Great teacher thrives in unique habitat

The journal Science is publishing biologist Nitya Jacob's paper "Investigating Arabia Mountain: A Molecular Approach" so that other teachers can emulate her methods. Photo by Kay Hinton.

By Carol Clark

A favorite biology professor introduced Nitya Jacob to Arabia Mountain when she was a student at Agnes Scott College. Sandra Bowden took her botany class on field trips to the Georgia granite outcrop.

“I remember thinking how weird and otherworldly the outcrop looked, with strange plants, unique to that habitat,” Jacob says. “I loved getting to see these plants in the wild that I had been learning about.”

Now Jacob is an assistant professor of biology at Emory’s Oxford College, introducing a new generation of students to Arabia Mountain. She developed a lab module that trains freshmen and sophomores to collect samples on the outcrop, then investigate microbial diversity through DNA isolation and sequencing.

“I want my students to be aware of their biological surroundings,” Jacob says. “It’s so easy to go about life without ever thinking about what’s around you.”

The popular lab module, which Jacob has been teaching and refining for six years, is one of only 15 winners nationwide of the 2011 Science Prize for Inquiry-Based Instruction. The journal Science is publishing Jacob’s paper, “Investigating Arabia Mountain: A Molecular Approach,” in its next issue, so that other science teachers can emulate her methods.

“I always had this dream of publishing in Science, like a lot of scientists do,” Jacob says. “But when I decided to focus on teaching, I thought, ‘There goes any chance of seeing my name in Science.’ I’m just blown away by this.”

Jacob's favorite tree growing up was the gulmohar, Hindi for "peacock flower." In English, the tree is known as Royal Poinsetta. Photo by Nitya Jacob.

Jacob grew up in India, in a small town near Pune. Her mother was a professor of English and linguistics, and her father was a professor of psychology and philosophy of religion. But Jacob was fascinated by nature from an early age.

“We had a big yard and I was always surrounded by plants and animals,” she says. “My favorite tree was a gulmohar. It was easy to climb, and it has these fascinating red flowers. Four of the petals are plain red, and one has a white and yellow pattern. It also produced these long seed pods that I could use as a ‘sword.’”

Jacob came to Georgia to attend Agnes Scott College, where she majored in biology. While Sandra Bowden mentored Jacob in biology, chemistry professor Linda Hodges involved her in lab research. “We were isolating compounds from plant extracts to test their anti-glaucoma activity,” Jacob says. “I felt really inspired by getting to do real science.”

The classroom turned out to be Jacob’s true passion, something she realized as a post-doc in Illinois. “I find myself happiest when I’m around students,” she says. “They have a certain kind of energy and an eagerness to learn.”

Oxford students gather microbial samples from Arabia Mountain. While the plants and geology of the granite outcrop have been studied in detail, its microbes have not. Photo by Nitya Jacob.

She found the perfect fit as a teacher at Oxford College, which has easy access to forests, the Oxhouse Science Center and the Arabia Mountain National Heritage Area. The mountain is a monadnock, an exposed granite rock, rising nearly 200 feet above the piedmont. Sandy hollows in the granite surface fill with rain water and turn into vernal pools, harboring an array of unusual plants, like the bright-red diamorpha and the endangered fleshy-leafed little amphianthus, and isoetes melanospora – better known as black-spored Merlin’s grass.

These quirky survivors have adapted to extreme heat and drought conditions. “They are truly living on the edge, in this very specific habitat,” Jacob says.

That got her wondering: What unseen life could the outcrop be harboring? While the plants and geology of Arabia Mountain have been studied in detail, its microbes have not.

Jacob’s curiosity, and her desire to inspire students the way her own professors did, led her to work Arabia Mountain into curriculum of Biology 142. She drew on the experience of her colleague, Oxford biologist Eloise Carter, who co-wrote a field guide to granite outcrops.

Working in teams, the students design an original research question about investigating microbial diversity on a granite outcrop. They gather microbial samples in the field, from pools, leaf surfaces, rocks and soil, then grow cultures back in the lab.

First they look for visual differences in the bacterial colonies, which can have different colors, shapes and surface features. The students have isolated two types of bacteria that are purple, for instance, which they have so far collected only from wet or damp environments.

Jacob helps students analyze their data in the lab. Photo by Kay Hinton.

The research teams select morphologically distinct bacteria from their collections and use a polymerase chain reaction (PCR) technique to amplify the DNA sequence. They further analyze, examine and synthesize the data, looking for patterns in different bacteria from different collection areas. They discuss their outcomes and make arguments, before presenting their findings in a research seminar format.

“I loved that class,” says Susanna Brantley, who took it as a freshman and is now a junior majoring in biology at Emory. “It was a real research project and not a so-called ‘cookbook’ science class. I was learning something, but also doing something meaningful, maybe even contributing to new scientific knowledge.”

The students have made several interesting discoveries. “Some of the bacteria we’ve found has apparently never been identified,” Jacob says. “When you put the DNA into the database and look for a match, there isn’t one.”

Studying bacterial diversity, and how it adapts to different environments, could help solve human problems of pollution, energy and health.

"I want my students to be aware of their biological surroundings," Jacob says. Photo by Carol Clark.

Rachel Koval, who took Jacob’s class in 2006, is working on a masters in public health at the University of Michigan. One of her projects involves looking at microbiological diversity in diarrheal diseases in Peru, to learn more about how the disease has changed as the environment has changed.

“When you learn how microbes adapt to different settings, it can give you a better idea of how natural selection can work,” says Koval, who remains in close touch with Jacob.

Jacob is slight, soft-spoken and preternaturally calm, yet exudes a quiet power. She did not hesitate to use it by politely admonishing a visitor to Arabia Mountain who was trampling an endangered plant while taking a photo.

“My students were really outraged about that and they came to me and asked me to do something,” she recalls. “That’s when I realized that what they are learning is sinking in, and it’s important to them.”

On a recent outing to Arabia, on a sunny day with a cool breeze, students scattered over the face of the outcrop. They called out to Jacob if they saw a plant that was new to them, or found something interesting swimming in a vernal pool.

“I’ve been doing this for years,” Jacob says, “but every time I bring students here they have big smiles on their faces, and that makes it all seem new to me again.”

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Proving math is good for endurance sports

Theoretical math and endurance exercise go together like paper and pencil, says Ken Ono, above. "Each activity makes me better at the other."

By Carol Clark

Some people run from their problems. Emory math professor Ken Ono runs with his.

“I do the bulk of my creative research when I’m outdoors, running or cycling, and free of other obligations,” says Ono, who studies long-standing problems in number theory. “Exercise clears my mind. That’s when I can really get down to the nature of a problem.”

While Ono’s mind is getting down to math, his heart is getting pumped up. At 44, he has been named to Team USA for his age group by the USA Triathlon Federation. On May 19, Ono will be competing in the 2012 International Triathlon Union Cross Triathlon World Championships in Pelham, Alabama.

“I’m not going to win,” Ono says, calculating his odds, “but I’m excited to compete against the best in the world, wearing the red-white-and-blue.”

Set in Alabama’s Oak Mountain State Park, the triathlon involves a 1,500-meter swim across a lake, a 19-mile mountain-biking trail and a 10-kilometer cross-country run.

“Maybe it was a mid-life crisis,” Ono says, when asked what possessed him to try out for a spot in the competition last year, his first triathlon. “Some people buy sports cars.”

Ono qualified for the national team by performing well in off-road triathlon and trail runs known as the XTERRA series. Last year he ranked 14th for his age group in the Southeast region.

He quickly improved. Over spring break, Ono competed in an XTERRA national event in Miami. He is now ranked third in his age group nationally.

"I do the bulk of my creative research when I'm outdoors, running or cycling, and free of other obligations," Ono says.

Ono is a seasoned athlete. While an undergraduate at the University or Chicago, he was a nationally ranked cyclist for the Pepsi-Miyata team, competing in the U.S. Professional Cycling Championships.

Now married and the father of two, Ono stays active in solo sports like surfing, running and cycling. He also enjoys hiking. Last year, he and a colleague made an important discovery about partition numbers while they were hiking in a north Georgia forest. As they made their way to a waterfall, they noticed patterns in the trees that helped them see a centuries-old problem in a new way.

“Nature guided us to one, crystal-clear, important idea,” Ono says.

Theoretical math and endurance exercise go together like paper and pencil, says Ono: “Each activity makes me better at the other.”

In the lead up to the triathlon world championship, he’s training three hours a day. The grueling workouts might seem unbearably long, but Ono’s mind is busy with collections of math problems.

“I especially love running in the woods,” he says. “When I’m alone with my thoughts, just me and the sounds of birds and a stream, it gives me clarity and focus. On those rare occasions that you hit upon an idea to prove a theorem that you’ve been struggling with, it’s a rush, like a runner’s high.”

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A field botanist's take on the pollen blitz

By Carol Clark

The first day of spring was more like summer at Emory’s Oxford College campus, 40 minutes east of Atlanta. It was the seventh straight day of highs above 80 degrees, breaking the March record for an unbroken stretch of such high heat in the Atlanta region.

Biology professor Eloise Carter and students in her field botany course returned to the lab from a trip to nearby Oxhouse Lake, sweaty and dusted in pollen. As the students laid out specimens of flowering plants they collected, Carter brought out her iPhone to show photos to another biologist in the department.

“It’s pollen,” she says, showing what looked like a sandy beach, but was actually tree pollen coating the surface of the water along the lake shore.

The count of 9,369 particles of pollen per cubic meter of air on Tuesday was 55 percent higher than the previous record, set in 1999. A mild winter, leading up to a hot spring, has blown back the clock, driving the blitz of allergens from trees that are pollinated by wind.

Instead of tree pollination extending as usual from February to May, “it’s been telescoped down,” Carter says. “It’s pretty extreme.”

Carter, who has been leading students on biology outings since 1988, has been collecting data for 25 years on what plants flower when around Oxford, Georgia.

The loblolly and short leaf pines are shedding pollen now, on their usual schedule. But flowering that is usually spread out over a month for 10 different varieties of oak has been collapsed to the past few days, she notes. Mulberries, box elders, sweet gums, birch and sycamore are also currently in the mix.

“I’m wondering what’s going to happen downstream from now,” Carter says. Late in the semester, will there be any flowering plants left for her field botany students to collect? Perhaps plants that normally flower in the summer will blossom and fill the spring void, she speculates.

Plants decide when to flower based on the length of day and the temperature. “While plants may respond to temperature changes, insects may or may not,” Carter says. “If you get a real disconnect between plants and their pollinators that may affect the reproduction of rare plants, agriculture plants and others. Plants living on the fringe of their range might even be eliminated.”

Top photo by iStockphoto.com.

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Bluebirds egg on spring

A glorious, blue egg appeared on this first day of spring in a bluebird nest on the quadrangle of Emory's Oxford Campus. The proud parents are busily flitting about amid the oaks and ornamental pear trees. "They just finished building their nest," says Oxford biologist Eloise Carter, who installed a wooden bluebird box just outside of her office. Last year, two clutches of birds were raised in the little box.

If you want to attract bluebirds to your yard, Carter recommends buying a special bluebird house for them, with the right sized opening. "It's best to put the house up in February, because then the bluebirds have time to shop around for a home, but you probably still have time to attract some this season," she says.

Add water and a feeding station. "They especially love mealworms," Carter says. "The birds will see, 'What a great neighborhood, it's got food and it's safe,' and they'll move in."

How culture shaped a mathematician

"I like to connect abstract math with things that are really concrete," says Skip Garibaldi. Photo by Bryan Meltz.

By Carol Clark

As a graduate student, Emory math professor Skip Garibaldi visited the Orangerie Museum near Paris. He and a friend, a fellow mathematician, were transfixed upon entering one of the museum’s galleries. But it wasn’t the stunning mural of Claude Monet water lilies that grabbed their attention.

“I said, ‘It’s a whispering chamber!’ And we immediately ran to opposite ends of this oval room and began having a conversation,” Garibaldi recalls.

No plaque identified the whispering phenomenon. But the mathematicians recognized the geometry of ellipses that allow sound waves to travel around walls without getting much quieter.

Here’s what a non-mathematician would probably first notice upon entering the Monet gallery:

Source: Wikipedia Commons.


Here’s a diagram of what caught Garibaldi's attention:



Now Garibaldi is himself part of a museum exhibit that opened this month at the Smithsonian Institution. “MathAlive!” aims to reveal the beauty of math to middle and elementary school students, by showing it through the eyes of hip young engineers, designers, urban planners, athletes and others who use math in their work and play.

“A lot of good things are going on right now to help get kids interested in math,” Garibaldi says, from the Khan Academy phenomenon to the Museum of Mathematics opening this week in New York. “That’s great, because technology is integrated into everything we do today, and if you want any kind of career in technology, engineering or science, math is the gateway.”

The interactive MathAlive! exhibit combines math with virtual reality to let visitors do things like design a skateboard, and then test it out to see how it works, or operate a robotic rover to pick up samples from the surface of Mars.

Garibaldi, who is an avid rock climber, inspired an actual climbing wall at the exhibit.

Watch a "fly-through" of MathAlive! in the video below. The traveling exhibit is a collaboration of the Raytheon Company, NASA, the National Council of Teachers of Mathematics and others. In addition to the Smithsonian, MathAlive! will travel to the Arizona Museum and the U.S. Space and Rocket Center in Huntsville, Alabama.



The philosophy behind MathAlive! is that one way to get kids interested in a subject is to find a way to make it fun and cool.

Popular books and movies guided his own meandering trail through academia, says Garibaldi, who grew up in semi-rural Fairfield, California, on the edge of the Central Valley.

Garibaldi became fascinated by physics after an uncle gave him a copy of “The Cosmic Code” by Heinz Pagels, a physicist and mountain climber who had a gift for explaining complex topics in ways that were both gripping and easy to understand.

Here’s how Pagels wrote about cosmology in the 1982 book:

“Lately I dreamed I was clutching at the face of a rock but it would not hold. Gravel gave way. I grasped for a shrub, but it pulled loose, and in cold terror I fell into the abyss ... what I embody, the principle of life, cannot be destroyed ... It is written into the cosmic code, the order of the universe. As I continued to fall in the dark void, embraced by the vault of the heavens, I sang to the beauty of the stars and made my peace with the darkness.”

Credit: EE One/Wikipedia Commons.

Pagels was a larger-than-life figure who embodied what he wrote. In 1988, he died while climbing Colorado’s Pyramid Peak (above), in an accident that was eerily similar to his dream.

Another book that influenced Garibaldi was “Surely, You’re Joking, Mr. Feynman: The Adventures of a Curious Character.” This classic memoir by Nobel Prize-winning physicist Richard Feynman covers everything from safecracking to meeting Albert Einstein.

“It’s got real science in it, but it’s also fun,” Garibaldi says. “If you’re a geeky kid and you read that book, it would be really hard not to have Feynman as a hero.”

By the time he was a sophomore in high school, Garibaldi had taken most of the math and science courses offered in the vicinity of his small town. So he decided to skip the rest of high school and apply to college. He enrolled at Purdue.

“Looking back on it, it seems like a crazy idea,” Garibaldi says, “but it didn’t seem strange at the time.” He explains that he had recently seen the movie “Real Genius,” starring Val Kilmer as one of the youngest students ever accepted to study physics at CalTech, where he and a roommate develop a high-powered laser.

Although he enjoyed the theoretical aspects of physics, Garibaldi says he didn’t like working in a lab. He switched his major to computer science in his junior year at Purdue, but once again hit a wall.

“I had spent a lot of time programming, going back to 7th grade, and I was getting tired of being in front of a computer screen under fluorescent lights,” he says. “I just don’t like being encased in a room.”

Garibaldi went on to a PhD program for math at the University of California at San Diego. “One advantage of math is you can do it yourself, anywhere, even at the beach,” Garibaldi says. “All you need is a pencil and paper, or sometimes, not even that.”

As he immersed himself in becoming a theoretical mathematician, he discovered a twin passion: Rock climbing.

Garibaldi climbing Desert Reality in Red Rock Canyon National Conservation Area near Las Vegas. Photo by Craig Clarence.

Precision is key to both scaling a mountain safely and finding the solution hidden in a maze of equations, he says. “They both involve puzzle solving. And they both require close attention. You tune out everything else. You get taken away from the every day.”

While in San Diego, and later during a post-doctoral position at UCLA, Garibaldi continued to hone his climbing skills. “When you’re climbing you have a lot of adrenaline and focus, and that affects what you remember,” he says. “I did hundreds of climbs in Joshua Tree National Park, and my memories of each one of them are intense because of the focus that I had while doing them.”

Garibaldi met his wife, Julia, a fellow mathematician, while at UCLA, and the couple moved to Atlanta in 2002 when he joined the Emory faculty. The math department was seeing a rise in enrollment, which Garibaldi thinks may have been at least partly due to more appearances of math in popular culture, like the movie “A Beautiful Mind.” Russell Crowe (left) played real-life mathematician John Nash in the hit movie, which won the 2002 Oscar for best picture.

As a theoretical mathematician, Garibaldi grapples with esoteric subjects, like cohomological invariants and an enigmatic structure known as E8. But he also strives to help non-mathematicians see the world of numbers as he does. He wrote a paper called “Finding Good Bets in the Lottery – And Why You Shouldn’t Take Them” and a computer program that allows people to rearrange the stars in the U.S. flag. He also starred in a popular YouTube video called “The Math of Rock Climbing.”

“Pure math is, to a great degree, separated from reality. So whenever possible, I like to connect really abstract math with things that are concrete and make it publicly accessible,” Garibaldi says. “When I’m teaching, I show students how the math in cryptology applies to their computers, and how the math of finance can be used to analyze whether the market is pricing something correctly.”

Garibaldi says that his greatest ambition is not to solve a major mystery in math or science, but to help young people sense the beauty and wonder inherent in those mysteries. “I have two young kids,” Garibaldi says. “I want to write a popular book on science that someday they will find just as compelling as Heinz Pagels’ and Richard Feynman’s books were to me.”

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