Transcript Models and Modeling in the High School Chemistry Classroom Larry Dukerich Modeling Instruction Arizona State University.

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Models and Modeling
in the High School
Chemistry Classroom
Larry Dukerich
Modeling Instruction
Arizona State University
Traditional Instruction
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 Presumes two kinds of knowledge:
 Facts and ideas - things packaged into words and
distributed to students.
 Know-how - skills packaged as rules or procedures.
 Assumes students will see the underlying structure
in the content.
“Teaching by Telling” is Ineffective
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Students…
Systematically miss the point of what we tell them.
 do not have the same “schema” associated with key
ideas/words that we have.
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do not improve their problem-solving skills by watching
the teacher solve problems
Algorithms vs Understanding
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What does it mean when students can solve
quantitative problems, but cannot answer the
following?
Nitrogen gas and hydrogen gas react to form
ammonia gas by the reaction
N2 + 3 H2  2 NH3
The box at right shows a mixture of nitrogen and
hydrogen molecules before the reaction begins.
Which of the boxes below correctly shows what the
reaction mixture would look like after the reaction
was complete?
A
B
C
D
How Do You Know?
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 All students know the formula
for water is H2O.
 Very few are able to cite any
evidence for why we believe
this to be the case.
Do They Really Have an
Atomic View of Matter?
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Before we investigate the inner workings of
the atom, let’s first make sure they really
believe in atoms.
Students can state the Law of Conservation of Mass,
but then will claim that mass is “lost” in some
reactions.
 When asked to represent matter at sub-microscopic
level, many sketch matter using a continuous
model.
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Representation of Matter
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 Question: “What’s happening at the simplest
level of matter?”
More
Storyboards
Gas Diffusion:
Where’s The Air?
Aqueous Diffusion:
The Continuous
Model of Matter
Where’s the Evidence?
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Why teach a model of the inner workings of the
atom without examining any of the evidence?
Students “know” the atom has a nucleus surrounded by
electrons, but cannot use this model to account for
electrical interactions.
 What’s gained by telling a Cliff’s Notes version of the
story of how our current model of the atom evolved?
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Seeing is Believing?
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Because students have trouble relating microscopic and
macroscopic views, we start our discussion with the
atom and bypass the traditional historical approach
taken by many texts. (This is not to say that we do not
value the study of the history of chemistry; in fact, we
believe that history helps the material come alive.)
Pictures from scanning tunneling microscopes can now
“show” us atoms. Therefore, we begin with “We
believe in atoms because we can see them.”
“Teaching Tip” from World of Chemistry, Zumdahl, Zumdahl, DeCoste, McDougall Littell, 2007
I See It Because I Believe It
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Instructional Objectives
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 Construct and use scientific models to describe, to
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explain, to predict and to control physical
phenomena.
Model physical objects and processes using
diagrammatic, graphical and algebraic
representations.
Recognize a small set of particle models as the content
core of chemistry.
Evaluate scientific models through comparison with
empirical data.
View modeling as the procedural core of scientific
knowledge
What Do We Mean by Model?
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Symbolic Representations
Verbal
Physical
System
Algebraic
Mental
Model
Diagrammatic
Graphical
Models are representations of structure in a physical
system or process
Why Models?
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 Models are basic units of knowledge

A few basic models are used again and again with only minor
modifications.
 Models help students connect
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Macroscopic observations
Sub-microscopic representations
Symbolic representations
Why Modeling?!
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 To help students see science as a way of viewing
the world rather than as a collection of facts.
 To make the coherence of scientific knowledge
more evident to students by making it more
explicit.
 Models and modeling figure prominently in the
NGSS.
Uncovering Chemistry
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Examine matter from outside-in instead of from
inside-out
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Observable Phenomena  Model
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Students learn to trust scientific thinking, not just
teacher/textbook authority
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Organize content around a meaningful ‘Story of Matter’
Particle Models of Increasing Complexity
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 Begin with phenomena that can be accounted for by
simple BB’s
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Conservation of mass
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Behavior of gases - KMT
 Recognize that particles DO attract one another
 “Sticky BB’s” account for behavior of condensed phases
Models Evolve as Need Arises
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 Develop model of atom that can acquire charge after
you examine behavior of charged objects
 Atom with + core and mobile electrons should
explain
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Conductivity of solutions
Properties of ionic solids
Energy - Early and Often
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 Make energy an integral part of the story line
 Help students develop a coherent picture of the
role of energy in changes in matter
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Energy storage modes within system
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Transfer mechanisms between system and surroundings
Reconnect Eth and Ech
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 Particles in system exchange Eth for Ech to
rearrange atoms
181 kJ + N2 + O2 ––> 2 NO
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Representation consistent with fact that an endothermic
reaction absorbs energy, yet the system cools
How to Teach it?
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constructivist
vs
transmissionist
cooperative inquiry
vs
lecture/demonstration
student-centered
vs
teacher-centered
active engagement
vs
passive reception
student activity
vs
teacher demonstration
student articulation
vs
teacher presentation
lab-based
vs
textbook-based
Be the “Guide on the Side”
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 Don’t be the dispenser of knowledge
 Help students develop tools to explain behavior of
matter in a coherent way
Let the students do the talking
 Ask, “How do you know that?”
 Require particle diagrams when applicable
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Preparing the Whiteboard
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Making the Presentation
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