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Title: What General Chemistry Students Know (and Don


1
What General Chemistry Students Know (and Dont
Know) About Quantum Concepts in Chemistry
2
Quantum Concepts in ChemistryThe TeamPeter
Garik (presenting), Boston University (garik_at_bu.e
du)
  • Haim Eshach,
  • Ben Gurion University, Israel
  • Luciana Garbayo, BU
  • Alexander Golger, BU
  • Morton Z. Hoffman, BU
  • Peter Carr, BU
  • Alan Crosby, BU
  • Dan Dill, BU
  • Yehudit Judy Dori,
  • Technion, Israel

3
Quantum Concepts in Chemistry
  • This project is funded by the U.S Department of
    Educations Fund for the Improvement of Post
    Secondary Education (FIPSE).

4
Quantum Concepts in Chemistry
  • The objectives of our FIPSE project are
  • to find ways to introduce quantum concepts into
    the chemistry curriculum
  • to design software that will support the teaching
    of quantum concepts and,
  • to evaluate the success of our software and
    curricular activities in supporting student
    learning of quantum concepts.

5
Quantum Concepts in Chemistry
  • Why teach quantum concepts at an early stage in
    the chemistry curriculum?
  • The epistemology of a mature science relies upon
    foundational models for its research program.
  • Such models provide a unifying perspective on the
    physical world and support the best insights and
    reasoning that we can currently achieve.

6
Quantum Concepts in Chemistry
  • For cosmology, it is the inflationary theory of
    the universe.
  • For geology, it is plate tectonics.
  • For biology, it is Darwinian evolution.

7
Quantum Concepts in Chemistry
  • For chemistry, one of the foundational models is
    unarguably the quantum theory of atomic structure
    and electronic behavior.
  • The pedagogical issue is where does it belong in
    the curriculum?
  • Quantum concepts appear burdened with additional
    abstractions (including mathematics) that make
    them first appear forbidding to teach.

8
Quantum Concepts in Chemistry
  • We argue that the unifying power of quantum
    concepts is so great, and their utilization for
    modern chemistry so extensive, that finding ways
    to successfully introduce them at an early point
    in chemistry education is our obligation to the
    students.

9
Quantum Concepts in Chemistry
  • What are quantum concepts in chemistry?
  • The principal quantum topics in chemistry are
  • 1) The description of electrons and how they
    behave in the presence of other charges.
  • 2) The description of the interaction of
    radiation with matter, and primarily with
    electrons.

10
Quantum Concepts in Chemistry
  • Historically quantum concepts grew out of
    analogies to electromagnetic theory. Since the
    interaction of radiation with matter is a key
    concept in chemistry (spectroscopy), it is
    traditionally taught.
  • The properties of electromagnetic waves provide
    an early access point for what we refer to as
    Quantum Readiness.

11
Quantum Concepts in Chemistry
  • What is a wave?
  • What is an electromagnetic wave?
  • Is there an associated electric field
  • Is there an associated magnetic field
  • What is the relationship between amplitude and
    intensity?
  • What is constructive and destructive interference?

12
Quantum Concepts in Chemistry
  • How does the phase of a wave vary with time and
    space?
  • How does a light wave interact with a charged
    particle?
  • What is a photon?
  • How do charged particles interact?
  • Students prepared with these concepts should have
    analogies for understanding quantum phenomena.

13
Quantum Concepts in Chemistry
  • What are the quantum concepts that we would like
    students to master?
  • The delocalization of the electron and its
    description by a probability amplitude.
  • The quantization of energy levels.
  • The pairing of a wave function with an energy.
  • Constructive and destructive interference.
  • The Pauli Exclusion Principle.

14
Quantum Concepts in Chemistry
  • The transition in energy levels associated with
    absorption and emission of radiation.
  • The geometry of atomic and molecular orbitals.
  • The atomic structure that arises from the Aufbau
    Principle.
  • The molecular structure that arises from bonding
    orbitals and hybridization.

15
Evaluating Students Conceptual Understanding of
Quantum Concepts
  • As a first step to determining how students learn
    quantum concepts, we engaged in a qualitative
    research project.

16
Theoretical Background and Methodology
  • We base our qualitative research approach of
    using interviews on the empirical result from
    misconceptions research that, in assessing a
    population of students understanding of a
    scientific phenomenon, the number of different
    conceptions observed saturates quickly
    (Wandersse, Mintzes and Novak 1994).

17
Theoretical Background and Methodology
  • For our interpretive work reading the interviews,
    we adopted a perspective based on a dynamics
    systems approach proposed by Smith, diSessa and
    Roschelle (1993), diSessa and Sherin (1998), and
    by Petri and Niedderer (1998).

18
Theoretical Background and Methodology
  • We look for phenomenological primitives or
    cognitive elements/tools that students employ in
    order to construct their understanding.
  • We expect to find cognitive attractors
    recurring misconceptions expressed by the
    students.
  • We further expect to find stable cognitive
    elements, the deep seated convictions upon which
    students rely for their interpretations.

19
Theoretical Background and Methodology
  • To further understand students reasoning, we
    adopt a modified ontological categorization
    scheme following Chi and Slotta (1993). They
    categorize entities as matter (objects),
    processes, and mental states. This can be useful.
    For example, if a student thinks that a photon is
    an object, then with it comes a host of
    associations such as the photon energy object
    collides with an electron and knocks it to
    another orbital.

20
Theoretical Background and Methodology
  • We add to these ontological categories the field
    category in order to have a sensible ontology for
    quantum entities.
  • Finally, we follow Lawson (1993) by including
    chunking as an important component in explaining
    the way that our minds organize what we learn.

21
Design and Procedures
  • We interviewed students prior to, and subsequent
    to, instruction on quantum concepts.
  • Students were selected from a pool of volunteers
    taking the honors general chemistry course at a
    research university.

22
Design and Procedures
  • The students were all freshman in their second
    semester.
  • This was an elite group of students they had
    passed a placement test to enroll in the honors
    course for science majors.
  • Most students were chemistry or science
    concentrators.

23
Design and Procedures
  • Students were selected for the interviews to
    produce an even grade distribution.
  • Each interview was conducted based on the same
    set of questions (an interview guide approach).
  • To the extent possible, the interviews were
    clinical in nature in a Piagetian fashion. The
    interviewers flexibly probed the individual
    students responses to elicit deeply held
    convictions.

24
Design and Procedures
  • As an aid to better elicit explanations from the
    participants, experiments were done during the
    interview (double slit interference pattern,
    hydrodgen discharge tube with grating, strong
    magnets).
  • In conducting the interviews prior to
    instruction, an assumption was made that students
    would have had exposure to quantum concepts in
    their high school chemistry courses.

25
Findings
  • Our findings in our pre-instruction interviews
    are confirmatory of prior physics education
    research, and some echo our earlier findings with
    high school students (Eshach and Garik 2001).
  • 1) In describing the structure of the hydrogen
    atom, most students began with descriptors
    reminiscent of the Bohr model (orbit, circular
    region) but in further conversation they
    described and drew pictures with elements of an
    electron cloud model, albeit one frequently
    characterized by a rapidly moving particle. Such
    transitional descriptions of the H-atom agree
    with the reports of Petri and Niedderer (1998),
    Müller and Wiesner (2002), Mashhadi (1996), and
    Ireson (2000).

26
Findings
  • 2) Students knew that both light and electrons
    possessed wave-like properties. However, some
    believed that this referred to the trajectory of
    these as particles in space, a previously
    described cognitive attractor (Ireson 2000
    Müller and Wiesner 2002 Olsen 2002).
  • 3) In discussing interference of light waves,
    students referred to waves as if they were
    objects, as opposed to being dynamic events
    (Wittmann 2001).

27
Findings
  • 4) The confusion of students about the properties
    of electromagnetic waves is apparent from the
    fact that they were unaware that there is an
    electric field component to radiation. This was
    uniformly true in our pre-instruction interviews.

28
Findings (and Disclaimer)
  • Many topics were covered in the pre-interviews.
    The post-interviews tended to be more focused as
    learning of specific items were investigated.
  • At the risk of mischaracterizing what these very
    bright and very well taught students
    accomplished, we will now focus on two areas in
    which they encountered difficulty.

29
Findings
  • A key quantum concept is that atomic orbitals are
    stationary quantum states characterized by two
    quantities a wave function and an energy (?, E).
  • As we see from the following responses, students
    wrestle mightily with this apparently simple idea.

30
Findings Orbital/Energy Level
  • S1.112.post
  • P What is an orbital?
  • S An orbital is the space where the electron is
    probably going to be, and its defined by a wave
    that fits with the Schrödinger... Or that meets
    the solution for the Schrödinger Equation.
  • P You say the space that an electron is going
    to be. That is an orbital?
  • S Well, okay, let me rephrase this, hopefully
    clearer. An orbital is an area of space that
    satisfies the Schrödinger Equation, and has a
    specific energy that satisfies that equation, and
    within that area in space, each point in space
    has a probability that the electron may be at
    that point in space, and an orbital is all the
    points in space that satisfy that energy.
  • P What is an energy level?
  • S An energy level is a specific energy that
    satisfies the Schrödinger equation, thats a
    possible solution for that equation, and you can
    have many points in space that will satisfy that
    energy, and all the points that satisfy that
    energy make up the orbital thats in that energy
    level.
  • P So, what is the connection between an energy
    level and an orbital?
  • S Orbitals are at specific energy levels.

31
Findings Orbital/Energy Level
  • S2.112.post
  • S Energy level. This is word, this is the phrase
    that I just really dont like. An energy level
    represents the difference between two orbitals as
    far one electron moves from one orbital to
    another. I cant say this still. The electron
    moves from one orbital to another that difference
    is known as a quote, unquote, energy level. I
    left you saying last time saying that I dont
    think that is good word for it, but I never, I
    thought about it for a long time actually. I
    spent most of the day thinking about it, and I
    couldnt come up with a phrase that accurately
    described it. And, its, I think, energy state is
    better because it describes the state of the
    electron, the electron is in the excited state,
    its not where it is normally at. But then when
    you start saying state, students start thinking
    is it a solid, liquid, or gas? and theres too
    many overlapping words in chemistry. It makes
    things very confusing. But, an energy level is
    just the difference between two orbitals of an
    atom.

32
Findings Orbital/Energy Level
  • S3.112.post
  • S An orbital is Its actually just another name
    for the wave function, which is the probability
    of finding an electron in a certain shape and
    area, distance away from the nucleus.
  • P What is an energy level?
  • S An energy level is the radius, a certain set
    radius away from the nucleus where electrons are
    found to be.
  • P What is the relationship between an orbital
    and an energy level?
  • S Orbitals are found in certain energy levels,
    so if theres, in the first energy level theres
    the s orbital, which is spherically shaped, and
    thats, theres a probability of finding it
    there, and then if you go into the second
    orbital, in the middle theres a node, a region
    where is just doesnt, you wont, you will not
    find the electron, when you get into higher more
    complex atoms with more electrons.

33
Findings Orbital/Energy Level
  • S4.112.post
  • P What is the relationship between an orbital
    and an energy level?
  • S The energy level dictates, no actually not,
    actually its nopause Every orbital, that,
    like the different orbitals, have different
    possible energy configurationsno, thats not
    whatI am not really sure how to explain it.
    UmmI know that theyre related, I just cant
    really explain how. Like, ah, as energy
    increases, the radius of the electron, or the
    distance of the electron away form the nucleus
    increases and generally speaking, the different,
    the more complex, um orbital shapes also increase
    complexity as energy does. I guess that the only
    way I can explain, I cant really think of any
    other way to say it.

34
Findings
  • Another example of student confusion emerged in
    discussions of what electromagnetic radiation and
    photons are.

35
Findings Nature of Light
  • S1.112.post
  • P Okay. When you say that its electromagnetic
    radiation, can you elaborate on that? What is
    electromagnetic?
  • S Its oscillating in energy, and that induces
    some sort of magnetic oscillation with it, but
    electromagnetic radiation would be the, like,
    wave thats oscillating in energy, I think.
  • P It is said that light propagates as a wave.
    What is it that is waving?
  • S Oh, I think its the energy. Yeah. Well,
    its the value of the wave function, and that is
    related to energy.
  • P And what is it that is oscillating?
  • S The value of the wave function. So
  • P Could you put a Could you label what your
    axis, or what your axes are?
  • S Okay, well, if this an axis that isWe can
    label it x, we can label it anything, then where
    it crosses this other axis is zero and the value
    of the function along that axis equals to psi of
    the function, whatever the functionOr psi of the
    variable, whatever you chose to call that axis,
    x, or r, or d.
  • P Okay, what are the units for x, and what are
    the units for psi?
  • S the units for x would be distance, so
    probably meters, or centimeters, however you
    chose to measure it, and Im pretty sure psi is
    unitless.

36
Findings Nature of Light
  • 3.112
  • P What is light?
  • S Its electromagnetic radiation.
  • P What do you mean by electromagnetic, when you
    say electromagnetic radiation?
  • S Well, its In wave form its electricity
    perpendicular to magnetic waves.
  • P Okay, but when you say electricity, what do
    you mean by electricity?
  • S Just the charge of the electron.
  • P Charge of the electron?
  • S Uh huh.
  • P So are there electrons present within an
    electromagnetic wave or radiation?
  • S Yes.

37
Findings Nature of Light
  • S3.112.post
  • Whats waving?
  • S Its Its not really anything thats in
    particular waving, thats just Cause its Its
    actually found to be Theres the wave and
    particle duality, so its not really waving
    necessarily. I mean, theres a sine curve so I
    guess it would be energy, if anything.
  • P So you said the sine curve, and now you say
    energy. How do you relate the sine curve to
    energy?
  • S As it As the wave propagates up and down its
    different states, or different amounts of energy.

38
Findings Nature of Light
  • S4.112.post
  • P Okay, can you tell me what light is?
  • S Nope, still really dont know. Just pretty
    much, packets of , well not packets of energy,
    just straight up energy. Quantized energy. There.
  • (skip)
  • P It is said that light propagates as a wave.
    Can you tell me what it is that is waving or
    oscillating for a light wave?
  • S The way it moves. It just goes in a wavelike
    fashion. And so, the traditional thought that
    light is just a straight beam, the individual,
    well, theoretical, the quantity that they
    quantify as a particle is moving in a wavelike
    fashion, not just straight.
  • (skip. What follows demonstrates that the above
    is a liberated conviction, and not deeply held
    conviction.)
  • S Light doesnt really have a distinct form or
    shape. Its just the wave that they say is just a
    general, just a representation ofof what it
    could be. Not technically the actual movement
    itself, its just a theoretical representation of
    what it could be, not technically the actual
    movement itself. It is just a theoretical
    representation because we cant measure what it
    looks like or what it does. So, we just have to
    give some mathematical computation to that to
    represent some sort of quantification of light
    itself.
  • During the course of the interview, this student
    interpreted the two-slit experiment done in his
    presence with a HeNe-laser as showing a pattern
    of electron density.

39
Findings
  • These two examples of misconceptions both revolve
    around a common problem the understanding of a
    wave function. In one case it is the wave
    function for a particle with mass. In the other
    it is for a massless particle, a photon.
  • The difficulties revealed suggest that a common
    solution might be in order that emphasizes the
    field nature of both the electrons wave function
    and the wave function of radiation.

40
Findings Chunks
  • Chemistry education relies heavily on students
    acquiring chunks of knowledge that can be drawn
    upon quickly. There is chunked knowledge that
    students need to learn about atomic structure
    (principal quantum number, s, p, d, f), about the
    Periodic Table (groups of elements, periodic
    trends), and spectroscopy.
  • Here we provide an example of a successful chunk,
    and then one that is less well founded.

41
Findings
  • Based on our interviews, some of the chunks we
    heard were
  • light
  • interference
  • energy level
  • orbital
  • spectrum
  • atomic structure
  • H atom
  • He atom
  • Li atom
  • H2
  • molecular bonding

42
Example H-spectrum chunk
  • H-spectrum chunk
  • S TheresI dont think I could draw it as
    electrons jumping within an atom, just because
    all the It would be hard to draw all the
    different shapes of the orbitals, and everything,
    but if you wanted to draw, you could draw, like,
    lines here, and this would beThe scale that this
    was on would be increasing energy, and the first
    energy level would be down here, very low energy,
    and that would be the n equals one energy level,
    and then youd somewhat further up have n equals
    two, and as you increase, the energy levels get
    closer together, until eventually they blend into
    a solid line up here, and when an electron
    jumpsThis would be n equals five. When an
    electron jumps down, if you put energy in it,
    into an atom, to get an electron all the way up
    to a higher energy level, and then it goes and
    falls back down into the n equals two energy
    level, then theres a certain energy that it
    emits, and energy is equal to Planks constant
    times a certain frequency, and so, if you find
    the frequency and convert that to a wavelength,
    you can find out that these jumps, where an
    electron goes down from n equals five to two, n
    equals four to n equals two, or n equals three to
    n equals two, all emit energy thats within the
    visible range, or visible light range. So thats
    what we just saw, was electrons going down an
    energy level, and the atoms emitting light.

43
Example Interference Chunk
  • P Do you think you could sketch for me what you
    mean by this destructive interference?
  • S So just like in the experiment theres two
    slits, the light passes through there, and then
    you just go on from here and here, and it would
    meet at a central point, which is the wall, so
    right here, and when it Thats just one section
    of the sine curve. When it meets this way, you
    get constructive interference, and if the
    amplitude of it was, say, plus one, plus one,
    plus one, minus one, minus one, youd get
    amplitude added up to a plus two, and minus two.
    You have to get the intensity, which is square of
    that result and plus two equals And This
    would result in zero, with a flat line, and that
    would result in the square root of that and youd
    get nothing. So that would be a dark region and
    that would be a bright region.
  • P Why would the interference between the two
    waves be different at different positions?
  • S Im not sure I understand it.
  • (skip)
  • P Is there something that determines whether
    they meet and result in destructive interference
    as opposed to meeting and resulting in
    constructive interference?
  • S No. I dont believe there is.

44
Discussion
  • The honors students that we interviewed showed a
    remarkably stronger understanding of the Born
    interpretation of orbitals than we have found in
    the past. Our prior experience, with high school
    students and medical students (Eshach Garik
    2001 and 2002), matched other reports in the
    literature that students describe atomic
    structure as a composite of Bohr, de Broglie, and
    electron cloud concepts.
  • Moreover, on the whole the students we
    interviewed grasped the fundamental spectroscopic
    fact that the energy of emitted radiation is the
    difference between energy levels, as opposed to
    the energy of a level (Zollman 2002).

45
Discussion
  • Nevertheless, these students exhibited a series
    of misconceptions that are enlightening for an
    education researcher.
  • Specifically, we observe that the lack of a
    careful introduction to the properties of an
    electromagnetic wave, specifically the fact that
    there is an electric field, eventually led to
    students confusion.

46
Discussion
  • We further suggest that the confusion that
    students evidenced about photons as objects, and
    the relationship between energy levels and
    orbitals, is a result of not understanding the
    field nature of both electromagnetic radiation
    and wave states of matter.

47
Discussion
  • Such incomplete conceptions can later manifest
    themselves when chunks of knowledge are put to
    the test. For example, the interference chunk
    previously related at first sounds plausible.
    However, it proves inoperative when tested for
    predictions. The student apparently has
    constructed the chunk with waves behaving as
    objects. As such, he cannot predict where maxima
    and minima should occur in an interference
    pattern.

48
Conclusion
  • Given the central nature of quantum concepts to
    modern chemistry, the dearth of education
    research in how to teach this subject is
    surprising. Many papers have appeared in J. Chem.
    Ed. discussing methods of instruction that rely
    on quantum principles, but evaluation of these
    methods is seemingly missing.
  • It is our conviction that if properly approached,
    quantum concepts are teachable from an early
    stage in the undergraduate chemistry curriculum.
    We hope to follow-up this current research with
    future work that supports the design of
    successful curriculum.
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