $7,000 — William Gregory Knowles, for the OmniPresent Community-Based Response Network, a personal, business or industrial security system that draws on networked users and devices to more efficiently verify burglar alarms, fire alarms or medical emergencies.
* Third place and $4,000 — Garret Fitzpatrick, Jon Oiler, Angie Franzke, Peter Kohlhepp and Greg Hoell for the Self-Leveling Wheelchair Tray, a stowable working surface for wheelchairs that self-levels, even when the wheelchair is tilted or reclined up to a 45-degree angle.

Read more about the 2006 competition

MIT Energy Storage Using Carbon Nanotubes

Images of different types of carbon nanotubes

MIT Researchers Fired up Over New Battery

Image / Michael Ströck, Images of different types of carbon nanotubes. Carbon nanotubes are key to MIT researchers’ efforts to improve on an energy storage device called an ultracapacitor. Larger image

Work at MIT’s Laboratory for Electromagnetic and Electronic Systems (LEES) holds out the promise of the first technologically significant and economically viable alternative to conventional batteries in more than 200 years.

The LEES ultracapacitor has the capacity to overcome this energy limitation by using vertically aligned, single-wall carbon nanotubes — one thirty-thousandth the diameter of a human hair and 100,000 times as long as they are wide. How does it work? Storage capacity in an ultracapacitor is proportional to the surface area of the electrodes. Today’s ultracapacitors use electrodes made of activated carbon, which is extremely porous and therefore has a very large surface area. However, the pores in the carbon are irregular in size and shape, which reduces efficiency. The vertically aligned nanotubes in the LEES ultracapacitor have a regular shape, and a size that is only several atomic diameters in width. The result is a significantly more effective surface area, which equates to significantly increased storage capacity.

Solar Powered Hearing Aid

Solar Hearing Aid
African-Made, Solar-Powered Hearing Aid

The SolarAid is a hearing aid designed and built by Godisa Technologies, a Botswana company founded to make low-cost hearing aids for the developing world. The SolarAid system combines a small hearing aid and a lightweight solar charger; Godisa developed the first No. 13 rechargeable button battery for the system. Godisa is Africa’s only hearing aid manufacturer, and the only one in the world making hearing aids specifically for the sub-Saharan Africa environment.

Innovation through creating effective solutions using technology solutions that have existed in other contexts can have huge impacts. Appropriate technology solutions offer the opportunity for great gains for humanity.

Related posts:

Self-Assembling Cubes Could Deliver Medicine

Nanocubes photos

Tiny Self-Assembling Cubes Could Carry Medicine, Cell Therapy – News Release from Johns Hopkins (pdf format)

Details of photos: “Scanning electron microscopy images of image of (A) a hollow, open surfaced, biocontainer, and (B) a device loaded with glass microbeads. (C) Fluorescence microscopy images of a biocontainer loaded with cell-ECM-agarose with the cell viability stain, Calcein-AM. (D) Release of viable cells from the biocontainer.”

Johns Hopkins researchers have devised a self- assembling cube-shaped perforated container, no larger than a dust speck, that could serve as a delivery system for medications and cell therapy.

When the process is completed, they form a perforated cube. When the solution is cooled, the solder hardens again, and the containers remain in their box-like shape.

“To make sure it folds itself exactly into a cube, we have to engineer the hinges very precisely,” Gracias said. “The self-assembly technique allows us to make a large number of these microcontainers at the same time and at a relatively low cost.”

Gracias and his colleagues used micropipettes to insert into the cubes a suspension containing microbeads that are commonly used in cell therapy. The lab team showed that these beads could be released from the cubes through agitation. The researchers also inserted human cells, similar to the type used in medical therapy, into the cubes. A positive stain test showed that these cells remained alive in the microcontainers and could easily be released.

And they are “always on the lookout for exceptional and highly creative undergraduate, graduate students and post-doctoral candidates” – maybe you.