Tuesday January 11, 2005 news@michigandaily.com SCIENCE 5 v ZERO-GRAVITY ZONE Two teams prepare experiments for weightless environment By Kingson Man Daily Staff Reporter Furnace Exhaust Fuel Distribution1 es even .... t Air Distribution Pipe [ncrease ~ ZI efficiency Creati comb 5 y by ustion *1 it yr __ Pi The next time you receive a shot at the doctor's office, pay close atten- tion to how the syringe is handled. Immediate- ly before an injection, the needle is pointed upwards, tapped with a finger and some of the fluid is ejected before it is inserted into the body. Any air bubbles, or embolisms, that rise to the top and are removed from the needle. This is a crucial step in administering shots, as embolisms inside the bloodstream can travel to the heart or the brain and cause death. For astronauts in space, however, there is no gravity and there is no "up" - so how can they receive shots safely? This past December, NASA announced that two groups of under- graduates from the throughout furnace by recirculating byproducts T r r r 0 &Inbus Y Y I A A producing large amount of heat and radiation, reducing energy loss by up to 50% H Intense uniform radiation up Ob e ts Hetd yr aeted RAPH LINDSEY UNGAR The new furnace developed by the Mechanical Engineering Department may be a huge industrial advancement since it reuses the byproducts created from the combustion process, decreasing its pollution output and allowing it to operate with less energy than normal furnaces. New furnace to alter method of combustion COURTESY OF NASA The KC-135 or 'Vomit Comit' begins a parabolic arc to create the effect of weightlessness. The teams of students will fly the C-9, a smaller aircraft that performs the same maneuver. University had been selected from a pool of applicants to enroll in "Microgravity University," or the Reduced Gravity Student Flight Opportunities Program. Both teams will travel to Houston's Johnson Space Center in July to perform experiments in a zero-gravity environment. One of the groups will experiment with removing embolisms from needles; the other will study the dynamics of fluid droplets. Engineering seniors Laura Gadzala, Andy Klesh, Rene Kreis, Jeff Lance and junior Nick Shoeps make up the group of students who will investigate how to make needles safer in space. The intrepid group of microgravity researchers will board a C-9 aircraft that will fly steep parabolic arcs up and down over the Gulf of Mexico, creating half- minute intervals of weightlessness. Their plan is to spin syringes pre-load- ed with air bubbles in a centrifuge. This creates artificial gravity in the syringes because the acceleration, due to the spin- ning, simulates the effects of gravity. Due to the zero-gravity environment, the sharp needles themselves will be removed prior to flying, leaving the syring- es, or the barrels containing the fluid, to be spun. The heavier fluid will sink and the lighter bubbles will be pushed up. "Artificial gravity pushes bubbles to the end so they can be removed," Gadzala explained. With NASA's latest goal of human exploration on Mars, the duration of space missions will be measured on the scale of years instead of weeks or months. In the ever-more likely possibility of a medical situation requiring needles in space, this research has the potential to deliver safe injections to astronauts. In previous years, the KC-135 air- craft, affectionately known as the "Vomit Comet," was used to create the weight- less environment. The KC-135 has flown 80,000 parabolas, some of the most well- known of which have been used to film scenes of the movie "Apollo 13." This year the smaller C-9 will be flown, reducing the 70 student groups usually selected to do research down. to 50. In addition to the air embolism group, the University will be send- ing a team investigating a different aspect of fluid dynamics. Aerospace engineering undergraduates Jamal Al- Amin, Robin Lin, Jeffrey Medlen and William Stoddard will be video-tap- ing the action of spinning droplets in a microgravity setting. The experiment will set a droplet of liquid spinning at different speeds to mea- sure the changes in shape of the droplet in zero- gravity. As a spherical object spins, its shape tends to flatten outwards - spin it fast enough, and it will split into two. Even the rotating Earth exhibits this behav- ior, as it is slightly thicker around the equator than at the poles, resembling an M&M. Under normal conditions, however, it is difficult to study a spinning drop- let free of other influences. A weight- less drop of liquid in space is a sphere, but on Earth its shape deforms to a teardrop. The group plans to experiment with a variety of liquids at different speeds, examining the degree of shape-shift- ing in relation to the viscosity, or stickiness, of different liquids. This research may help scientists under- stand the shapes and spins of asteroids. And on Earth, it may improve process- es that require forming spheres, like the manufacture of ball bearings. For all the possible practical impli- cations of both groups' subjects of study, the members are finding it a daunting task to raise funds to support their trip to Houston. A majority of both groups' budgets of several thou- sand dollars will be spent simply get- ting themselves and their equipment there. The Engineering College's Wil- son Student Project Center provided some financial support to the groups. NASA will provide the flight opportu- nity, which is itself no small contribution - private aviation companies are now starting to offer similar microgravity trips for $80,000 per flight. It was this opportunity that first piqued the interest of the selected undergraduates, even before they had a project idea in mind. "I've had friends do the NASA project before and I can remember being jealous ... the only real hard part was finding a project idea," said Al-Amin. Gadzala, of the air embolism group, agreed. "Roller coasters will be so lame after this." Energy-saving furnace aims to help environment By Philip Svabik For the Daily While energy costs continue to soar domestically and abroad, mechanical engineering Prof. Arvind Atreya and his team of colleagues and students are pioneering a revolutionary new method of combus- tion that has the potential to save American indus- tries billions of dollars in energy costs each year. Though many researchers are working on alter- native energy sources for the future such as hydro- gen power, Atreya's new concept could save money and reduce pollution by simply using existing fuels more efficiently. "We use a lot of energy in manufacturing. That may be going down, but we still use a lot," Atreya said. "This creates two problems: One is that it costs a lot, and the second, and more important problem in my mind, is that it causes a lot of greenhouse gases," he added. Traditional industrial furnaces burn fossil fuels in order to create heat, often used for melting dif- ferent metals such as steel. The main problem with traditional furnaces is that over 40 percent of the heat escapes, wasted as exhaust. Atreya thinks he may have the solution. Called radiative homogeneous combustion, this innovative technique improves upon tradi- tional industrial furnaces by creating even com- bustion throughout the furnace and recirculating byproducts, which increases efficiency by pro- ducing a tremendous amount of heat and radia- tion. This method can reduce energy loss by 50 percent, Atreya said. Along with his team, Atreya recently built a ceramic radiative homogeneous combustion fur- nace for experimental purposes. The furnace is housed in the Francois-Xavier Bagnaoud Build- ing on North Campus. In a traditional industrial furnace, combustion only occurs where the fuel and air meet inside the furnace and the leftover byproducts quickly escape as exhaust. These, byproducts typically include pollutants like soot, nitrogen oxides and carbon dioxide. However, in a radiative homogeneous combus- tion furnace, the entire volume of fuel and air within the furnace burns at once and recirculates instead of leaving immediately as exhaust. Burning the entire volume at once helps to burn up many pollutants. This hot gas volume that is formed also helps the heat radiate more effectively. The exhaust eventually exits by passing over unheated fuel and air lines. Heating the fuel and air prior to entering the furnace helps to further recover heat. Atreya said another secret to the efficiency of homogeneous combustion is the spacing of the nozzles that release the air and fuel into the furnace. As the two substances enter, their tem- peratures rise as they mix with the recirculating byproducts. The fuel initially begins to form soot. The fuel and air then homogeneously mix together, burning all of the soot in an immense- ly radiative flame. Atreya filed last year for a U.S. patent for the furnace on behalf of the University. He is currently conducting experiments in an effort to make the homogeneous combustion concept a reality. Atreya said he is determined to make it work. "The important thing, in my mind, is if we can get this actually demonstrated, measured, and pub- lished, then I have some industry people who are interested in this, and they can come here and see the results," he said. "Then there is the possibility of us continuing on a much bigger scale," Atreya added. To bring the concept into practical use, Atreya still must research and be able to prove it works. "What we need to do is understand at what rate we should send the fuel, at what rate we should send the air, what should be the difference between the two such that the homogeneous combustion occurs with the proper site. These are the variables that we are trying to understand," Atreya said. The underlying principles of homogeneous combustion can be applied to industries other than manufacturing. Atreya said he speculates that homogeneous combustion could also be used in boilers for the production of electricity. Currently, the automotive industry is research- ing this concept in what the industry calls "homogeneous compression charge ignition." The aim is to highly compress well-mixed fuel in the cylinder of the car so that it auto-ignites without the need of a spark - consequently burning homogeneously, increasing efficiency and decreasing pollutants. For Atreya, the development of fuel-efficient manufacturing comes at a critical time because he believes the planet is on the verge of facing an envi- ronmental crisis. "This is what is left (of our fossil fuels): about 48 years of oil, about 50 years of natural gas, and about a couple hundred years of coal," Atreya said. "People say don't worry, we will do nuclear, but there is only about 70 years of uranium left. It's a shame because nobody worries about it. Everybody is trying to burn coal now because it is cheaper." Atreya said evidence gathered from ice core samples in Antarctica shows cyclic carbon diox- ide levels over the last 400,000 years cycling between concentrations of 180 and 280 parts per million. But today, carbon dioxide concentration levels are at 360 ppm and expected to reach 720 ppm by 2100, according to the Intergovernmental Panel on Climate Change. As a result of increased carbon dioxide levels, Atreya said by that time the earth's average temperature is expected to increase four or five degrees Celsius. These predictions for the future fuel Atreya's passion for researching more environmentally friendly methods of combustion. "I am much more interested in making this a great success because of more of my personal rea- sons than any other reason," he said. "I want it to be adopted not so much for the patent, but for totally different reasons. I want it to be my little contribu- tion to saving energy." DAVIDTUIMN/LDily Aerospace engineering seniors Andy Klesh, Rene Kreis and Laura Gadzaia prepare their project on how to make needles safer in space for NASA's C-9 microgravity experiment platform. Marshall Scholar winner tackles dark matter mystery By Brandon McNaughton For the Daily Have you ever sat up all night contem- plating the mysteries of the universe or the perplexities of nature? LSA senior Jacob Bourjaily frequently does. In fact, Bourjaily stays up all night, every other night - and these all-nighters paid off when late last year he was announced as a recipient of the 2005 Marshall Scholarship, a prestigious annual award given to forty American college graduates for their high academic achievements. For Bourjaily, it was in part due to his extensive work in physics and math at the University, which earned him the award. But while receiving the Marshall Scholarship was a great honor, Bourjaily is hoping he can sur- pass that achievement by attempting to solve the great mystery of dark matter. Unlike ordinary matter, dark matter can- not be seen, but its existence is suggested by its gravitational effects. Bourjaily, who has become the only undergraduate associate member of the University's Michigan Center for Theoreti- cal Physics, researches this phenomena with Physics Prof. Gordon Kane. In regards to dark matter, Bourjaily said "It's not bricks; it's not planets; it's not cold stars; it's really something else." "About 85 percent of all the matter in the universe is unlike any of the matter we have ever observed." - Jacob Bourjaily LSA senior and 2005 Marshall Scholar near future.... If they are, we want to know how much of the dark matter they account for," Bour- jaily said, since other particles may be responsible for the properties of dark matter. Bourjaily has already begun to establish himself as a theoretical physicist. He pre- higher. The recipients must choose to attend a University in the United Kingdom. Bourjaily, now 20, grew up in Grand Rapids, Michigan and is the fifth generation of his fam- ily to attend the University. He decided to major in physics while taking courses at Calvin College ~-- 3 1 I ,