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Ghost Particle, The
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Classroom Activity
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Activity Summary
Students collect evidence to make inferences about an object hidden
inside a sealed box.
Learning Objectives
Students will be able to:
think critically and logically to raise questions. -
identify questions that can be answered through investigation.
formulate and test hypotheses. -
develop predictions and descriptions based on investigations.
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copy of the "Black Box Mystery" student handouts (PDF
or
HTML)
- box with unknown object inside
Background
In 1930, Wolfgang Pauli postulated the existence of a small
elementary particle with no charge and very little or no mass. He
proposed this particle because scientists were measuring less energy
after a process known as beta decay than before it occurred,
conflicting with the law of conservation of energy. Pauli's new
theoretical particle balanced the energy equation. (The particle was
later named the neutrino in 1934 by Enrico Fermi.) Further studies
showed that the neutrino was also necessary to maintain the
conservation laws of momentum and spin. There are currently three
known types, or "flavors," of neutrinos: electron, muon, and tau
neutrinos.
Billions of neutrinos pass through Earth each second, but since they
are particles with no electric charge and have very little mass,
they only interact weakly with other kinds of matter and are
difficult to detect. Scientists study neutrinos indirectly by
looking at the results of their interactions with other forms of
matter such as heavy water or chlorine.
To help students understand the size of subatomic particles, you may
want to share the following chart with them and as a class develop a
sample analogy regarding atomic sizes. (For example, one sample
analogy would be "If an atom filled the distance from Boston to
Cleveland, the nucleus would be about the length of a football
field; a proton would be about the height of a three-story apartment
building; and an electron and a subatomic particle called a quark
would be about a centimeter wide, or the width of a blueberry.")
Atomic Scale
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scale in meters
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scale in 1016 meters
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sample analogy
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atom
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10-10
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1,000,000
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something 100,000,000 cm or 1,000,000 m
(distance from Boston to Cleveland)
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nucleus of atom
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10-14
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100 |
something 10,000 cm or 100 m
(football field length)
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proton
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10-15
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10 |
something 1,000 cm or 10 m
(height of 3-story apartment building)
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quark or electron
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≤10-18
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≤.01
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something about 1 cm such as a blueberry
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Scientists have developed instruments to help them study subatomic
particles, such as particle colliders and detectors. In this
activity, students will experiment with what it is like to gain
information about something they cannot physically see. Students
will generate and test questions to try to identify an unseen
object. Based on the evidence they gather, they will infer what is
in their mystery box.
Key Terms
conservation of energy: States that the total amount of
energy in a closed system remains constant.
conservation of mass: States that the products of a chemical
reaction have the same total mass as that of the reactants.
lepton: A family of elementary matter (or antimatter)
particles that includes the electrically charged electron, muon, and
tau and their antimatter counterparts. The family also includes the
electrically neutral electron-neutrino, muon-neutrino, and
tau-neutrino and their antimatter counterparts.
neutrino: A lepton with very little mass and no electric
charge.
particle: A subatomic object with a definite mass and charge.
Currently known elementary matter particles are grouped into
categories of quarks and leptons and their antimatter counterparts.
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Discuss how scientists sometimes collect evidence to infer the
presence of objects they cannot see. Tell students that in this
activity, they will collect evidence to make inferences about an
object hidden inside a sealed box.
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Create each mystery box by placing a common classroom object
(such as a roll of tape, scissors, or a beaker) inside a box and
sealing it with tape or a rubber band.
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Set up a table that displays 10 to 15 common classroom objects,
some of which are similar to or exactly the same as the objects
in the mystery boxes. Provide additional empty boxes as well.
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Organize students into groups and distribute the "Black Box
Mystery" student handout to each student and a mystery box to
each group. Explain that the challenge is to design ways to
gather information about a mystery object that students can't
see or test directly.
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Point out that the mystery objects are similar to some of the
objects on the display table. Students can use information they
know about these objects to help them learn more about the
unknown mystery objects.
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After they have completed the activity, have students compare
the process of inferring the identity of a mystery object sealed
in a box to inferring the existence and number of neutrinos
detected by their effect on another substance. Then have groups
consider how inference plays a role in their daily lives.
Explore group answers in a whole-class discussion.
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As an extension, provide teams with a black box that has an
object taped to the bottom of the box. Provide teams with
skewers, rulers, pencils, and grid paper. Have teams measure
their objects and draw them on grid paper. Ask whether measuring
made the object easier to identify. Discuss how specific
measurements sometimes help scientists better define things they
cannot see.
Students will design a variety of tests to gather information about
the mystery object. For example, they might determine the weight of
the object by comparing the weight of the mystery box to the weight
of an empty box. They might shake the box and listen to the sound
the object makes. Or they might try to determine the object's shape
by the way it strikes different points of the box when shaken. They
could then take a known object from the display table and put it
through similar tests. Students might also rule out objects that are
unlikely or impossible, such as objects that are too large to fit in
the box.
If students arrive at immediate conclusions, direct them to return
to the evidence by asking questions like
How do you know that? Remind students to evaluate their
inferences by comparing them to the evidence they've collected.
Inferences that don't include all of the evidence are not
necessarily wrong but may be less believable. Point out that there
is a range of plausible explanations, some being more likely than
others.
Discuss with students whether the real identity of the mystery
object should be revealed. By not allowing students to see what the
object is at the end, the focus of the activity remains not on
getting the right answer but on developing plausible inferences, or
conclusions, that are supported by evidence.
Student Handout Questions
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What inferences can you make about the object? List them on a
separate sheet and include the evidence that supports them.
Student answers will vary based on the tests they
conducted.
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What situations in your daily life might call for inference?
List the situations and the evidence you use to support those
situations.
Student answers will vary. One example of a daily life
inference might involve inferring whether someone is in the
bathroom. Evidence such as a closed door, the sound of running
water, and a bathrobe missing from a sibling's bedroom could
be used to infer that someone is in the bathroom.
Web Sites
NOVA—The Ghost Particle
www.pbs.org/nova/neutrino
Read seven steps to making a good science film, learn of two
scientists who spent their careers searching for the solar neutrino,
explore neutrino-hunting projects worldwide, and view a time line
detailing the pursuit of the elusive particle.
How Do We Know Protons, Electrons, and Quarks Really Exist?
www.nsta.org/main/news/stories/science_and_children.php?
category_ID=86&news_story_ID=51054
Suggests ways of addressing the existence of invisible particles.
Solving the Mystery of Missing Neutrinos
nobelprize.org/physics/articles/bahcall
Describes how scientists solved the solar neutrino mystery.
What's a Neutrino?
www.ps.uci.edu/~superk/neutrino.html
Provides a detailed look at the history of neutrinos, along with
in-depth reviews of the different experiments and devices used to
detect neutrinos.
Books
A Tour of the Subatomic Zoo: A Guide to Particle Physics
by Cindy Schwarz and Sheldon Glashow. American Institute of Physics,
1996.
Introduces the ideas, terminology, and techniques of high-energy
physics and provides historical views of matter from the atom to the
quark.
The World of Atoms and Quarks
by Albert Stwertka. Twenty-First Century Books, 1995.
Traces the history of atomic theory in physics and includes a guide
to elementary particles.
The "Black Box Mystery" activity aligns with the following National
Science Education Standards (see
books.nap.edu/html/nses).
Grades 5-8
Science Standard A
Science as Inquiry
Abilities necessary to do scientific inquiry
Grades 9-12
Science Standard A
Science as Inquiry
Abilities necessary to do scientific inquiry
Classroom Activity Author
Tanya Gregoire has taught at Brookline Public Schools in
Massachusetts and is coauthor of "Museum of Science Activities for
Kids." This classroom activity originally appeared in the companion
Teacher's Guide for NOVA's "Hunt for Alien Worlds" program.
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