Nature Agrees: Science Students Should "Actively Grapple with Questions" Not Just "Listen to Answers"
Sarah Chaffee August 5, 2015 3:59 AM |
Discovery Institute has long promoted critical thinking in the
science classroom, noting that it is remarkably scarce in the way
evolution is taught. Despite media opposition to academic freedom laws,
active engagement, asking questions, and thinking analytically have been
demonstrated to promote student understanding and success.
That insight has now been confirmed by no less a source than Nature, the world's most prestigious scientific journal, in collaboration with Scientific American.
The two journals got together to produce an issue on the theme, showing
that STEM (science, technology, engineering, and mathematics)
instruction is due for reform. They note, "[S]tudents gain a much deeper
understanding of science when they actively grapple with questions than
when they passively listen to answers."
What Is Active Learning?
Jay Labov, a senior education advisor from the U.S. National Academy
of Sciences, describes active engagement as "learning content not as
something you memorize and regurgitate, but as raw material for making
connections, drawing inferences, creating new information -- learning
how to learn."
Unfortunately, this is not the norm for science classes. Jonathan Osborne wrote in 2010 in the journal Science:
Typically, in the rush to present the major features of
the scientific landscape, most of the arguments required to achieve such
knowledge are excised. Consequently, science can appear to its students
as a monolith of facts, an authoritative discourse where the discursive
exploration of ideas, their implications, and their importance is
absent (7). Students then emerge with naïve ideas or misconceptions
about the nature of science itself -- a state of affairs that exists
even though the National Research Council; the American Association for
the Advancement of Science; and a large body of research, major aspects
of which are presented here, all emphasize the value of argumentation
for learning science (8-10).
Active learning can take many forms, but it generally repudiates
traditional lecture-style teaching. Neuroscientist Sarah Leupen, for
example, doesn't ask her physiology class to name the sensory nerves in
the leg. Instead, says Nature, she poses the following question to the students:
You're innocently walking down the street when aliens zap away the sensory neurons in your legs. What happens?
- Your walking movements show no significant change.
- You can no longer walk.
- You can walk, but the pace changes.
- You can walk, but clumsily.
"We usually get lots of vigorous debate on this one," Leupen said. (For curious readers, the answer is d).
And there are many other classroom strategies for fostering scientific inquiry. Nature highlights
Little Scientists' House, a program developed in Germany for children
between three and six years old, but spreading worldwide. At Little
Scientists' House, students learn to ask questions about the world
around them and look for answers by simple observation and
experimentation.
In one exercise, students guessed whether more water could accumulate
on the head of a euro coin or other currency. One student thought that
the smaller coin, which was worth more money, would hold more water --
and the class proceeded to try out his idea. "In the end, the children
could not come to a definitive answer, but that is OK, says
[kindergarten teacher Christina] Jeuthe. The point is to spark
questions, and a conviction that they can be explored rationally."
On the college level, the University of Richmond in Virginia has
begun offering introductory, interdisciplinary science courses that
explore real science questions such as "antibiotic resistance and cells'
response to heat." Outside of the traditional classroom setting, active
learning can encompass activities from involving high school students
in real scientific research projects to materials-based outdoor
exploration.
What about Evolution?
Eugenie Scott, former executive director of the National Center for
Science Education, has said, "There are no weaknesses in the theory of
evolution." No matter what your stance is on evolution, however,
treating scientific theories as unquestionable fact doesn't make sense.
At Discovery Institute, we recommend teaching both the scientific
strengths and scientific weaknesses of evolutionary theory. Students
should not only hear about similarities in DNA sequences between species
and antibiotic-resistant strains of bacteria, but also grapple with the
Cambrian explosion and the intricacies of the cell.
What Is a Suggested Plan for Teaching a Unit on Neo-Darwinian Evolution?
Objective education means that students must be allowed to form and
express their own opinions. An objective unit covering neo-Darwinian
evolution might look something like this:
- First, cover the required curriculum by teaching the material
in the textbook. Ensure that students understand the scientific
arguments for neo-Darwinian evolution. (1-2 weeks)
- Next, spend a few days discussing scientific criticisms of neo-Darwinian evolution. The supplementary textbook Explore Evolution, the DVD Investigating Evolution, and the Icons of Evolution Study Guide are potential resources. Encourage students to think critically. (2-3 days)
- Finally, consider allowing students to spend a couple
days wrestling with the data and forming their own opinions. This could
include in-class debates, or an assignment where students write a
position statement on neo-Darwinian evolution. In these exercises,
students may defend whatever position they wish, but must justify it
using only scientific evidence and scientific arguments. (1-2 days)
Most public school curricula stop after step 1, missing out on the
benefits from steps 2 and 3. Some might claim those extra steps would
take too much time. But teaching the modern neo-Darwinian theory of
evolution in an objective fashion need not take any more time than the
2-3 weeks typically spent on an evolution unit.
More importantly, any extra time taken to teach this topic
objectively is not wasted -- it will help students better understand the
evidence, better appreciate scientific reasoning, and fulfill standards
requiring critical thinking and use of the inquiry method. Finally,
this approach will be welcomed by students who find this topic engages
their interest in science.
Building 21st-Century Scientists
It's high time for a change. Science education, especially at the university level, faces some hurdles. Nature
says, "A study tracking 17,000 post-secondary students in the United
States and Puerto Rico found that only two-fifths of those who enrolled
in a STEM discipline went on to obtain a degree in the field, or were
still studying for one 6 years later." On the other hand, Nature notes
that research at the University of Washington in 2014 surveyed 225
studies of teaching in STEM fields and found that active engagement
decreased failure rates by one-third.
Carl Wieman, a physicist at Stanford who won the 2001 Nobel Prize in
his field, began advocating for science education reform after
interacting with newly graduated scientists who "had done really well as
undergraduates, but couldn't do research." Today, along with prominent
journals such as Nature, Scientific American,and Science, he promotes active engagement in the classroom.
Nature concludes its keynote editorial, "But change is
essential.... In an era when more of us now work with our heads, rather
than our hands, the world can no longer afford to support poor learning
systems that allow too few people to achieve their goals."
That's right. Teaching the controversy over origins would be a step
towards better overall science education. Where the approach has been
adopted already, it trains students to think analytically and examine
the evidence -- in all scientific fields. It awakens interest in the
issue of origins by inviting students to confront the research
themselves. And students who succeed in courses on evolution (as well as
other STEM courses) are more likely to pursue degrees in these fields.
Inquiry in the classroom paves the way for inquiry in the lab.