Physics Module 6 605 Lens and Mirror Lab XXXXXXXXXXPoints Purpose: To study the formation of an image formed by light passing through a convex lens and light reflecting off of a concave mirror....

Physics
Module 6
605 Lens and Mi
or Lab                                 XXXXXXXXXXPoints
Purpose: To study the formation of an image formed by light passing through a convex lens and light reflecting off of a concave mi
or.
Materials:
Virtual simulation in lesson 6.05, page 1, Part C
View prelab video: http:
safeshare.tv/v/LKNWEl6hQ7E
Procedure:
1. Make a copy of this file into your Google drive
2. Collect data from the supplied graphics by clicking the links for each trial
A. Convex Lens
B. Concave Mi
o
3. Complete your table 1 and table 2. Compare the results, answer the analysis questions and conclusion.
4. Download your file, to your computer, save it into your Physics folder and submit for grading
Data collection: (1 point ea.)
Table 1: Convex Lens with ten cm focal distance (f = 10cm)
    Trial #
    do
    di
    Image Characteristics
    
    (cm)
    (cm)
    Size of image
compared to object
Smalle
Larger or
Same Size
    Image
Orientation
Upright o
Inverted
    Image Type
Real or
Virtual
    Trial 1
    30.0
    
    
    
    
    Trial 2
    20.0
    
    
    
    
    Trial 3
    15.0
    
    
    
    
    Trial 4
    6.5
    
    
    
    
    Trial 5
    5.0
    
    
    
    
Data collection cont’d: (1 point ea.)
Table 2: Concave Mi
or with f = 10cm.
    Trial #
    do
    di
    Image Characteristics
    
    (cm)
    (cm)
    Size of image
compared to object
Smalle
Larger o
Same Size
    Image
Orientation
Upright o
Inverted
    Image Type
Real o
Virtual
    Trial 1
    30.0
    
    
    
    
    Trial 2
    20.0
    
    
    
    
    Trial 3
    15.0
    
    
    
    
    Trial 4
    6.5
    
    
    
    
    Trial 5
    5.0
    
    
    
    
Analysis/Conclusion Questions:
1. Describe using physics vocabulary, where a magnifying glass should be placed in order to produce magnification, a larger image. Use trials from the lab to support your description. At least 5 sentences.(5 points)
2. Summarize the common relationship between convex lens and concave mi
or in relation to their image characteristics. At least 3 sentences. (5 points)
o = do (distance object); i = di (distance image); f = f (focal length); M =magnification
     Magnification
     XXXXXXXXXXIt means image is
     M = 1
     The image is the same size as the object.
     M < 1
     The image is smaller than the object.
     M > 1
     The image is larger than the object.
     M = +
     The image is upright.
     M = –
     The image is inverted.
    Convex Lens Trial 1
ack to table 1
    Concave Mi
or Trial 1
ack to table 2
    Convex Lens Trial 2
ack to table 1
    Concave Mi
or Trial 2
ack to table 2
    Convex Lens Trial 3
ack to table 1
    Concave Mi
or Trial 3
ack to table 2
    Convex Lens Trial 4
ack to table 1
    Concave Mi
or Trial 4
ack to table 2
    Convex Lens Trial 5
ack to table 1
    Concave Mi
or Trial 5
ack to table 2

Physics
Module 6
601 Pendulum Lab                                 XXXXXXXXXXPoints
Purpose: To explore the variables that affect the period of a pendulum.
Materials:
Virtual simulation in lesson 6.01, page 3
View the demo.
Collect data from this video
Graphing tutorial for Google SheetsPendulum equation: XXXXXXXXXXy = kx^½
PART 1. Use the demo.
Hypothesis: Before you do the next steps in the procedure, predict what will happen to the swing time if you construct a pendulum with the same length, but with more mass as the bob, wider amplitude or different lengths.
· Fill the blanks with what you feel is appropriate (increased or decreased).
Table 1 : Hypothesis (1.5 pts)
    Mass
    If mass is increased, the period of the pendulum will __
    Amplitude
    If amplitude is increased, the period of the pendulum will __
    Length
    If length is increased, the period of the pendulum will __
Test each variable and state your observations (1.5 pts) View the demo.
1. As the mass was increased, the period of the pendulum _________.
2. As the amplitude was increased, the period of the pendulum ______.
3. As the length was increased, the period of the pendulum _________.
    Procedure:
    
    1. Choose five different rod lengths between 0.5 and 2.0 meters.
2. Ensure damping is set to 0, starting angle is 10°, gravity is 9.8 m/s2, and mass of ball is 250 g. Set the stop time at 60 s.
3. Run the simulation by pressing the play button and measure the time for 10 complete swings of the pendulum, then press pause. For L=0.50 m, the time should be around 14.3 seconds
4. Calculate the time for one swing of the pendulum. The answer should be 1.43 s.
5. Enter the data in table 2. Alternatively you can collect data from this video Don’t forget to add the value (0,0) to your data table below. Make sure to have column headers, and select them along with the data, when inserting the chart. The graph is NOT LINEAR, make sure to make the adjustments to obtain the equation of “best fit”. As explained visually in the graphing visual for Google Sheets
PART 2
Table 2: Length Data (10 pts)
    Length (m)
    Period (s)
    0
    0
    
    
    
    
    
    
    
    
    
    
Graph (6 pts)
Use Google sheets to graph your data, and insert the screen shot of the graph. Be sure to follow your graphing ru
ic (variables, labels, title, scale, plots and graph line) and use this graphing tutorial for help graphing in Google sheets)
As explained visually in the graphing tutorial and graphing visual: Choose "Series" from the Chart Edito
Customize menu>Series>Check Trendline>Choose “Power Series”. Choose “label”>”use equation”.
{Insert Graph here}
Analysis and Conclusion Questions (9pts):
1. What type of relationship is present between T and L? (linear, parabolic, hype
olic) (3 pts)
2. The pendulum equation is: T = 2π sqrt (L/ g) where, g = 9.81 m/s2
Use the pendulum equation to calculate L if the period T = 1.0s? Show your calculations (3pts)
Given
Unknown
Equation
Substitute
Solve
3. Use the pendulum equation to calculate the period of a 1.50 m pendulum. Show your calculations. (3pts)
Givens
Unknown
Equation T = 2π sqrt (L/ g)
Substitute
Solve
4. The following data has been gathered by another lab group. Analyze the data using your graph as the template. Can you detect an experimental e
or in the group's data? (2pts)
Here is the data in a spreadsheet, graphed and fitted.
    Length (m)
    Period (s)
    0.80
    0.94
    0.60
    0.78
    0.50
    0.75
    0.30
    0.56
    0.10
    0.38
    0
    0

Physics
Module 6
606 Snell’s Law Lab                                 XXXXXXXXXXPoints
Purpose: To determine the index of refraction of unknown “stolen” materials and identify each material to determine “Who stole the diamonds!” using Snell’s Law
Background: For any light that is traveling from one medium of index of refraction n1, at angle of incidence θ1, to another medium of index of refraction n2, Snell’s law of refraction describes the angle of refraction, θ2, experienced by the light.
n1 sin θ1 = n2 sin θ2
index of refraction = n1
angle of incidence = θ1
index of refraction = n2
angle of refraction = θ2
For air, the index of refraction is equal to 1, because the speed of light in air is nearly equal to the speed of light in a vacuum. Whenever air is the medium of incidence of the light, Snell’s law can be simplified.
n2 = sin θ1/ sin θ2
Light travels at different speeds in different media. As light passes at an angle from one medium to another, it changes direction at the boundary between the two media. The index of refraction of a medium, n, is the ratio of the speed of light in a vacuum, c, to its speed in the substance, v.
n = c/v
XXXXXXXXXXn = index of refraction
c = speed of light in a vacuum = 3.10^8 m/s
XXXXXXXXXXv = speed in a different medium
When light enters a medium with a higher index of refraction than the medium it is leaving, it bends toward the normal. When light enters a medium with a lower index of refraction than the medium it is leaving, it bends away from the normal. This change of direction of light at the boundary of two media is called refraction.
Materials: Use the pictures below to collect the results into the data table
Procedure: Watch 6.06 Step by Step Tutorial, if needed or this tutorial for the PhEt simulation
1. Collect data for the angle of incidence and the angle of refraction from the given evidence files for each suspect and trial.
2. Calculate the index of refraction for medium 2 (n2) for each suspect for each trial, using Snell’s law.
3. Use the index table to determine the unknown materials for each suspect
4. Using the chart below of various indices of refraction for various media, identify your mystery material you had in your experiment.
Data: (0.5 points ea.)
    Trial
    Angle 1 θ1 (degrees)
    Angle 2
θ2 (degrees)
    Sine of the angle Sin θ1
    Sine of the angle
Sin θ2
    n2 = sin θ1/sin θ2
(show your work here)
    Identify Mistery Material (using table below)
    1
    60
    26.81
    0.866
    
    
    
    2
    
    
    
    
    
    
    3
    
    
    
    
    
    
    4
    
    
    
    
    
    
    5
    
    
    
    
    
    
    6
    
    
    
    
    
    
Scroll down to answer the analysis questions and conclusion
Materials: Use these pictures to collect the results into the data table
    
    
    
    
    
    
    
    
    
    
    
    
Analysis questions: (2 points ea.)
Use this tutorial for the PhEt simulation
1. Which way does light bend when traveling from air to glass? (Toward the normal, away from the normal or it does not bend). Please write in your answer and explain your reasoning