[MSTA ] Motivating Underachieving Students in Math and Science
Deborah Duncan
deb50duncan at gmail.com
Mon Mar 5 18:56:13 CST 2012
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Resources and Strategies for K-12 Science and Math Teachers
Monday, March 5, 2012
Motivating Underachieving Students in Math and
Science<http://www.teachscienceandmath.com/2011/12/06/motivating-underachieving-students-in-math-and-science/>
<https://profiles.google.com/117292222642442780899>
[image: Hands-On Learning Using Math and Science]
Hands-On Learning Using Math and Science
Your students’ future and education needs are not like yours and mine. For
the most part, we are a product of an education system heavily influenced
by the industrial age - lectures and rote memorization. This style of
teaching was primarily designed to produce factory and skilled trade
workers.
Due to the dynamics of today’s world economy, most students no longer have
the same types of jobs waiting for them when they graduate. Their future is
in the service, health, and technology career fields. However, there is
still a demand for skilled trade workers (Bureau of Labor Statistics, 2010).
*A Need for a Shift in Teaching Strategies*
Today’s education system is still following the demands of the industrial
age. So how does this clash with students’ needs for the future?
When students are forced to sit in straight rows and listen to the
industrial revolution style of teaching — lectures and rote memorization of
facts — countless become bored underachievers! Primarily because education
system is out of step with the information age.
Unfortunately, many students view math and science as the two hardest
subjects to master. Why? Because there is way too much emphasis on lectures
and memorization. This contributes to their boredom in school and does
motivate them to learn.
So what must be done to stimulate their curiosity and engagement in a
manner that makes them to want to learn math and science?
**
*Tips for Increasing Student Engagement*
Motivating underachieving students requires moving away from demonstration,
telling, showing, and rote recall. Today’s math and science students need
hands-on, minds-on experiences to stimulate and challenge them to think.
The following are example strategies.****
*Technology Tools* - must have specific learning objectives, along with
real-world applications. Students use technology tools every day, so why
not use their prior knowledge and experiences with these tools to challenge
them to learn concepts.
***Online Interactive Math or Science Programs* - must address specific
learning concepts. Not just means of keeping students occupied or as a
reward for good behavior.
*Problem Solving *- solving real world problems frequently motivate
underachieving students. Why? Because they are allowed to think out of the
box to solve problems. Also, this strategy takes advantage of challenging
higher-order thinking skills. This strategy works well for all students,
not just underachievers. In addition, many students do not understand how
to solve problems. These students must be taught how to solve
problems<http://david-r-wetzel.suite101.com/12-tips-for-solving-word-problems-a57713>
.
***Concepts* - help students understand the critical features of a concept.
This includes requiring students to develop examples and non-examples of a
concept, assessing their true level of understanding. Also, require them to
provide examples of a concept linked to one or more other concepts.
*Lessons* - must include opportunities for students to shift to a new,
although still related to lesson objective, activity every 15 to 20
minutes. Examples include giving students opportunities to analyze, use or
demonstrate what they learned, and show how to or explain what would happen
if… This paradigm moves beyond completing worksheets (which in my
experience, students view as busy work).
Higher Order Thinking (HOT) - requires the use of higher-order thinking
questions. Open-ended questions to stimulate discussion. Do not use “yes or
no answer” questions. Effective use of wait time “I” and “II.” Do not use
questions which contain the answer. Example higher-order thinking
questions<https://docs.google.com/viewer?a=v&pid=sites&srcid=ZGVmYXVsdGRvbWFpbnxyaHNzY2llbmNlcGxjMjAxMHxneDo1ZWM2NjA1ZWVhMDAyZjdk>,
include:
- What might happen if ____?
- Can you summarize ____?
- What evidence supports ____?
- How is this similar or different to ____?
- How might you organize ____ into categories?
- What other ways can you show or illustrate ____?
*Math Example*
Instead of showing your students the formula in geometry for determining
the volume of an object, labeling variables, and how to solve the equation.
Followed by endless drill and practice. Give them concrete and tangible
objects to explore, touch, and measure. This leads to higher levels of
thinking as they analyze and apply the concept of volume. After providing
them with a variety of objects (regular and irregular shapes), ask them how
they will determine the volume of these objects. Example higher-level
questions include:
- Which object has the greatest volume?
- How do you know this true?
- How many ways are there to determine the volume of an object?
- How could you visually represent your solution? (looking for a graph,
table, equation, pictures, etc.)
*Science Example*
Instead of showing, demonstrating, or watching a video of a discrepant
event. Allow students to participant through hands-ondiscrepant
event<http://david-r-wetzel.suite101.com/three-more-discrepant-events-in-science-a68313>
investigations.
For example: *Air Pressure* Materials - One Set for Each Group: one
aluminum pan pie (non-smooth bottom), water, one 16oz clear glass, one
candle (about 3 inches tall), and matches.
1. Students attach the candle to the center, bottom of the pie pan.
2. Now they pour water into the pie pan, about three quarters of an inch
deep.
3. Students light the candle.
4. Now they place glass over the candle and observe what happens.
5. Allow students to repeat as necessary.
After they have observed and recorded their observations, ask themhigher-level
science questions<http://david-r-wetzel.suite101.com/20-questions-in-science-projects-a58140>,
for example:
- Why is ____ happening?
- What do you think is causing ____?
- You seem to be assuming that ____?
- What conclusions may be draw from ____?
- How is ____ different (like) ____?
Motivating underachieving students to learn math and science can be
difficult or even challenging on occasions. With these teaching strategies
students will no longer be bored by traditional lessons. They will find
that math and science are not that difficult, because they are allowed to
participate, think outside the box, and make connections.
Now it is your turn, do you have any additions to these strategies?
http://www.teachscienceandmath.com/2011/12/06/motivating-underachieving-students-in-math-and-science/
--
Deborah
I live in my own little world, but that's ok they know me here.
Deborah Duncan, Neshoba Central High School
http://nchsdduncan.wikispaces.com
http://msta.wikispaces.com
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