Course Profile
Science, Grade 9 applied, Public
Unit 1
Course Profiles are professional development materials designed to help teachers implement the new Grade 9 secondary school curriculum. These materials were created by writing partnerships of school boards and subject associations. The development of these resources was funded by the Ontario Ministry of Education and Training. This document reflects the views of the developers and not necessarily those of the Ministry. Permission is given to reproduce these materials for any purpose except profit. Teachers are encouraged to amend, revise, edit, cut, paste, and otherwise adapt this material for educational purposes.
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Acknowledgments
Public District School Board Writing Teams - Science
Course Profile Writing Team
Arthur Prudham, Lead Writer, Waterloo Region District School Board and
Science Co-ordinators and Consultants Association of Ontario
Tom Card, Peel District School Board
Nancy Clarke, York Region District School Board
Chuck Hammill, Peel District School Board
Heather Troup, Peel District School Board
Peter Tse, York Region District School Board
Reviewers
Dave Arthur, Ontario Society for Environmental Education (OSEE); Cecil Knight, Kawartha Pine Ridge DSB; Phil Logan, Ed Mahfouz, Patricia Thomas, Ottawa Carleton DSB; Paulette Luft, Philip Marsh, Elaine Sturm, Peel DSB; Dennis Wendland, Waterloo Region DSB and OSEE; Fiona White, Kawartha Pine Ridge DSB and STAO
Lead Board
Peel District School Board
Allan Smith, Project Manager
Partner Boards
Kawartha Pine Ridge District School Board, Ottawa Carleton District School Board, Waterloo Region District School Board, York Region District School Board
Associations
Ontario Society for Environmental Education (OSEE)
Science Co-ordinators and Consultants Association of Ontario (SCCAO)
Science Teachers Association of Ontario (STAO)
Unit 1: Weird Water - Skill Builders
Activity 1 | Activity 2 | Activity 3 | Activity 4 | Activity 5 | Activity 6
Time: 865 minutes
Unit Description
This unit uses some of the unique properties of water as a unifying theme and provides opportunities for the teacher to assess the current status of students with respect to their skills in science inquiry, their knowledge of the safe and appropriate use of equipment, and their ability to work independently, in small groups and as a whole class during instruction. The second overall expectation in each of the Ministry Strands describes the development of cognitive and manipulative science skills, and it is these Expectations that are the focus of this unit.
Strand(s) & Expectations
Strands: Biology, Chemistry, Earth and Space Science, Physics
Expectations:
|
Knowledge / Understanding
|
|
postulates of Cell Theory,
process of cell division, BY1.01 |
|
properties of static
electric charges, PH1.01 |
|
properties, motion and
components of solar system, ES1.03 |
|
models - atomic, subatomic
..... CH1.04 |
|
Skills - inquiry, communication |
|
initiating and planning |
|
• plan and conduct investigation, using tools, BY2.03 |
|
• plan and conduct investigation, using tools, CH2.04 |
|
• formulate questions PH2.03 |
|
• formulate questions CH2.03 |
|
performing and recording |
|
• manipulation of lab equipment calculator, PH2.01 |
|
• manipulation of lab equipment microscope, BY2.02 |
|
• manipulation of lab equipment glassware, CH2.04 |
|
• gather, organize and record information ES2.05 |
|
analyzing and interpreting |
|
• research, evaluate and integrate ES2.04 |
|
• research, evaluate and integrate PH2.05 |
|
• using model CH2.10 |
|
communicating |
|
• scientific ideas BY2.07 |
|
• scientific ideas PH2.07 |
|
• scientific ideas CH2.06 |
|
Applications |
|
how data from different sources
contribute to knowledge ES3.03 |
Activity Titles (Time and
Sequence)
|
Activity |
Title |
Time (minutes) |
|
1 |
Working with Water |
80-100 |
|
2 |
Pond Water |
150 |
|
3 |
Properties of Water |
225 |
|
4 |
Water and Space |
120-150 |
|
5 |
Models of Atoms and
Molecules |
120 |
|
6 |
Culminating Task |
120 |
Prior Learning Required
Teachers should examine the Teacher Support Material (TSM - Ontario Curriculum, Grades 1 - 8: Science and Technology) to gain an understanding of content and skills with which students arrive. This is a diagnostic unit, providing opportunities to assess the knowledge and skills of students as they begin this course.
Unit Planning Notes
Student notebooks should be divided into two parts: Science Notes where students copy or create their notes and a Science Journal where students record their questions and reflect on their learning.
The ‘Wonder Wall’, or a bulletin board where students post Thought Provoking Questions (TPQ.) needs to be organized before the first class. Its use is explained in Activity 1. (See TSM - Glossary: Wonder Wall)
Specific planning for each activity is described in the subsequent pages. However, the following should be noted in advance:
• pond water is required for Activity 2
• access to the Resource Centre / Library
materials is required for Activities 4 and 6
Learning/Teaching Strategies or Activities
|
Activity |
Strategy |
Description |
|
1 |
Mind Map |
Diagnostic in nature,
where students record what they know about water related to the four strands.
The students will work in a whole-class setting and individually. |
|
2 |
Using equipment |
The activity reviews
microscope use and the completion of scientific diagrams. The students will
work individually or in pairs depending on the availability of microscopes. |
|
3 |
Inquiry / Experimental |
This is a hands-on
activity on measurement, collecting and organizing data. The students will
work in small group settings including a jigsaw activity. |
|
4 |
Inquiry / Research |
This is a research
activity conducted in the Resource Centre. The students will work
individually. |
|
5 |
Using models |
This is a teacher-directed
activity on the role and importance of models. The students will work in
small groups. |
|
6 |
Culminating Task |
Students will work
individually. |
Assessment / Evaluation
|
Activity |
Assessing and
Evaluating |
Method or Instrument |
|
1 |
Prior Knowledge |
Mind Map |
|
2 |
Microscope Usage |
Peer check-list |
|
|
Scientific Diagrams |
Teacher evaluated |
|
3 |
Communication and Group
skills |
Rubrics |
|
|
Recording data |
Rubrics |
|
|
Interpreting and analyzing
data |
Rubrics |
|
4 |
Communication skills |
Rubrics |
|
|
Research skills |
Rubrics |
|
5 |
Prior Knowledge |
Science Journal and
checklist |
|
|
Understanding concepts |
Science Journal and Quiz |
|
6 |
Inquiry Skills |
Culminating Task Rubric |
|
|
Understanding concepts |
Mind Map revision and Quiz |
Resources
Scales of Scientific Inquiry
and Technological Design, Peel District School Board, 1998.
Activity 1: Working with
Water (Introduction to Course Expectations)
Time: 80 - 100 minutes
Description
The first activity serves to
introduce the course content, the assessment and evaluation practices employed,
the notebook organization, and to begin some diagnostic tasks. There are four
parts to this activity and they should be presented in the order suggested
here. Other course-beginning procedures, as determined by individual schools,
can be integrated into this first activity.
Strand(s) & Expectations
Strands: Biology, Chemistry, Earth and
Space Science, Physics
Expectations: BY2.02, BY2.07, PH2.03, PH2.07,
CH2.03, CH2.06
These expectations relate to
formulating questions and communicating ideas -- two aspects of the inquiry
process which are stressed in this activity. These will be assessed on many
occasions throughout the course.
Planning Notes
Equipment required:
ebonite rod wool
or fur
rubbing alcohol paraffin
wax
dry cell copper
wire (depending on the demonstrations
planned)
Handouts:
mind map template Achievement
Chart for Science
outline of the Culminating Task rubric used to evaluate the Culminating Task
Any demonstration should be
practised ahead of time. As well, it is necessary to be conversant with the
Achievement Chart for Science and the rubrics for inquiry and the final
assessment task.
Prior Learning Required
None is specifically
required but many students will arrive being familiar with some aspects of
inquiry. For a summary of students’ previous learning refer to TSM - Ontario
Curriculum, Grades 1 - 8: Science and Technology.
Teaching/Learning Strategies
1.1 Student Activity: Students
will observe a number of discrepant event demonstrations related to water.
Students will work on developing their questioning skills. Questions,
observations and inferences should be recorded in the Science Journal. Students
will also post their questions on a bulletin board (the Wonder Wall - see TSM -
Glossary).
Teacher Facilitation: The teacher will perform a number of discrepant
event demonstrations that are related to water. These could include:
• bending of water: charge an ebonite rod by
rubbing it with a piece of wool or fur and hold the charged rod close to a
narrow stream of water
• paraffin in water and in alcohol: set up two
beakers, one containing alcohol and the other containing water, and place a
piece of paraffin wax in each. [Take appropriate safety precautions using
flammable alcohol; some individuals have skin sensitivities or allergies to
alcohols.]
• mini-electrolysis: attach each terminal of a
dry cell to two separate pieces of copper wire and immerse the ends of the wires
in a beaker of acidified water.
The intent of these
activities is to develop the questioning skills of the students. (Refer to
Teacher Support Material, TSM - Questions.) At no time should you explain the
events. Discuss observations and inferences with students. Prompt students to
modify their questions until they are in a form that could be subjected to
investigation – a question on an issue which could be researched, or one which
identifies variables which could be subjected to experimental investigation.
(Refer to Teacher Support Material, TSM - Questions.) A bulletin board should
be set aside for students to post questions. This could be called “The Wonder
Wall” or “TPQ” (thought provoking questions) (TSM - Glossary: Wonder Wall). Throughout the course, as
questions are answered, solutions are posted, and as new questions evolve they
are added. Questions from the Wonder Wall and Science Journal may provide a
starting point for the end-of-course Final Assessment (Unit 6: Making
Connections).
1.2 Student Activity:
Students working in groups will complete the mind map template to the best of
their abilities. At the end of the unit, students will revise their original
mind map.Teacher Facilitation: The
teacher will hand out the mind map sheets (see example that follows and TSM -
Visual Tools) to the class. These will not be evaluated but will be used to
assess some of the students’ prior knowledge and to be used as a starting point
to assess and evaluate learning during this unit.
1.3 Student Activity:
Students will learn that the Achievement Chart for Science is the key tool that
the teacher will use to evaluate their performance in Grade 9 Science. Teacher Facilitation: The teacher will
introduce and explain the Achievement Chart for Science. This should be
explained to the students so that they are aware of the levels from the
beginning. This should be shared with parents and guardians as well. (Some
schools may have a special grade 9 parents’ night.) A way of explaining this to
students is that the various assessments are observations made by you, the teacher, in order to produce an inference, their evaluation in the
course.
1.4 Student Activity:
Students will be introduced to the Culminating Task for the first Unit:
In this task, students will be required to formulate a
specific question based on concepts and/or skills developed during the first
unit. They are to conduct an investigation using the inquiry process (either
experimental or research) to answer their question and produce a written
report.
Students review with the
teacher the rubric for evaluating this Culminating Task.Teacher Facilitation: The teacher will inform students that the
culminating task for this unit mirrors the end-of-course assessment where they
will also investigate a question of their own choice. This activity allows
students to practise skills needed for the final assessment while helping to
diagnose areas of relative weakness and strength.
The rubrics for the inquiry
process (both experimental and research) are found in the Teacher Support
Materials (TSM - Rubrics). They may be used as presented or modified to meet
individual teacher needs. The teacher will remind students to record questions
in their Science Journal and to post questions on the “Wonder Wall” throughout
the unit. Students may be directed to these places to find their question for
the Culminating Task.
If students are having
difficulty coming up with their own questions, several possibilities are
provided below. These should only be given to students if all other means of
developing their own questions have been exhausted.
• What is the cost per year of a water drip
from a leaky tap?
• Where do you find the most microscopic
organisms in pond water, at the bottom of the pond or near the upper surface?
• How does temperature affect the density of a
material?
• Do liquids, other than water, behave in the
same manner when charged objects are brought near to a stream of the liquid?
Why is this so?
• In what ways is water a very special liquid?
• What causes different patterns of water
droplets to form on various surfaces, like glass?
• Is the density of a salt solution (15 g of
salt per 100 g of water) the same as a sugar solution (15 g of sugar per 100 g
of water)?
Assessment/Evaluation
Techniques
The mind map will be used to
estimate the class’s familiarity with the topic. It will not form any part of a
student’s evaluation. Their questioning skills should not be evaluated during
this activity. This will come later as they have more opportunity to practise.
Accommodations
This activity will give you
an opportunity to gauge the need for accommodations for students with special
needs in future activities.
Refer to TSM -
Accommodations for Students with Special Needs
References
Scales of Scientific Inquiry
and Technological Design , Peel District School Board, 1998.
Achievement Chart for Science, The Ontario Curriculum Grades 9 and 10, Science
pp.44-47
Various source books for
demonstrations
Activity 2: Observing Life in Pond Water
Time: 150 minutes
Description
This activity allows for a
review of the skills related to the use of the microscope, as well as concepts
related to The Cell Theory and simple cellular structure. Students will have
the opportunity to apply this knowledge and skill to the study of pond water.
Strand(s) & Expectations
Strand: Biology
Expectations: BY1.01, BY2.02
Planning Notes
Equipment and Materials
needed:
• microscope • copper penny
• cover slips • pond water
• slides - flat & depression • onion skin
• iodine stain
Prior Learning Required
Refer to Teacher Support
Materials (TSM - Ontario Curriculum, Grades 1 - 8: Science and Technology).
Teaching/Learning Strategies
The following sequence is
suggested to develop skills and concepts for this unit.
2.1 Student Activity:
The students will view a variety of materials using a compound or dissecting
microscope. They will then view a penny (Cdn - for leaf structure - is it maple
or sycamore?- and identification, US - for Lincoln between the pillars) using
either microscope. They will draw a detailed scientific diagram of the penny to
practise recording what is seen, not inferred.
Teacher Facilitation: The teacher will discuss appropriate uses of the
compound and dissecting microscopes. (Note - sufficient light reflects off the
penny to allow use of the compound microscope.) The teacher will observe
student use of the microscope, initiate peer assessment of microscope use, and
outline the expectations for scientific diagrams (i.e., stippling, labeling…..).
2.2 Student Activity:
The students will practise making a wet-mount using newsprint (e.g., the letter
“e” lab and a coloured picture).
Teacher Facilitation: The teacher will review proper technique to avoid
creating air bubbles.
2.3 Student Activity: The
students will use a Graffiti or Think-Pair-Share process to verbalize their
understanding of animal and plant cells and the Cell Theory.
Teacher Facilitation: Refer to
the Glossary (TSM - Glossary) for a brief description of the Graffiti process.
Think-Pair-Share is a simple example of a Cooperative Small Group Learning
(CSML) strategy in which students first consider (silently) what they recall
about a topic, then after a minute or two of silent reflection share their
thoughts with one partner. The pair then consolidate their thinking and, under
the teacher’s direction, participate in a sharing session with pairs in the
class.
2.4 Student Activity:
The students will stain and mount an onion skin for viewing of a typical plant
cell, then view a prepared slide of an animal cell. Students will compare
animal and plant cells and state the components of the cell theory using any
format/structure of their choice e.g., notes, tables, diagrams, visual
presentation etc.
Teacher Facilitation: The teacher will review handling of stains,
cellular structures which are stained, and the main observable differences
between plant and animal cells. Safety: Students should avoid skin contact with
biological stains, and should be advised of proper chemical disposal procedures.
2.5 Student Activity:
The students will observe a sample of pond water and draw a protist.
Teacher Facilitation: The teacher will discuss the use of depression vs.
flat slides, importance of scanning the slide and possible protists found in
pond water.
Safety: The teacher will remind students that pond water may contain harmful
organisms and/or pollutants and should be handled with appropriate caution
(wash hands after handling; no contact of pond water with cuts or face, etc.).
Assessment / Evaluation Techniques
• Use a peer check-list (see Attachment A) to
assess the use of the microscope.
• Use a teacher marking scheme to assess the
diagrams drawn.
Accommodations (Special Needs)
Some students may benefit
from working with a peer helper during the microscope exercise, or may need
written instructions.
Refer to TSM -
Accommodations for Students with Special Needs
Resources
Videos on Cell Theory - e.g.
Pomasanoff, A. Director. The Invisible World. Videorecording. The
National Geographic Society. Vestron Video, 1979.
Images from various types of
microscopes
Appendices
TSM - Ontario Curriculum,
Grades 1 - 8: Science and Technology
Attachment
Peer Assessment of Microscope Use
|
Does your partner..... |
Yes / No |
|
|
1. |
carry the microscope with
two hands. |
|
|
2. |
start with the stage down. |
|
|
3. |
locate and focus the
specimen successfully starting with the lowest power. |
|
|
4. |
use the coarse adjustment to
move stage up. |
|
|
5. |
view the microscope from
the side as the stage is raised. |
|
|
6. |
focus on the slide by
turning the coarse adjustment knob away from them. |
|
|
7. |
view the nosepiece from the
side while slowly rotating the objective lenses. |
|
|
8. |
use only the fine
adjustment knob to focus clearly on the slide. |
|
|
9. |
move the nosepiece to the
lowest objective before removing the slide. |
|
|
10. |
return the stage to its initial
position before carrying the microscope back to the cart. |
|
Note: One
should never touch either the eyepiece or the objective lenses directly. Use
only the appropriate tissue on the lenses for the removal of dirt and
fingerprints.
Activity 3: Properties of Water – Density
Time: 225 minutes
Description
In this activity, students
will be expected to determine the relative densities of different types of
material and justify their claim with numerical data. They will work
collaboratively in small-group and large-group settings to complete a task and
practise appropriate measurement skills. The focus of this activity is scientific inquiry and the nature of
experimentation (collect, analyze and interpret data, make predictions and
justify the claim) using the concepts of density, mass, and volume as the vehicle for developing and assessing
those skills.
Strands(s) & Expectations
Strand: Chemistry
Expectations: CH2.04
Planning Notes
Equipment needed:
balances or scales rulers
narrow glass tubes / clear
plastic straws test
tubes
graduated cylinders over
flow cans
computer with spreadsheet
(optional)
items to measure: wood,
rubber stoppers, styrofoam balls, aluminum blocks, lead fishing sinkers.
Materials:
5 different intensely
coloured salt or sugar solutions with densities suggested below (Activity
3.2):
100 g solute in 1 L water with orange food colouring
50 g of solute in 1 L water with blue food colouring
25 g of solute in 1 L water with red food colouring
12.5 g of solute in 1 L of water with green food colouring
6.25 g of solute in 1 L of water with yellow food colouring
Prior Learning Required
Students should have some
knowledge of the concept of density and of variables, and the ability to use
balances, overflow cans and, graduated cylinders. They should also have some
experience at collecting data, reading a meniscus and graphing.
Teaching / Learning Strategies
3.1 Student Activity:
Students view the discrepant events described below and generate questions for
potential use during the Culminating Task.
Teacher Facilitation: The teacher will demonstrate the sinking and
floating of different cans of soft drinks (various brands, regular and diet) in
a tank of water. This is a quick assessment of prior learning - concept of
density. The questions generated should not be answered but should be posted on
the Wonder Wall or in the students’ Science Journal.
3.2 Student Activity:
In Collaborative Small-Group Learning (C.S.G.L.). Students will determine the relative
densities of three coloured solutions given three test tubes, a waste
container, a clear straw / glass tubing and three of the five solutions.
Students will obtain any
three prepared solutions from the front desk in three separate test tubes. They
will determine the relative densities of two solutions by ‘drawing’ about 1 cm
of each of the solutions into the clear plastic straw. This is done by first
inserting the straw 1 cm into a solution, then putting a finger over the top of
the straw, and moving the straw into 2 cm of a second solution without removing
the finger (thus keeping solution one in the straw). The finger is then removed
to allow the second solution to come into the straw. If the two solutions mix,
then solution one is greater in density than solution two. If two distinct
layers are seen, then solution one is lower in density than solution two.
Students can repeat this process to determine the relative densities of their
three solutions. When this is done, each group will record their findings on a
class data chart. Students then use the collective results to determine the
relative densities of all five solutions.
Students will write a brief
explanation in their Science Journals on how they deduced the relative
densities of the solutions.
Teacher Facilitation: The teacher will ensure that different groups have
a different combination of three liquids to test and that no mixing and
contamination of the stock solutions. Create a class recording chart for the
groups.
|
Sample Class Data Chart for Unit 1
Activity 3 (with one group’s data entered as an example) |
||||||
|
Solution Colour |
Group 1 |
Group 2 |
Group 3 |
Group 4 |
Group 5 |
Group 6 |
|
Red |
|
|
|
|
|
|
|
Green |
M |
|
|
|
|
|
|
Orange |
|
|
|
|
|
|
|
Yellow |
L |
|
|
|
|
|
|
Blue |
H |
|
|
|
|
|
Legend: H = highest density of the three solutions
tested
M = middle density of
the three solutions tested
L = lowest density of
the three solutions tested
3.3 Student Activity: Students
will calculate densities in collaborative small groups (C.S.G.L.) using a home
group / expert group structure. Each of the five expert groups will learn one
of the following:
• measuring the mass of solid objects on available balances
• measuring the mass of liquids on available balances
• measuring the volume of irregular objects directly by displacement
• measuring the volume of irregular objects using water displacement into overflow cans
• measuring the volume of regular objects - measurements, mathematical formulae, calculations
Experts will then return to their home groups. The task
of each home group is to measure the volume and mass of at least five samples
of a solid (regular or irregular shape) and five samples of a liquid (one of
the colored solutions from Activity 3.2). For example, group 1 will measure
different sizes of rubber stoppers and five different volumes of the orange
solution; group 2 will measure different sizes of wood and five different
volumes of the green solution; etc. When this is completed, students will have
at least ten sets of data. A tabular data chart may be given to students
beforehand for recording purposes, or students may be asked to design their own
way of recording the data.
Teacher Facilitation: For classes using electronic balances, the teacher
will combine the two mass measurement together to create four expert groups.
3.4 Student Activity:
Home groups will report their collected data to the instructor, who will then
have a comprehensive set of results. Students will then be given all sets of
results and their task is to use the data (graph and calculation) to support
their claim made in Activity 3.2 in which they deduced the relative densities
of the five solutions. Students will plot one graph of mass vs. volume data
showing lines for all five solutions.
Teacher Facilitation: To compile the class data efficiently, it may be
easier if groups input their data into a spreadsheet directly. The teacher will
review graphing techniques, line of best fit and qualitative determination of
the slope of the line (i.e., more dense = steeper slope) using one set of
results.
Pass results to the Math
department for in-depth analysis of data by students.
3.5 Student Activity:
Students will determine from the class data the ‘best’ density value for each
of the solids. Students will sketch one graph (showing relative positions of
lines with no numeric values) for all solid substances. Students will observe
the teacher demonstration on sinking and floating of objects and based on the
result, estimate the density of water and sketch the line (for water) on their
graphs.
Teacher Facilitation: The teacher will place one of each type of the
solids (from the home group activity above) in a tank of water to observe which
substances float and sink.
Assessment /Evaluation Techniques
A variety of assessment and
evaluation instruments is possible. The teacher should not use all, but select
some appropriate ones. Use rubrics developed from the Achievement Chart for
Science and from the samples in TSM - Rubrics.
• calculation of density through performance
task - students are to determine the density of an unknown solution given
appropriate equipment
• communication and group skills using rubrics
• data recording - tabular recording chart or
student design to record data
• data interpretation - group presentation,
written explanation, graphing
• data analysis - graphing, written explanation
• quiz
Accommodation
Some students will need peer
or teacher assistance to interpret class data on liquid densities and to draw
graphs and interpret them. Written instructions and/or visual examples may also
be required for students with language difficulties to help them generate
useful charts and graphs.
Refer to TSM -
Accommodations for Students with Special Needs
Resources
Lincoln County Board of
Education; Lem, V., ed. Growing Collaboratively. Prentice Hall Canada
Inc., Scarborough, Ont.; 1993.
Activity 4: Using the Resource Centre to Inquire about Water and Space
Time: 120- 150 minutes
Description
In this activity students
will formulate a question that pinpoints a topic for investigation. They will
then conduct a research inquiry using a wide variety of print and electronic
resources. Documents, books, articles and other resources will be accessed and
judged critically with attention to usefulness, accuracy, bias, validity, and
authenticity of information. Chosen information from many sources will be
recorded, organized, analyzed and integrated to allow the student to
communicate their answer to the original question. A one-page written report
provides an opportunity for teachers to check writing skills using a diagnostic
assessment. A bibliography will be produced by the student and will be assessed
for both form and content.
Strand and Expectations
Strand: Earth and Space Science
Expectations: ES1.03, ES2.04, ES2.05, ES2.06
Planning Notes
Introduce Activity 4 several
class periods before the actual research time in the resource centre. Students
will need time to formulate their question, and should be encouraged to consult
family members, other students, and friends for ideas.
Co-ordination with the
teacher-librarian is necessary to ensure the success of this activity. Many
resource centres have orientation programs to help students use the library.
Librarians can also help students critique on-line sources of information to
decide if the material is reliable and valid. Critical analysis handouts may be
available in the resource centre. Documentation of sources of information and
organization of a bibliography are also processes that can be directed by the
teacher in concert with the teacher-librarian.
The teacher will focus on
small group interaction, and one-to-one learning opportunities. Students may
require encouragement to stay on track, find and integrate their information.
Monitoring and checking off each stage of work encourages students to complete
manageable portions of the research, and ensures that their time is used
effectively and efficiently. This may be accomplished using a monitoring sheet
developed by the teacher (and the teacher-librarian).
Refer to the Course Notes
for some ideas which may be used as alternatives if a school resource centre is
unavailable.
Prior Learning Required
Students have practised
framing questions, and have also had opportunities to access, organize, and
present information in grades seven and eight. They may not be familiar with
all of the different research strategies available, and should be helped to
expand their skills in this area.
Teaching/Learning Strategies
4.1 Student Activity:
Students will examine the bibliography assessment checklist and the writing
scale rubric for the one page report (TSM - Rubrics)
Teacher Facilitation: The teacher will lead a discussion to clearly
establish the purpose of the research activity and preview assessment
expectations.
4.2 Student Activity:
Students will frame questions that are open-ended, and directed towards
understanding the universe, and our solar system using the underlying theme of
water. Out-of-class time over a few days may be needed for students to develop
a satisfactory question. Students may ask parents, relatives, and friends for
ideas.
Teacher Facilitation: The teacher will ask questions to help students
get started. Starter questions should be on a different, but related, topic.
For example: “Where in the solar system would you be able to mine iron?
Copper?”, or “What is the greatest range of temperature found on the surface on
a planet in the solar system?”
4.3 Student Activity:
Students will use as many resources as possible (print, electronic, community
experts) to help answer their question. Information is evaluated for relevance,
accuracy, bias, completeness, and authenticity.
Teacher Facilitation: The teacher will help students access information
by providing checklists to guide their search. Introduce students to the
concepts of relevance, accuracy, bias, completeness and authenticity of
information sources. Provide critical evaluation sheets to help students
determine the value of information from a variety of resources.
4.4 Student Activity:
Students will choose their five best resources that will help answer their
question. At least one source must be electronic, one source from a journal or
periodical, and one source from a book or encyclopedia.
Teacher Facilitation: The teacher will encourage peer-sharing of
resources to enable students to work co-operatively.
4.5 Student Activity:
Students will record and organize information. All information required for
properly citing references is recorded.
Teacher Facilitation: The teacher will show students samples of
bibliographies. Include examples of on-line citations.
4.6 Student Activity:
Students will write a one-page report that answers their question and includes
an bibliography for their best 5 resources.
Teacher Facilitation: The teacher will remind students to refer to the
writing scale rubric and the bibliography checklist that will be used as the
assessment tools.
4.7 Student Activity:
Students will reflect on the research assignment in their Science Journals, and
comment on why they chose their final resources, the difficulties they
encountered, and their successes. Also, additional questions that may be
investigated for the end of unit Culminating Task should be recorded.
Assessment/Evaluation Techniques
The expectations that will
be assessed include developing skills of Inquiry and Communication.
As the activity is taking
place early in the course, the assessment will be diagnostic in nature, and
will allow the teacher to note and guide the students’ achievement of inquiry
and writing skills. Areas that require remediation should be taken into account
and a plan for upgrading skills developed.
The assessment tools to be
utilized include a checklist for the bibliography, and a writing scale rubric
for the one page report.
No sample checklist has been
included in the profile; the teacher should use the school’s style guide to
create one, or acquire one from the resource centre or another department
within the school. Students in the science classroom should be encouraged to
use the same bibliographic style as is used elsewhere in the curriculum.
Accommodations
It is important to note that
some students may find the writing challenging, but it is necessary to assess
their skills early and provide appropriate support where required. Future
activities will encourage students to use other formats (visual, and oral) to
communicate their ideas.
Refer to TSM -
Accommodations for Students with Special Needs
Activity 5: Models of Atoms and Molecules
Time: 120 minutes
Description:
In this activity, students
will review and extend their knowledge of models in science. They will then use
a model to explain some observations about water.
Strand(s) & Expectations
Strands: Biology, Chemistry, Physics
Expectations: CH1.04, BY1.01, PH1.01, CH2.03, CH2.06, CH2.10
Planning Notes:
Materials required for the
activities include:
variety of models and real
items watch
glasses
tape or modeling clay molecular
modeling kit
material for electrostatics
(e.g. ebonite, plexiglass, plastic rods, fur, wool silk)
Prior Learning Required
Although no specific prior
knowledge of the topics is prerequisite, the teacher will be able to determine
the general background knowledge of the class during the discussion and
brainstorming activities.
Teaching/Learning Strategies
5.1 Student Activity:
Students will be presented with a mixture of models (e.g., model of ear,
skeleton, cell, atom, car, doll, diagram of the Krebs cycle, a mathematical
formula, doll house, symbolic model such as H2O...etc.) and items
that are not models, one at a time, and watch as the teacher places them into one
of two piles. When they feel they know the “rule” for putting them into piles
(i.e., models vs. non-models), students will be invited to select an item and
place it appropriately. This will continue until the students discover the rule
or until it is appropriate to tell them.
Teacher Facilitation: The teacher will present the items to the students
as a game show host might, with lots of enthusiasm and establishing false
patterns at the beginning (e.g., put several items that are obviously science
items, but non-models, into one pile; then place a non science item model in
the other pile; and then hold up a science-based model and have students guess
as to which pile it belongs). This will force students to examine their
reasoning several times during the activity. Follow the initial activity by
discussing with students: characteristics of models (i.e., they are alternate
representations of reality); reasons for using models (object is too small, too
large, too expensive, too dangerous, inaccessible); and types of models
(physical, graphic, conceptual, mathematical).
5.2 Student Activity:
In small groups students will report on chart paper what they think they “know”
about atoms. After each group shares with the class, the groups will then draw
a model of the atom which they feel captures the necessary points presented by
all groups. Groups will then present their model and their reasoning to the
class. A teacher-led discussion will follow, then students will make an entry
into their Science Notebook as seatwork or homework.
Teacher Facilitation: As groups discuss and later draw, the teacher will
move about the class encouraging and questioning groups as appropriate.
Following the presentation of drawings, review or present information
regarding: the components of the atom (i.e., protons, neutrons, electrons); a
simplified Bohr-Rutherford model (nucleus of protons and neutrons, electrons
orbiting the nucleus); and the method by which atoms gain a charge (i.e., gain
of electrons results in a negative charge, loss of electrons results in a
positive charge). Once student questions are discussed, have them make a note
in their Science Notebook about a) models and b) the atomic model.
5.3 Student Activity:
Students, in pairs or small groups, will set up materials according to teacher
instructions. Materials will include a neutral rod (e.g., uncharged ebonite
rod) resting on a watch glass and held in place by tape or modeling clay. The
watch glass is free to rotate. Have students bring charged rods (positive and
negative, one at a time) close to the neutral one and record what happens. Have
them repeat this, but this time using a charged rod on the watch glass as well.
Students then use the model of the atom discussed previously to infer the
movement of electrons and propose a possible explanation for their
observations. Explanations are shared. Students will then extend their
reasoning to offer an explanation of the teacher demonstration which follows.
Teacher Facilitation: As the students work, the teacher will travel about
the class making observations and brief anecdotal notes about student work
methods and participation. Following discussion of student observations and
explanations, repeat the discrepant event from the beginning of the unit
whereby a stream of water is bent using first a positively-charged rod, then a
negatively-charged rod. Question them as to whether water is positively
charged, negatively charged or neutral. Briefly review the atomic structure of
elements and compounds. Then discuss how localized charges can occur within a
neutral molecule (i.e., if electrons tend towards one part of a molecule, that
portion will effectively become negative, while the area with relatively fewer
electrons will take on a positive charge).
5.4 Student Activity:
Students will be presented with two models of water, one linear, the other
bent. They are told that the hydrogen atoms have a slightly positive charge and
the oxygen a slightly negative charge. In a think-pair-share (C.S.G.L.) format,
students will use their knowledge of charges and electrons to defend the model
that better explains their observations of the discrepant events.
Teacher Facilitation: As an alternative to the above activity, teacher may present the correct model of a
water molecule (bent). Students would then relate their observations about the
behaviour of water to the model. Using effective questioning techniques, the
teacher will challenge students to verbalize their thinking and reasoning at
each step. They will likely require reminders of past learning. Remind them of
the Culminating Task and encourage them to jot down questions as they work.
Summarize the activity by
discussing advantages and disadvantages of models and reasons for their
evolution.
Assessment/Evaluation Techniques
• anecdotal comments from class observations
• completion and accuracy of entries in Science
Notebook
• quiz
Accommodations
Activity 5.4 as written may
be used as an enrichment activity.
Refer to: TSM -
Accommodations for Students with Special Needs
Activity 6: Culminating Task
Time: 120 minutes
Description
Students are required to
formulate a specific question based on concepts and/or skills developed during
this first unit. They will conduct an investigation using the inquiry process
(either experimental or research) to answer their question and produce a
written report.
As well, students will
complete a second mind map using the same format as the one done in Activity 1.
Planning Notes
This activity was introduced
during Activity 1. Time must be provided towards the end of the unit so that
students can work on this activity.
Prior Learning Required
Students will use several of
the skills they practised during this unit in order to successfully complete
the Culminating Task.
Assessment/Evaluation Techniques
A rubric for evaluating
inquiry, both experimental and research, and a rubric for evaluating writing
are found in the Teacher Support Materials (TSM - Rubrics).
The mind map should be
compared to the one produced in Activity 1 to assess student learning during
this unit.
Quiz to assess understanding
of concepts.
Accommodations
Refer to TSM -
Accommodations for Students with Special Needs for a number of specific
suggestions for accommodating both academically challenged and ESL/ESD
students. Although some degree of uniformity is desirable in the way in which
students’’ achievement is assessed, the teacher should still provide
alternatives which will maximize each student’’s chance to be successful when
they demonstrate their learning.
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