Category Archives: Engineering

Google Computer Science Scholarship Program

United Negro College Fund (UNCF) Google Scholarship Program:

On the strength of candidates’ academic background and demonstrated leadership, we’ll be awarding $5,000 scholarships. Students must be enrolled in their junior year of undergraduate study at a UNCF Member College or University or at a participating Historically Black College or University (HBCU), and pursuing a Computer Science or Computer Engineering major.

The application deadline is October 6th. Previous posts on fellowships and scholarships in science and technology including: NSF Graduate Research Fellowship (deadline early November) and the proposal for Graduate Scholar Awards in Science, Technology, Engineering, or Math.

Engineering Jobs in Mexico

Maquila sunrise: Jobs headed back to Mexico:

What we see in Mexico today are things that have more engineering. And the reason why that is occurring is that it’s good to have your engineers in proximity to your manufacturing due to the fact that changes can be implemented much more quickly than if your center for manufacture is halfway around the world.

Today, Mexico’s pumping out more jet engines, semiconductors, and engine harnesses than its old staples like textiles and basic electronics. And that’s creating jobs for Mexican engineers inside the maquilas, like the Gulfstream Aerospace plant in Mexicali.

Read more about lean manufacturing (Toyota Production System) that values the performance improvement over short term savings on our management improvement blog. The kind of thing that allows Toyota to make a great deal of money manufacturing in the USA while Ford and GM can’t seem to do as well.
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Turning Trash into Electricity

Florida county plans to vaporize landfill trash:

The $425 million facility expected to be built in St. Lucie County will use lightning-like plasma arcs to turn trash into gas and rock-like material. It will be the first such plant in the nation operating on such a massive scale and the largest in the world.

Supporters say the process is cleaner than traditional trash incineration, though skeptics question whether the technology can meet the lofty expectations.

The 100,000-square-foot plant, slated to be operational in two years, is expected to vaporize 3,000 tons of garbage a day. County officials estimate their entire landfill — 4.3 million tons of trash collected since 1978 — will be gone in 18 years.

No byproduct will go unused, according to Geoplasma, the Atlanta-based company building and paying for the plant.

Synthetic, combustible gas produced in the process will be used to run turbines to create about 120 megawatts of electricity that will be sold back to the grid. The facility will operate on about a third of the power it generates, free from outside electricity.

Engineering Delivery Systems to the Brain

Engineering a ‘Trojan horse’ to sneak drugs into the brain by Terry Devitt:

Using engineered yeast as microscopic factories to produce human antibodies customized to recognize the surface features of cells that compose the blood-brain barrier, Shusta has developed a set of unique antibodies that may one day be used to ferry drugs to specified regions of the brain.

With roughly 400 miles of blood vessels, the human brain is equipped with its own expansive delivery network for therapy – provided scientists are able to figure out a way to get past the blood-brain barrier. With different cell surface features in different parts of the circulatory system and also in different regions of the brain, it might be possible to customize antibodies to carry drugs to only those parts of the brain that would benefit from treatment.

Related: blog posts on medical breakthroughsblog posts on heath care research

MIT’s molecular sieve advances protein research

MIT’s molecular sieve advances protein research

Separating proteins from complex biological fluids such as blood is becoming increasingly important for understanding diseases and developing new treatments. The molecular sieve developed by MIT engineers is more precise than conventional methods and has the potential to be much faster.

The key to the molecular sieve, which is made using microfabrication technology, is the uniform size of the nanopores through which proteins are separated from biological fluids. Millions of pores can be spread across a microchip the size of a thumbnail.

Juhwan Yoo, a Caltech undergraduate, also participated in the research as a summer visiting student. Funding came from the National Science Foundation, the National Institutes of Health and the Singapore-MIT Alliance.

Clean Water Filter

Clean water project hit by funding drought

Charities estimate that more than a billion people do not have access to safe drinking water. In some parts of Africa, water-borne diseases such as cholera, dysentery and viral diarrhoea claim the lives of one in four children.

The Newcastle project began after a group of postgraduate civil engineering students visited Ghana, Kenya and Malaysia and recognised the huge benefits that sustainable water filtration could have on health. One of the students, Matt Simpson, decided to devote his doctoral research project to this topic.

At these temperatures the crop residue decomposes, releasing carbon dioxide gas which forms microscopic pores in the ceramic material exactly the right size to trap bacteria and viruses but allow water to pass through.

They are looking for funding to expand the adoption of this effort.

Related: Appropriate TechnologyWater and Electricity for All – Tag

Bringing Eye Care to Thousands in India

New wireless networking system brings eye care to thousands in India

With high-speed links to the hospital, three of the clinics, also known as vision centers, screen about 1,500 patients each month. (Numbers are not yet available for the two other centers, which came online in May 2006.) Centers are run by a nurse trained in eye care. Patients first see the nurse, then spend about five minutes on a web camera consulting with an Aravind doctor. If the doctor determines that a closer examination or an operation is necessary, the patient is given a hospital appointment.

Another great example of applying technology to improve people’s lives. More on appropriate technology projects. It is great to see the focus on improving people’s lives, and using technology to do so.

Related: $100 Laptops for the WorldSafe Water Through Play

Millennium Technology Prize to Dr. Shuji Nakamura

Photo of Dr. Shuji Nakamura (from UC Santa Barbara)

The Millennium Technology Prize is a bi-annual award recognizing technology innovators created by a public private partnership in Finland. Finland understands the importance of technology advances for economic gains. Winners receive 1 million Euros. Tim Berners-Lee, the father of the web, received the first prize in 2004. The 2006 prize was awarded to Dr. Shuji Nakamura:

According to Professor Nakamura, we have only just begun to explore the vast number of opportunities presented by applications using LEDs and lasers. ”I hope the award of this prize will help people to understand that this invention makes it possible to improve quality of life for many millions of people. This is not just a source of light that makes enormous energy savings possible, it is also an innovation that can be used in the sterilisation of drinking water and for storing data in much more efficient ways.”

As LEDs can be powered by solar panels, lighting can be provided in remote areas of developing countries. In his speech, Professor Nakamura said that he will be donating part of the prize money to organizations that promote the use of LED lighting in such locations.

Related: blog posts on science and technology awardsTop prize for ‘light’ inventorUC Santa Barbara Solid State Lighting & Display CenterBlue LED Inventor Shuji Nakamura on Rewarding Innovators in Japan
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Bacteria Power Tiny Motor

Wheel of Life: Bacteria provide horsepower for tiny motor by Peter Weiss:

To make the motors, Hiratsuka’s team, led by Taro Q.P. Uyeda of the National Institute for Advanced Industrial Science and Technology in Tsukuba, Japan, borrowed fabrication techniques from the microelectronics industry.

The machinery of each motor consists of two parts: a ring-shaped groove etched into a silicon surface, and a star-shaped, six-armed rotor fabricated from silicon dioxide that’s placed on top of the circular groove. Tabs beneath the rotor arms fit loosely into the groove.

To prepare the bacterial-propulsion units, the team used a strain of the fast-crawling bacterium Mycoplasma mobile that was genetically engineered to crawl only on a carpet of certain proteins, including one called fetuin. The researchers laid down fetuin within the circular groove and coated the rotor with a protein called streptavidin.