Thursday, November 19, 2015

Lesson Plan for Considine’s Science classes: 601, 602, 603, 613

Lesson Plan for Considine’s Science classes: 601, 602, 603, 613
The textbooks and workbooks are located in the back of 509.  Please return the books to 509 at the end of the period so the next class will be able to use them.  The students are NOT to write in the notebooks; they are to write ALL of the information in their Science Notebooks. 
A.  Science Workbook
1.   Page 27-29: ALL
2.   Page 30: Complete, Summarize, Connect It
3.   Page 31: Predict, Define
4.   Page 32: Organize, Analyze
5.   Page 33: Model, Connect It

B.   Science Textbook
1.   Page 73: Launch Lab
2.   Page 84: Physical Setting-Define
3.   Page 94: Bionic People

C.   Science Article due Monday!



Monday, November 16, 2015

Chapter 3 HW

1. C3S1 pp. 74-76, RC, BQ, Applying Math #1-2, SC#1, Glossary work
2. C3S2, self check #1, p. 84 Physical Setting "Define"; Find 3 examples of a machine making work easier. Glossary input force
3. C3S3 – Vocabulary, RC, BQ, p. 87 Physical Setting “Design”

Work = Force x Distance





A. 

1. ____ is the use of _____ to move an object some ________.
2. What are the units for Force?
3. What are the units for Distance?
4. What is a Joule (J)?
5. Energy = Work    <----- Explain!


Friday, October 30, 2015

Energy Sources


1. Watch the BrainPOP video, "Energy Sources", take the Quiz, then write the answers in your Science Notebooks.



2. Play the , "What is Energy?" game.  
Match all the types of energy correctly, then answer the following questions in your Science Notebooks.
A. Why do we need energy?
B. What are the different forms of energy? 
C. Pick three forms of energy; where do you see evidence of each form of energy as you complete this assignment?
D. Put the following information into your own words: You can change energy from one type to another.
E. Complete the Quiz; how many did you get right?

http://www.childrensuniversity.manchester.ac.uk/media/services/thechildrensuniversityofmanchester/flash/whatisenergy.swf

3. C2S1; vocabulary, Physical Setting p. 44, RC, BQ, SC #1-5

4. •C2S2 (pp. 48-53); vocabulary, RC, BQ, SC #1-5
5. •C2S1: read pp. 44-46, 

6. •HW:  C2S3 pp. 55-57 – RC, BQ, vocabulary, Physical Setting p. 57,SC #1
Brainpop – “fossil fuels” video and quiz
7.  a. Finish C2S3 SC #1,2,4
 b. C2 Visualizing Main Ideas and Chapter Review
 # 2, 3, 5, 6, 7, 8, 10-22, 24, 26, 27, 30 29, 31

Wednesday, October 28, 2015

Chapter 2 Review


Energy transforms...

from www.dictionary.com:
energy  (ěn'ər-jē) Pronunciation Key
The capacity or power to do work, such as the capacity to movean object (of a given mass) by the application of force. Energycan exist in a variety of forms, such as electrical, mechanical,chemical, thermal, or nuclear, and can be transformed from oneform to another. It is measured by the amount of work done,usually in joules or watts.
 A. Types of Energy:
     1) Potential Energy is the energy of position.  An object's mass andheight give an object its potential energy.  The greater the mass or the higher an object is, the more P.E. an object has.
  Potential Energy = (mass)(gravity)(height) or P.E. = mgh

     2) Kinetic Energy is the energy of movement, motion.   An object's massand speed/velocity determine its kinetic energy.  The greater the mass and the more speed an object has, the more K.E. an object has. 
Kinetic Energy = 1/2(mass)(velocity)(velocity) or K.E. = 1/2 mv2     




B. Forms of Energy
Energy can come in a variety of forms.

1. Atomic/Nuclear Energy is produced when you split atoms. 
Examples:Atomic bombs, nuclear power plants, and the sun.




2. Chemical Energy - is really a form of potential energy and is the energy stored in food, gasoline or chemical bonds.
Examples: Striking a match, food, batteries.  


3.  Electrical Energy - Energy produced by electrons moving through a substance is known as electrical energy. We see evidence of electricity in household appliances, electric outlets, phone chargers, electric wires.
Examples: MP3 players, computers, video games, holiday light wires.


4. Mechanical Energy - is the energy of movement. All moving objects have mechanical energy. Examples: bicycles, machine parts, subway trains, wheels, us!
M.E. = P.E. + K.E.
  

5. Sound Energy- is produced when a solid, liquid or gas vibrates. Sound energy travels out as waves in all directions.
Examples: Voices, sirens, horns and musical instruments.





 6. Radiant Energy - is light energy, that when absorbed by an object, gets converted to thermal/heat energy. 
 Examples: A light bulb, the glowing coils on a toaster, the sun, and even headlights on cars. 




7. Thermal Energy - is the energy of molecular movement.  The faster the molecules move, the more thermal energy is present.  Heat is the transfer of thermal energy i.e. when thermal energy moves from object to object, we feel it as heat.




C. Generating Electricity!!!
- Electrical energy is needed in our daily lives.  Imagine what life would be like if all those appliances that you plug in on a daily basis were to disappear...   No refrigerators, no MP3s, no television, no hot water, etc.

Power plants use a generator to generate electricity.  A turbine turns the generator.  Mechanical energy is needed to turn the turbine, usually in the form of steam pushing against its blades.  Now, all we need is a source of thermal energy to boil the water into a gas.
 


Monday, October 26, 2015

Potential Energy vs. Kinetic Energy Illustrations

Potential Energy vs. Kinetic Energy
*Task*
You have seen many examples of PE/KE.  Your task is to create your own illustration of Potential and Kinetic Energy in action. 

Your illustration must include the following: A. Maximum KE, B. Minimum KE, C. Maximum PE, D. Minimum PE, E. Increasing KE, F. Decreasing KE, G.  Increasing PE, HDecreasing PE
*Include an explanation for each label*

*Due Date: Wednesday 10/28/15*

Friday, October 23, 2015

Potential/Kinetic Energy Videos

Watch the videos and answer the questions underneath them in your science notebooks.
A. 1. What is happening when potential energy is converted to kinetic energy?  Describe the actions.
     2.  Pretend you are an animator; create a cartoon of your own involving Potential and Kinetic                   Energy, and be sure to label both PE and KE.  

B. 1. Kinetic energy increases when the ____ and/or ______ of an object increases.
     2. Potential energy increases when the ____, ______ or ___________ of an object increases.
     3. Give an example of Potential Energy converting to Kinetic Energy, and an example of KE                  converting to PE.  You can either write a short paragraph or draw an illustration/cartoon of this.



C. 1. ______ is the ability to do work.
     2. Energy cannot be _______ or _________, it can only be ______ or ___________.
     3. Energy can take two forms: _________ Energy and ________ Energy.
     4. _________ Energy is stored, whereas ______ Energy is based on motion or speed.
     5. Give an example of PE and an example of KE; draw a picture!

D. 1. What is the law of conservation of energy?  Put it into your own words.
     2. Energy is __________ from one type to _______.
     3. At the bottom of the rollercoaster, describe the Potential Energy and why this is.
     4. Kinetic Energy deals with the energy of velocity or _____.

E. Energy in a Roller Coaster Ride
"This interactive roller coaster ride produced by WGBH illustrates the relationship between potential and kinetic energy. As the coaster cars go up and down the hills and around the loop of the track, a pie chart shows how energy is transformed back and forth between gravitational potential energy and kinetic energy."
Play with the interactive roller coaster ride here: http://www.pbslearningmedia.org/asset/mck05_int_rollercoaster/
How does the PE and KE change at each of the 6 steps?  Think of the position and speed at each position.  

F. 

Energy 101: Electricity Generation



Friday, October 2, 2015

Chapter 1 HW

(1) C1S2 pp. 12-20 
a. vocabulary
b. blue questions
c. reading check
d. self check Q/A #1,2
e.  Mini-Lab p. 14
f. Applying Math p. 17


(2) HW: C1S1
1.Read pp. 6-7, 11
2.Reading Check Q/A
3. Fig. 7 Blue Q/A
4. Self Check Q/A #1-5
5. Vocabulary

(3)  Text p. 35 -Visualizing Main Ideas

(4) pp. 36-37 Ch. 1 Review #1-3,5,6,9-11,13-18, 21, 23, 25, 28

Wednesday, September 9, 2015

What is Science?

What is Science? 
Watch the video, and answer these questions in your Science Notebooks: What have you learned from it?  What did you already know?  Is there anything else you could add to the video?  Explain.












Tuesday, February 10, 2015

3rd Quarter HW

HW:       1. Science Artices: Mass, Volume, Density; Matter; Matter


2. Text pp. 122-123 “Float or Sink”
a. definitions
b. Blue Q “Communicate”
c. Applying Math #1, 2
d. p. 124 Physical Setting “Define”
e. p. 125 Self Check #3


3.  c4s1: vocabulary, bq, rc, sc #1-4

4. •C4S2 – Vocabulary, Blue Question, Reading Check, Self Check #1-4,6


5.  C4 Visualizing Main Ideas.
 C4 Review: #1,2,5,6,7,11,13-15,21,22,24,25

6. C5S1 pp. 136 – 139 ; vocabulary, reading check, PS “Explain” p. 138, Applying Math p. 138, self check # 1,3,4

7. C5S2: vocabulary, RC, BQ, p.142 Mini-LAB, SC #1-6

8. Chapter 5 Review pp. 156-157 #2-5, 7-9, 11-23, 25-28

LAB #5 – Measurement: Mass, Volume, and the Exploration of Density

LAB #5 – Measurement: Mass, Volume, and the Exploration of Density

Introduction
Volume is the amount of space occupied by matter - solid, liquid, or gas.
Volume is measured in units: cm3 for a solid, mL for a liquid. 

Problem
-         A: How can we find the volume of a rectangular block? 
-         B: How can we find the volume of an irregularly
           shaped object?

Hypothesis:
-

Materials
-         Various sized blocks, irregular shaped objects, ruler, graduated cylinder

Procedure A
 1) Use a metric ruler to measure the dimensions of your rectangular objects; measure to the nearest tenth (0.1) cm.
 2) Calculate the volume in cm3 of your rectangular object by multiplying the length (cm) times the width (cm) times the height (cm). V = L x W x H
 3) Record your measurements in the data table.

Results A
Data Table: Volume of rectangular objects
        
Object
length (cm)
width (cm)
height (cm)
Volume (cm3)
 A



 
 B




 C




 D



  





E





   






V = L x W x H
cm3 = (cm)(cm)(cm)

Procedure B
Use a graduated cylinder to measure the volume of an irregular shaped solid. 
1. Fill the graduated cylinder to 50 mL and record this into your notebook.  This is your initial volume.
2. Carefully drop the object in on an angle.  The object will displace water (push water up to make way for the object) which will rise to make a new volume.
3. Subtract your initial volume from the new water level.

 Results B
Final Volume --------------à                _____mL
- Initial Volume ------------à                 _____mL
=Volume of irregularly shaped object: _____mL

Analysis B
1)  What is the maximum volume you can measure with this graduated cylinder?
2)  What is the smallest volume you can measure with this graduated cylinder?
3)   Determine the value of the minor grids on the cylinder.  i.e. how many mL does each line equal?
4)   Now, check to see if you’ve measured correctly using the Volume of a sphere equation:                                                    
Volume of sphere using equation:_____cm3

 Procedure C
The mass of an object is a measure of the number of atoms in it. The basic unit of measurement for mass is the gram (g).
You are going to calculate the densities of the wood blocks using the equation, Density = Mass/Volume.  You already have the volume of wood blocks A, B, C, D, and E in the data table for Results A.  You will use a triple beam balance to find the mass of each block, and then use the equation to find their volumes.  As always, make sure to include the proper units and round to the nearest tenth. 
Results C
Density = Mass/Volume 
Object
Mass (g)
Volume (cm3)
Density
 ( g/cm3 )
A



B



C



D



E




Units:
Mass =        grams  =       g
Volume = cubic cm =     cm3 
Density = ___     hint: D=M/V
Analysis C

1)  Calculate: Combine the densities of blocks A, B, C, D and E to find the average density for the wood.  Show your work.
2)  What is the maximum mass the triple beam balance can measure?
3)  What is the minimum mass the triple beam balance can measure?
4)  What are the units for the triple beam balance?
5)  Why is it called a triple beam balance?  What does each beam measure; think in numerical terms.
6)  Why is it necessary to zero your triple beam balance before using it?


Analysis B
1) What is the maximum volume you can measure with this graduated cylinder?
2) What is the smallest volume you can measure with this graduated cylinder?
3)  Determine the value of the minor grids on the cylinder.  i.e. How many mL does each line equal?
4) Now, check to see if you’ve measured correctly using the Volume of a sphere equation:                                     
5) How can you use a graduated cylinder to measure the volume of a liquid?
6) What happens to the volume of the liquid when you drop an object into the graduated cylinder?  How can we use this to help us find the volume of the object?
7) If an object dropped into the graduated cylinder pushes up the water mark from an initial volume of 25 ml to a final volume of 51.5 ml, how many cm3 is the object?
8) Compare the two different methods of obtaining volume of a marble, how did you do?  How far off were your calculations?
9) Go back to Lab #2 – Crazy Coasters
Mass of glass marble:    _____
Volume of glass marble: _____
Density of glass marble: _____
Predict: Would you expect the glass marble to sink or float based on its density?  Why? 
10) Marble (glass), Wood blocks (wood), Water (liquid H2O): List them in order from least dense to most dense; use data from this lab to support this. 


  **Round each answer to the nearest tenth**
++Include units++

Conclusion

 What was your problem?
 Restate your hypothesis.  Was it right? wrong?  why or why not?
 What did you learn in this lab?
 What did you like about this lab?
 What were some challenges you had to deal with?
 What could you do next with this problem?  What other tests could you perform?
 Write down any other additional thoughts, observations, inferences, etc.