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Current
Articles, Interviews and Commentary
from
Education Week, February 23, 2005
Unlearning Bad
Science
by John
Merrow |
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illustration
by Patti Raine |
The news of the
so-so performance in science by American students on the latest TIMSS
assessment will be used by some to accelerate the expansion of the
No Child Left Behind Act. But that federal law's mandate for more
science testing may actually make matters worse. It could lead to
more rote teaching of material that's easy to test on multiple-choice
exams. It could lead to "dumbing down" the science curriculum,
which will drive competent teachers either to distraction or to other
occupations.
The larger picture isn't much brighter. Congress has slashed funds
that the National Science Foundation uses to improve science teaching,
ever larger numbers of school districts are embracing "creation
science" (typically under the guise of "intelligent design"),
and, in the name of national security, the Bush administration is
turning away bright foreign students who want to study science at
our universities. All of this is obscuring what may be a greater challenge-
unlearning bad science.
| Despite
superficial textbooks, rote teaching, and a shortage
of project-based learning, there is hope for science
education. |
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Teacher Scott Byington
likes to ask his science students at Cary Academy in North Carolina
which organism has the most chromosomes per cell: mosquitoes, corn,
broad beans, cats, or humans? The kids always pick humans, and they
are correct, because we have 46 chromosomes, while cats have 38 and
mosquitoes only 6. Then Byington. expands the list to include horses,
chickens, goldfish, and potatoes. Once again, his students confidently
choose their own species. At that point, he tells them that even potatoes,
with 48 chromosomes, beat us humans, and goldfish have 104 chromosomes,
more than twice as many as humans.
Invariably, the students are stunned. How can they be less evolved
than a potato? Or a horse? What Byington wants them to do is confront
their assumptions, because he knows that in order for students to
learn science, they first have to unlearn what they have assumed (in
this case, the more chromosomes the better).
As children,
we make all sorts of "common sense" assumptions about the
ways the world works, which is a loose definition of science. ''We
have more brains than horses or potatoes do, so we must have more
chromosomes," or, "The sun makes us warm, it's warm in summer,
so the sun must be closer." All too often we never unlearn these;
instead, "book learning" gets layered on top long enough
for us to pass exams. Then we revert.
Filmmakers at a Harvard graduation provided powerful evidence of this
more than 15 years ago, when they asked new graduates why it's colder
in New England in the winter and warmer in the summer. In the 1988
film, "A Private Universe," each young man and woman explains
with perfect confidence that the sun is closer to Earth in the summer
and farther away in winter.
Of course, the opposite is true. Earth's orbit is elliptical, and
New Englanders are actually closer to the sun in winter. Earth is
tilted away, however, and it is the tilt of its axis that determines
the climate.
We can assume that nobody taught those Harvard seniors bad science.
Instead, they probably intuited that "fact" when they were
young and never unlearned it. Since they were admitted to Harvard,
they must have learned enough classroom science to get high grades
on tests, but without dislodging or unlearning what they thought they
knew from observation. As Lee Shulman, the president of the Carnegie
Foundation for the Advancement of Teaching, has noted, "The first
influence on learning is not what teachers do pedagogically, but the
learning that's already inside the learner."
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Melanie
Krieger |
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| Omar Ghani |
Samuel
John |
How do teachers
help their students unlearn? Cary Academy's Scott Byington forces
students to confront their assumptions (we have more chromosomes than
potatoes) because he knows that mere rote learning of scientific facts
doesn't do the trick. Melanie
Krieger, the director of research at Plainview-Old Bethpage J.F.K.
High School on New York's Long Island, believes that hands-on, project-based
science helps students unlearn. Her students in grades 9-12 must develop
and carry out research projects, usually with the help of real scientists
working at nearby labs, hospitals, and technology companies. I watched
Samuel John and
Omar Ghani catch
carpenter ants for their project a couple of years ago: developing
ways to kill the ants using only biological controls and natural enemies;
in other words, with no pesticides.
Projects
like these take months, often including summer vacations, and demand
intense work, but the kids don't mind the work. As Samuel John described
it, Science is hands-on stuff: You learn it, and then you apply it,
and the applying part is where the fun comes in." John's and
Ghani's carpenter-ant project did not win any awards, but the following
year Samuel John scored a clean sweep, winning the Siemens/Westinghouse,
Intel Science Talent Search, and Intel International Science and Engineering
Fair competitions. He is now at Rensselaer Polytechnic Institute.
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If
only the elite enjoy the livliest approaches to
science teaching,
scientific illiteracy will only increase. |
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Although Melanie
Krieger's students enter their projects in prestigious science fairs
like Intel's (and sometimes win!), her class is open to all interested
students, not merely honors students. She notes that, while about
60 percent of the 100 school districts in her region use the project-based
approach to science, only two or three are open to all interested
students. "All the other programs have strict entry criteria
and quite often seem to look for ways to 'weed out' kids, she says.
 |
Leon
Lederman |
If only the elite
enjoy the liveliest approaches to science teaching, scientific illiteracy
will only increase. That worries Leon Lederman, the Nobel Prize-winning
physicist. "Our populations have never been more ignorant of
sci-
ence," he says, "and yet their lives are being influenced
ever more by technological developments: cellphones, implants, and
revolutions in molecular biology, genetics, and surgery. There's so
much fake science, junk science, 'out there, and people have to be
able to recognize it."
Lederman says science teaching can't be elitist because, as he puts
it, "All kids are born scientists. A scientist is someone who
asks questions, and kids ask questions. They have those embers of
curiosity. You blow on the embers, they get hotter and hotter, until
finally they erupt into a flame of passionate interest in the world."
‘Too
many kids are having their curiosity stomped out by
insensitive teaching in the schools.’
Leon Lederman,
Physicist |
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But too often science
class for "regular" students is rote memorization, particularly
with today's emphasis on multiple--choice testing. For example, Maryland's
state department of education was replacing bubble tests with perfornance-based
tests that required students to show how they arrived at their answers.
With the advent of the federal No Child Left Behind law's requirement
for testing in grades 3-8 every year, Maryland scrapped its Maryland
School Performance Assessment Program and has returned to cheaper,
more traditional methods of testing.
High-stakes tests and multiple-choice testing often determine how
science is taught, says Leon Lederman, who deplores what he calls
a winner-take-all mentality: "Too many kids are having their
curiosity stomped out by insensitive teaching in the schools."
Ray Baeehetti, an education veteran who is now- at the Carnegie Foundation,
shares Lederman's concern. "I've been in too many elementary
schools' where the reading and math emphasis was sucking the oxygen
out of just about everything else, he says. "Teachers would try
to work on bits of science ... but seldom with strong curricular strategies,
and hardly ever with useful support from their districts."
Textbooks are another problem. Jonathan Cole of Columbia University
found that the outstanding works of history, including textbooks,
were apt to contain more references to Madonna, the singer, than to
Watson and Crick and DNA. He notes, "College students who don't
major in science probably conclude that scientific developments and
accomplishments sprang from whole cloth, because they're not covered
in the books they read." .
Lederman believes a crisis is upon us. "If we don't fix our science
and math educational system," he warns, "the nation is really
in deep trouble; Our economy has been surviving on immigration, but
that's not going to last, because country after country is getting
wise and is keeping its scientists at home.
 But
despite superficial textbooks, rote teaching, and a shortage of project-based
learning, there is hope for science education. Robert Ballard, the
scientist and underwater explorer who is discovered the wreckage of
the Titanic, is one source of inspiration. Ballard first realized
that all of his graduate students were foreign-born. Where, he wondered,
were the young American scientists.? Then, spurred by the out-pouring
of letters (16,000 in two weeks) from children after he found the
Titanic, he created the Jason Project (www.jasonproject.org)
to allow middle school students to go on "virtual explorations.
Like Leon Lederman, Ballard believes most children are natural scientists.
"Any parent can tell you kids are fired up with curiosity,"
he says. "The first question they ask is why? Our job is to capture
that natural curiosity and turn it into a lifelong passion for learning."
Because of the Jason Project (now celebrating its 15th anniversary),
more than 12 million kids have explored the ocean floor, mapped wetlands,
and discovered sunken ships and treasures, thanks to the power of
technology. Some of these middle-schoolers have grown up and become
scientists in their own right, but that's not Ballard's goal. Like
Lederman, he wants all American citizens, regardless of their occupations,
to be scientifically literate.
Another ray of hope, albeit a faint one, emerged when high school
seniors were asked pretty much the same question the Harvard graduates
got wrong in 1988. The question was on last year's National Assessment
of Educational Progress science test, and 40 percent got it right.
That's not good enough, but it's better than Harvard did.
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