p06 labnotes
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PhysicsTRANSCRIPT
P 06 Lab Notes
PHYSICS LAB NOTES
FOR
MECHANICS, HEAT
AND
SOUND
EXPERIMENTS
PHYSICS 6Los Angeles Harbor College
J. C. FU
R. F. WHITING 1992Eighteenth Edition
August 2005
TABLE OF CONTENTS
1.Measurement 1
2.Acceleration Due to Gravity 7
3.The Addition of Vectors10
4.Projectile Motion14
5.Newtons Second Law17
6.Centripetal Force (Thistle Tube Method20
7.The Coefficient of Friction23
8.Conservation of Mechanical Energy27
9.The Ballistic Pendulum30
10.Torque and Center of Mass34
11.Archimedes' Principle37
12.The Coefficient of Linear Expansion41
13.The Heat of Fusion of Ice44
14.Standing Waves on Strings47
15.The Speed of Sound in Air50
The set of lab experiments that you will be doing this semester will, hopefully elucidate for you some abstract concepts, enable you to test a few hypotheses or theories using the scientific method, realize the capabilities or limitations of certain equipment and procedures, and to think analytically.
Each lab period will begin with a presentation / discussion of the experiment indicated in your lab notes. Come prepared, having read the references given. An attempt has been made to have the labs run in parallel with lecture. Share work with your partner so that each person will have an opportunity to have hands-on experience.
J. C. Fu, Ph.D.
R. F. Whiting, M.S.
Experiment 1: MEASUREMENTPURPOSE:
To determine the precision of measurements made using different devices for measuring length, mass and time, and to learn to report data with the appropriate number of significant Figures.
INTRODUCTION:
The three basic units in the SI system of units are the meter, kilogram, and second.
For measurement of length we will use micrometers, vernier calipers, and tape measures. When using the micrometer, be sure to take account of the zero reading of the instrument. For all the various measuring devices, with the exception of the vernier caliper, estimate to the nearest tenth of a division in order to get the most out of the instrument. For measurement of mass, we will use the double pan balance. If the mass of your object exceeds the capacity of the balance, use a counter mass on the other pan.
The electric stop clock will be used to measure time. The 60-Hertz oscillations assure the accuracy of these devices.
It is good practice to tabulate (put in table form) your data whenever possible.
Now to say something about precision and accuracy. Precision is a measure of how reproducible a measurement is, for example, if one measures an eraser 3 times, using the same ruler, and gets the following readings: 5.2 cm, 5.1 cm, and 5.3 cm, the result can be expressed as 5.2 0.1 cm. The 0.1 indicates the precision of the result. The accuracy of a measurement is an indication of how close the measurement is to the true or accepted value.
SUPPLIES & EQUIPMENT:
Tape measure
Micrometer
Metric ruler
Vernier caliper
Metal cylinder
Meter stick
Wire gauge
Wire and nail samplesDouble pan balance
Metronome
Rock samples
Electronic balance
100-gram slotted massElectric stop clock
PROCEDURE:
A.LENGTH
1.Determine the area of the classroom floor in square meters. Make three separate measurements of both the length and width and report your result with the average deviation.
2.Measure the diameter and length of a metal cylinder using the micrometer and a ruler. Then measure it again by using the vernier caliper. Calculate the volume. Observe the rules for the use of significant Figures.
3.Using a wire gauge, measure the diameter of a length of wire. Measure it again, this time with a micrometer. Compare the results, and number of significant Figures that can be recorded in each case.
B.MASS
1.Determine the mass of a 100-gram slotted mass on the balance and record your result with the appropriate uncertainty. Repeat the measurement on the electronic balance.
2.Determine the mass of an irregularly-shaped object such as a rock.
C.TIME
1.With the electric stop clock, time 50 beats of the metronome set at 120. Calculate the beats per second and the beats per minute. Repeat three times and calculate the average value.
2.With the electric stop clock, time 50 beats of your own or your lab partner's pulse. Calculate the beats per second and the pulse rate (beats / min.). Repeat three times for the same person and determine an average value.
MICROMETER
VERNIER CALIPER
An example of how to read the vernier caliper when making a measurement:
1.The zero line on the lower or vernier scale points up to 2.1 cm (plus a fraction of a millimeter) on upper or main scale. (Note where the long arrow is pointing on the diagram above.)
2.The 5th line on the vernier scale happens to line up with a main scale line (any line), therefore the last digit is 5. (Note where the short arrow is pointing on the diagram above.)
3.Any line on the vernier scale that lines up with a main scale line is the last digit. Thus, the length of the object is 2.15 cmWIRE GAUGE
DATA: MEASUREMENTI. LENGTH
a) Tape Measure*: Floor
Width Deviation = | Width - Average Width |
W
Width (m)
Average Width (m)W
Deviation (m)
Average Deviation (m)
___________________( _________________
Length Deviation = | Length - Average Length |
L
Length (m)
Average Length (m)L
Deviation (m)
Average Deviation (m)
___________________( _________________
* Measure to the nearest millimeter(Less than 10 m ( 4 sig. figs.)
(Greater than 10 m ( 5 sig. figs.)
Area Calculations:
Average area
= X
= ____________ m2Positive deviation of Area:A+ = ( + ) ( + )= ____________ m2
Negative deviation of Area:A = ( ) ( )= ____________ m2Average deviation of area =
= ___________ m2 Area of room = _____________ _____________ m2
Average area Average deviation
A =
b) Micrometer (diameter) (4 significant Figures); Ruler (length) (3 significant Figures)
ItemLength (m)Diameter (m)Radius (m)Volume (m3)
Metal Cylinder
c) Vernier Caliper (3 significant Figures)
ItemLengthDiameterRadiusVolume
Metal Cylinder
cmcmcmm3
mmmcm3
d) Wire Gauge* (3 sig. Figures) & Micrometer** (3 sig. Figures)
ItemWire GaugeMicrometer
DiameterDiameter
Wire(inches)(cm)(m)(mm)(m)
* 1.00 inch = 2.54 cm
** To the nearest 0.01 mm
II. MASS (For 100 gm. or more:Pan Balance: 4 significant Figures
Electronic Balance: 5 significant Figures
For less than 100 gm:Pan Balance: 3 significant Figures
Electronic Balance: 4 significant Figures)
ItemPan BalanceElectronic Balance
Mass (g)Mass (kg)Mass (g)Mass (kg)
Slotted Mass
Rock
III. TIME Electric Stop clock (3 significant Figures)
Object# BeatsTime (s)Beats/secondBeats/minuteAve. Beats/min.
Metronome
____________
Object# BeatsTime (s)Beats/secondPulse Rate =
Beats/minuteAve.Pulse Rate Beats/min.
Pulse
____________
Experiment 2: ACCELERATION DUE TO GRAVITYPURPOSE:
In this experiment, the numerical value of the acceleration due to gravity will be determined by a graphical technique.
INTRODUCTION:
If one neglects the effects of air friction, objects relatively close to the Earth's surface undergo uniformly accelerated motion. For our purposes, we will take this value of acceleration to be 9.80 m/s2.
In this experiment, the data are obtained by analyzing a wax paper tape that has a series of spark dots. The apparatus that produces the tape sparks every 1/60 of a second as the free-fall body descends. Thus a time-distance record of the object in free fall is produced and the acceleration due to gravity can be calculated.
By definition, acceleration is the time rate of change of velocity, so a plot of the instantaneous velocity vs. time should yield a straight line, the slope of which is the acceleration. For each spark interval, the average velocity is readily calculated, being the distance the object falls in the interval divided by time it takes to fall that interval distance. Use the fact that the average velocity is equal to the instantaneous velocity at the midpoint in time of the interval.
SUPPLIES & EQUIPMENT:
Demonstration free fall apparatus
Meter stick
Spark tape
Plastic triangle
Metric ruler
Masking tape
Average velocity = = =
PROCEDURE:1.Obtain a spark tape, secure it to the table with masking tape and draw a straight line perpendicular to the long direction of the tape, through every other dot. Start at the third or fourth dot down from the top. You should obtain about ten intervals. Number the perpendicular lines 0 through 10.
2.Measure and record the interval distances between each three successive dots, starting with 0 - 1, then 1 - 2 and so forth. Enter your data in the table.
3.Calculate the average velocity for each of your intervals by dividing the interval distance x by the elapsed time for each interval. The elapsed time is 1/30 second. Plot these average velocities on the y-axis vs the corresponding midpoint in time on the x-axis. Draw the best straight line for the data points by fitting the line so that the line is the closest it can be to all the data points. Note that the line does not necessarily have to pass through any particular point.
4.Calculate the slope of your straight line. This is done by dividing the rise (change in y) by the run (change in x) for any two points on the line, not necessarily data points, since it is possible that no data points lie on the line. Choose the two points so that they are widely separated. Slope = V/t = a = g (experimental)
5.Calculate the percent error of the value of g you obtain from your graph when compared to the given value of 9.80 m/s2.
% error = X 100 %
DATA: ACCELERATION DUE TO GRAVITYData and Calculations Table: (Measure to a fraction of a millimeter.)
Interval #
Interval Distance x
(m)Interval Time t
(s)Average Velocity
(m/s)Time from Zero to
Midpoint in Time
(s)
0 11/301/60
1 21/303/60
2 31/305/60
3 41/307/60
4 51/309/60
5 61/3011/60
6 71/3013/60
7 81/3015/60
8 91/3017/60
9 101/3019/60
Acceleration due to gravity (from graph) = ________ m/s2
% error ___________
Experiment 3: THE ADDITION OF VECTORS
PURPOSE: To establish the condition for equilibrium of a suspended metal object.
INTRODUCTION:The first condition for equilibrium is that the vector sum of the forces (the net force) acting on an object is zero:
F = 0
in a two-dimensional problem this becomes:
Fx = 0, and Fy = 0.
SUPPLIES & EQUIPMENT:
Force table
Slotted masses
Electronic balance
Metal cube (brass or iron)
Metric ruler
Protractor
50-gram mass holder
Circular bubble level
PROCEDURE:
A.ADDING FORCES WITH THE SAME MAGNITUDE BUT DIFFERENT DIRECTIONS.
1.Level the force table using a spirit level.
2.Determine the mass of a metal cube ___________ grams, ___________ kg, on the electronic balance.
3.Determine the weight of this metal object ___________ N. W = mg, where g=9.80 m/s24.Clamp three pulleys along the edge of the force table as in fig. 1., with A = 10o, B = -10o, and c = 180o (position of cube).5.Apply forces FA and FB of the same magnitude to balance the weight of the metal cube (at C) by placing masses on the hangers at A and B.
6.Record FA, FB and in data table 1.
7.Repeat steps 4 and 5, with: A = 30o, B = -30o and A = 50o, B = -50o
8.Using the graphical method, add the vectors head-to-tail to determine the resultant FR of FA and FB. Use a ruler and protractor to draw the vectors to scale and be sure to specify the scale you are using. (for example 1N = 3 cm). Enter the data in data table 1. (See Fig. 2.)
Fig. 1
Fig. 2
DATA AND CALCULATIONS Table 1: VECTOR ADDITION
A
BFA(N)FB(N)FR(graphical method)
(N)W
Object Weight
(N)| f |
Frictional Force
(N)
+ 10o- 10o
+ 30o- 30o
+ 50o- 50o
For Example :
FA = mA* g = ( ________ kg) X (9.80 m/s2) = ____________ N
* Note that mA includes the mass of the mass hanger.
At Equilibrium: F = FR + (-W) + Frictional Force = 0
| Frictional Force | = | f | = | FR - W |
B. Adding forces of different magnitudes and directions.
1.Balance the weight of the metal cube, W, with FA and FB of different magnitudes and different angles A and B on the force table. See Fig. 3a.
2.Calculate the resultant of FA and FB using the components method. See Fig. 3b which shows the components of FA.
Fig. 3a
Fig. 3b
DATA AND CALCULATIONS Table 2:A = ______________ B = ______________
VECTOR ADDITON
FA = ______________ FB = ______________
Vectorx-Component
(N)y-Component
(N)
FAFxA =FyA =
FBFxB =FyB =
FRFx = FxA + FxB =Fy = FyA + FyB =
FAx = FA cos A FBx = FB cos B FAy = FA sin A FBy = FB sin B
FR = ;
tan = Fy / Fx ( = tan-1 (Fy / Fx)
1.FR = _________________ at ____________ Degrees (from + x-axis)
2.Weight of Load (Metal Cube) = ___________ N at 180o (from + x-axis)
Experiment 4: PROJECTILE MOTION
PURPOSE:
The object of this experiment is to determine the initial velocity of a projectile from the range and time-of-flight measurements. Also, the equations of motion will be used to predict the point of impact of a projectile.
INTRODUCTION:
A projectile is any object in motion through space, which no longer has a force propelling it. Examples are: thrown balls, rifle bullets, falling bombs and rockets (after the propelling force is gone).
In order to determine the initial velocity of a projectile fired horizontally, one first makes use of the equation y = gt2 to calculate t, the time of flight; where t=. Then, from a measurement of the range (horizontal distance) the initial velocity, vo , can be determined from the equation s = vot .
For a projectile fired at an angle, the range of a projectile can be determined if the angle of elevation, the initial velocity and the initial height of the projectile above the landing point are known.
SUPPLIES & EQUIPMENT:Ballistic pendulum apparatusLarge cardboard
Inclinometer
Plain white and carbon paperMetric ruler
Catch box
Spirit level
Wooden board for inclined plane "C" clamp
Short support rod
Clamp and rod for inclined plane Plumb bob
One and two meter sticks
Fig. 1, Part A
PROCEDURE:
A.INITIAL VELOCITY1.Be extremely careful not to hit anybody with a projectile during this experiment.
2.Clamp the gun (not too tightly) to the table, using the inclinometer to orient the gun to fire horizontally and take a trial shot. Tape a large piece of cardboard to the floor centered on the spot where the projectile landed. On top of the cardboard, tape a carbon paper and a plain paper to record the point of impact. Use one of the boxes supplied to catch the projectile (ball).
3.Take six shots. Measure the range of each shot accurately. Record your values for the ranges in the data table.
4.Measure the height from the floor to the bottom of the ball, this is y and is the vertical displacement of the projectile. Use a plumb bob to get the exact vertical direction. Calculate the time of flight from this measurement:
t =
5.Calculate the range and the average initial velocity. vo = .
DATA FOR PART A: PROJECTILE MOTIONData and Calculations Table: Initial Velocity, vo
Trialy*
(m)Averagey
(m)s**
(m)
(m)
1__________________________________
2
3
4
5
6
* 3 sig. figs. ** 4 sig. figs.
Part A Calculations:
Time of Flight
t =
Initial Velocity
vo = .
Average Initial Velocity, vo ____________
Ballistic Gun # ____________B.PREDICTION OF THE RANGE1.Clamp the spring gun to a board at an arbitrary angle of between 10o and 20o. Measure this angle precisely with an inclinometer.
2.Measure the height of fall, y (= yf - yi).
3.Calculate the expected range. Fire the projectile and measure the range. Fire the projectile five more times and determine an average measured range.
4.Calculate the percent difference between the measured and calculated range. Compare the results.
Data for Part B:
Angle of Elevation () ________________(degrees)
Height from floor to the bottom of ball, y ___________ m
Data and Calculations Table: Measured Range
Measured Range x
(m)Average Measured Range
(m)
_____________________________________
Part B. Calculations:
Average Initial Velocity, vo = __________ (From part A)
vox = vo cos = __________
1.) y = voy t + EQ \f(1,2) gt2
voy = vo sin = __________
2.) EQ \f(1,2) gt2 + voy t - y = 0
3.) At2 + Bt + C = 0
Quadratic Equation
A = EQ \f(1,2) g = ___________ (g = - 9.80 m/s2)
B = voy = ___________
C = - (y) = ___________ (y is negative, therefore C is positive)
See Fig. 2
= __________ s (Choose t such that it is a positive number)
Expected Range:
x = vox t
Expected range, x _________________ m
Percent difference in measured and expected range _________________ %
Experiment 5: NEWTON'S SECOND LAW INTRODUCTION:
The acceleration of an object is directly proportional to the resultant force acting on it and inversely proportional to the mass being accelerated. Furthermore, the direction of the acceleration is in the direction of the resultant force.
F = ma(Newton's Second Law)
Using an air track, the acceleration of masses due to an unbalanced applied force will be determined, and compared with the acceleration calculated from the equation of motion for a uniformly accelerated object.
From Newton's 2nd law:
F = (m1 + m2)a
m2g = (m1 + m2)a
Solving for a:
From the equation of motion:
s = vot + at2. With vo = 0, .
SUPPLIES & EQUIPMENT:
Air track and accessories 5 & 10-gram slotted massesElectronic balance
Thread and scissors 5-gram mass holder
Fig. 1. Experimental Setup
PROCEDURE:
1.Level the air track by adjusting the leveling feet and balancing glider at the center of the air track. Turn air supply off when this is accomplished. Do not lean on the air track or the table (use another table for writing) during the experiment.
2.Determine the glider's mass m1 on a balance and convert this measurement to kilograms.
3.Place photogate #1 at the position x1 = 80 cm and photogate #2 at the position x2 = 150 cm.
4.Place a 5-gram mass holder at the end of the thread running over the pulley. Add a 5-gram mass onto the mass holder, so now, m2 = 10.0 grams = 0.0100 kg.
5.Set the photogate stop clock to the "pulse" mode. and push the "reset" button. Set the resolution scale to 1ms. Set the memory switch to the on position. Make sure the air is flowing steadily before you let go of the glider.
6.Turn on the air supply. Delicately hold the glider as close to the light beam of gate # 1 as possible (just before the LED on top of the gate lights up). Then release glider (do not push or pertube the glider) and record the displayed time.
7.Reset the stop clock and repeat the procedure two more times. Average the three values and record in the data table.
8.Add a 5-gram mass onto the mass holder. Repeat steps #5 and #6. (Remember that m2 equals the mass of the holder plus the mass on the holder, so the total mass for this step is 15 g.)
9.Repeat step #8 for m2 = 20 grams (including hanger). and m2 = 25 grams (including hanger).
10.Calculate the acceleration of the masses by using the equation of motion:
s = vot + EQ \f(1,2) at2 ,
s = | x2 - x1 |
with vo = 0,
s = EQ \f(1,2) at2( a = EQ \f(2s,t2) 11.Compare this calculated acceleration with the value calculated using Newton's law F = ma.
Fnet = W = m2g
Fnet = (m1 + m2)a
DATA: NEWTON'S SECOND LAWData and Calculations Table:
m1
(kg)
m2
(kg)0.01000.01500.02000.0250
s*
(m)
Time, Trial 1
(s)
Time, Trial 2
(s)
Time, Trial 3
(s)
Average Time
(s)
Acceleration from: ak = 2s/t2(m/s2)
Force from: F = m2g
(N)
Accelerated mass: m1 + m2(kg)
Acceleration from Newtons
2nd Law: aN = F/(m1 + m2)
(m/s2)
% difference = X 100%
* Measure carefully each time.
Experiment 6: CENTRIPETAL FORCE -
THISTLE TUBE METHOD
INTRODUCTION:
In this experiment we will study the motion of an object travelling in a circular path. A small object of known mass will be rotated in a circular path. The centripetal force will be determined directly and then calculated from measurements of the radius and the velocity. The following relation will be verified:
Fc =
SUPPLIES & EQUIPMENT:
Thistle tube
String & scissors# 5 Rubber stopper
Masking tapeRed felt markerHooked masses, 50g, 100g & 200g
Stop clock
Meter stick
Electronic balance
PROCEDURE:1. Determine the mass of a stopper. Tie a 1.5 m length of string to the stopper, then thread it through the thistle tube. Tie a 0.150 kg mass to the other end of the string. The weight of this mass creates the tension in the string that provides the centripetal force on the stopper.
2. To help you maintain the radial distance, use a dot of red ink as a marker at the top edge of contact with the thistle tube.
3. Using the stop clock, measure the total time for 25 revolutions for two different values of radial distance. Try values close to 0.500 m and 0.750 m. The time for one revolution is the total time divided by 25.
4. Maintain a steady horizontal swing.
5. The velocity is given by the equation:
v = EQ \f(circumference,time for 1 revolution) = EQ \f(2pr,T) where r is the radius of the circular path and T is the time for one revolution.
6. Repeat the above procedure for a 0.200-kg mass attached to the string.
7. What factors contribute to error in this experiment?
DATA: CENTRIPETAL FORCEData and Calculations Table 1:
Mass of Stopper, m (kg)
Radius, r (m)
**
Time for 25 Revolutions (s)
Time for 1 Revolution, T (s)
Velocity, v = 2r/T (m/s)
Velocity2 = v2 (m/s) 2
A. Experimental Fc = mv2/r (N)
Hanging Mass, M (kg)
0.1500.200
B. Centripetal Force from Fc = Mg (N)
Percent error
of centripetal force A relative to B
*Approximately 0.500 m
% error = (A B) / A X 100 %
Data and Calculations Table 2:
Mass of Stopper, m (kg)
Radius, r (m)
****
Time for 25 Revolutions (s)
Time for 1 Revolution, T (s)
Velocity, v = 2r/T (m/s)
Velocity2 = v2 (m/s) 2
A. Experimental Fc = mv2/r (N)
Hanging Mass, M (kg)
0.1500.200
B. Centripetal Force from Fc = Mg (N)
Percent error
of centripetal force A relative to B
**Approximately 0.750 m
Experiment 7: THE COEFFICIENT OF FRICTION PURPOSE:
The object of this experiment is to demonstrate some of the principles of dry friction and to determine the coefficients of kinetic and static friction for wood-on-wood surfaces.
INTRODUCTION:
In this experiment, we will investigate some of the principles of friction, such as: 1.The coefficient of static friction, s, is usually greater than the coefficient of kinetic friction, k. 2.The frictional force, f, is proportional to the normal force, FN. 3.Friction always acts in a direction opposite to the motion of an object.
SUPPLIES & EQUIPMENT:
Friction board
Friction BlockMeter stick
String & scissors
Inclinometer
Metric ruler
Electronic balance
Masking tapeClamp & rod for inclined plane
Slotted masses
Spirit level
Clamp-on pulley
PROCEDURE:A. COEFFICIENT OF STATIC FRICTION
We will determine the coefficient of static friction by tilting the board at an angle. At the point where the angle is just enough to cause the block to slip (overcome friction), we have:
Fig.1: Experimental setup for Part A
with associated forces showns = f / FN Fx = 0: f + (-mg sin = 0
f = mg sin
Fy = 0: FN + (-mg cos = 0
FN = mg cos
s =
s = tan
1. Place the block at the top of the inclined board. Experimentally determine the angle at which the block just breaks loose and starts sliding down the incline, using an inclinometer.
2. Repeat step 1-A five times and calculate an average value for the angle , and then calculate the coefficient of static friction s = tangent
Data For Part A:
Data and Calculations Table 1: Coefficient of Static Friction.
fs = s FNs = = = tanTrial
Average tan = s
1
2
3
4
5
Average value of coefficient of static friction: s = ________________
B. COEFFICIENT OF KINETIC FRICTION
The coefficient of kinetic friction will be determined by making use of the fact that the frictional force is proportional to the normal force, f = kFN .
Fig. 2. Experimental setup for Part B
with associated forces shown.
1. Determine the mass of the friction block and record its mass on the data sheet.
2. Level the friction board on the table. Clamp a pulley on one end. Tie a string and mass hanger to the block. Place slotted masses on the hanger until the block starts moving with constant velocity once given a slight push. The force pulling on the block is the applied force to overcome kinetic friction and is equal and opposite to the kinetic friction force. Mark the place on the board with a piece of tape where you start the block in order to start the block at the same place each time.
3.Repeat step 2-B four more times, each time adding 100 additional grams to the top of the block.
4. Plot a graph of the magnitude of the force of friction, | f |, on the y-axis vs. normal force on the x-axis. The slope of the graph can be used to calculate the coefficient of kinetic friction.
Fig. 3: Sample graph
Data For Part B:
Data and Calculations Table 2: Coefficient of Kinetic Friction.
At constant velocity,Fx = 0
(f + T = 0
Fy = 0
T m2g = 0
Trial12345
Total Sliding Mass
m1(kg)
Normal Force
FN = m1g(N)
Hanging Mass m2(kg)
Applied Force m2gN)
Magnitude of
Frictional Force(N)
Value of coefficient of kinetic friction from graph, k = _____________
Experiment 8: THE CONSERVATION OF
MECHANICAL ENERGY
INTRODUCTION:
Though conservation of energy is one of the most powerful laws of physics, it is not an easy principle to verify. If a boulder is rolling down a hill, for example, it is constantly converting gravitational potential energy into kinetic energy (linear and rotational), and into heat energy due to the friction between it and the hillside. It also loses energy as it strikes other objects along the way, imparting to them a certain portion of its kinetic energy. Measuring all these energy changes is no simple task.
This kind of difficulty exists throughout physics, and physicists meet this problem by creating simplified situations in which they can focus on a particular aspect of the problem. In this experiment you will examine the transformation of energy that occurs as an air track glider moves down an inclined track. Since there are no objects to interfere with the motion and there is minimal friction between the track and glider, the loss in gravitational potential energy as the glider moves down the track should be very nearly equal to the gain in kinetic energy. In the form of an equation, we have:
KE = (mgh) = mgh
where KE is the change in kinetic energy of the glider, KE = mv22 mv12 and (mgh) is the change in its gravitational potential energy (m is the mass of the glider, g is the acceleration of gravity, and h is the change in the vertical position of the glider).
SUPPLIES & EQUIPMENT:
Air Track & accessory kit
Meter stick
Electronic balance
2 Shim blocks, about 1 cm thick
Vernier caliperPhotogate timer
Accessory photogate timer
Glider
Air supply
Photogate timer transformer
PROCEDURE:
PART A:
1. Level the air track as accurately as possible by setting the glider at the middle of the track and adjusting the leveling screws until there is no movement of the glider. Once leveled, do not lean on the table or push down on the glider.
2. Measure D, the distance between the air track support legs. Record the distance above table A to the nearest millimeter.
3. Place a block of known thickness, H, under the support leg of the track. For greater accuracy, the thickness of the block should be measured with a vernier caliper. Record the thickness of the block above table A to the nearest tenth of a millimeter.
4.Set up a photogate timer and an accessory photogate as shown in the figure below.
Fig. 1: Equipment Setup.
5.Measure and record d, the distance the glider moves on the air track from where it first triggers the first photogate, to where it triggers the second photogate. You can tell where the photogates are triggered by watching the LED on top of each photogate. When the LED lights up, the photogate has been triggered. As always when measuring with a metric ruler, your measurement should be to the nearest millimeter.
6.Measure and record L, the length of the glider. (The best technique is to move the glider slowly through one of the photogates, and measure the distance it travels from where the LED first lights up to where it just goes off.)
7.Measure and record m, the mass of the glider.
8.Set the photogate timer to GATE mode, leave the memory function in the "off" position, and press the RESET button.
9.Hold the glider steady near the end of the air track, then release it, (don't push), so it glides freely through the photogates. Record t1 the time during which the glider blocks the first photogate and t2 the time during which it blocks the second photogate.
Notice that t2 = ttotal - t1. (Photogate timer first displays t1 , then ttotal= t1 + t2 , and does not display t2 by itself.)
10.Repeat the measurement four times and record your data in table A. You need not release the glider from the same point on the air track for each trial, but it must be gliding freely and smoothly (minimum wobble) as it passes through the photogate.
PART B:
1.Repeat procedure A with a block of greater thickness, H '. Record data in Table B.
CALCULATIONS:
1. Calculate , the angle of incline for the air track, using the equation = sin-1(h/d). Since sin= h/d = H/D, you can calculate h = d (H/D), which is the distance through which the glider drops vertically in passing between the two photogates.
2.For each set of time measurements:
a.Divide L by t1 and t2 to determine v1 and v2, the velocity of the glider as it passed through each photogate.
b.Use the equation KE = mv2 to calculate the kinetic energy of the glider as it passed through each photogate.
c.Calculate the change in kinetic energy, KE = KE2 - KE1.
D = distance between
supports
d = distance between
photogates
H = block thickness (distance
air track leg raised)
Fig. 2: Elevations
d.Calculate the average value of KE = KE2 - KE1, and calculate mgh. Find the percent difference between them. A small value of this percent difference is expected from the law of conservation of energy.
DATA SHEET: CONSERVATION OF MECHANICAL ENERGY
Part A: D = ____________ H = ____________ L = ____________ d =____________
h = ____________ = ____________ m =____________
Data and Calculations Table A
Trial12345
t1 (s)
t1 (s)
v1 (m/s)
v2 (m/s)
KE1 (J)
KE2 (J)
KE2 - KE1 (J)
Average KE = ____________ mgh = ____________ % difference = ____________
PART B: D = ____________ H = ____________ L = ____________ d =____________
h = ____________ = ____________ m =____________
Data and Calculations Table B:
Trial12345
t1 (s)
t1 (s)
v1 (m/s)
v2 (m/s)
KE1 (J)
KE2 (J)
KE2 - KE1 (J)
Average KE = ____________ mgh( = ____________ % difference = ____________
Experiment 9: THE BALLISTIC PENDULUM
In this experiment we will determine the initial velocity of a projectile by using the principles of the conservation of momentum and the conservation of energy.
INTRODUCTION:
A device called a ballistic pendulum will be used in this experiment to determine the initial velocity of a projectile. The device consists of a spring gun that propels a metal ball of mass m into a pendulum bob of mass M. This pendulum-ball combination then swings up onto a rack with a velocity v just after impact. The change in height h through which it rises depends directly on the initial velocity vo of the ball.
In order to derive an expression for the initial velocity vo of the projectile, we can make use of the law of conservation of linear momentum, expressed as:
Momentum Before Impact = Momentum After Impact
mvo = (m + M) V
vo = V Eq. 1
The second part of the process involves the pendulum-ball combination emerging with initial velocity v, then rising from h1 to h2. The conservation of energy for this part can be expressed as:
KE1 + PE1 (at h1) = KE2 + PE2 (at h2) 0
KE1 - KE2 = PE2 - PE1 ; since v2 = 0(m + M)V2 = (m + M)gh2 - (m + M)gh1
(m + M)V2 = (m + M)gh v2 = gh
So
V =
Eq. 2
Substituting the expression for V from Eq. 2 into the momentum Eq. 1, we have:
vo =
EMBED Equation.3
Eq. 3
SUPPLIES & EQUIPMENT:
Ballistic pendulum apparatus
Ruler
C-clamp
Electronic balance
Spirit level
PROCEDURE:
1. Level the apparatus on the lab table using a spirit level. You may need to shim the apparatus. Lightly clamp the apparatus to the table using a C-clamp. Once leveled and clamped, do not lean on the table or otherwise disturb the level of the apparatus.
2.Determine the position (hi) of the center of mass of the stationary pendulum relative to the base plate. The center of mass is indicated by the pointed projection on the side of the pendulum.
3. Determine the mass of the ball and record it on the data sheet.
4. Fire the gun six times, each time recording the number of the notch in which the pendulum comes to rest.
5.Calculate the average notch number. Place the pendulum at this average position and determine the height (hf) from the base plate to the pendulum center of mass. Calculate h=hf - hi.
6.Calculate the velocity of the ball and pendulum just after impact. V = .
7. Calculate the initial velocity of the ball: vo = V.
8. Calculate the energy loss in Joules. The kinetic energy before impact is mvo2, and immediately after impact the kinetic energy is (m+M)V2. What percent of the original kinetic energy was "lost" to non-conservative work? Where did this energy go?
DATA SHEET: BALLISTIC PENDULUMBallistic pendulum number ______________ (See label on equipment)
Mass of Pendulum
______________ (See label on equipment)
Mass of Ball
______________ kg
Data Table 1: Pendulum Height Measurements
TrialNotch #TrialNotch #TrialNotch #
135
246
Average Notch #
hi = height of pendulum when hanging freely
______________ m
hf = height of pendulum at average notch number
______________ m
h = hf - hi
______________ m
Initial velocity of ball: vo =
EMBED Equation.3 (Eq. 3)
____________ m/svo from Experiment 5, Projectile Motion
____________ m/s
% difference between the two vo
____________
Velocity of pendulum & ball after impact, V = (Eq. 2)
____________ m/s
Momentum before collision: mvo =
____________ kg-m/s
Momentum after collision: (m+M)V =
____________ kg-m/s
Is momentum conserved in this inelastic collision?
____________
KEi before collision: mvo2 =
____________ J
KEf after collision: (m + M)V2 =
____________ J
Is kinetic energy conserved in this inelastic collision?
____________
Energy loss: Wnc = KE + PE
Wnc = KEf KEi) + PEf - PEi)
Wnc = KEf KEi) + m + M)gh
____________ J
% energy loss: X 100% =
____________ %
Experiment 10: TORQUE AND CENTER OF MASSPURPOSE:
The object of this experiment is to use the method of balancing torques to determine the center of mass of a non-homogeneous meter stick, and to determine the unknown mass of an object.
INTRODUCTION:
If a rigid object is in rotational equilibrium, the net torque acting on it, about an axis, is zero. This equilibrium condition can be stated as:
= 0
where = Fd, F is the applied force, and d is lever arm. The lever arm is the distance from the axis of rotation (the fulcrum) to the point where the downward force is applied. The plus sign {+} corresponds to a counter-clockwise torque and the negative sign {-} corresponds to a clockwise torque.
The center of mass, denoted here by CM, is the point at which the mass of the object can be considered to be concentrated. The position x of the CM of a non-homogeneous meter stick can be determined by balancing the torque of the stick on one side of the fulcrum with the torque of a known mass on the other side of the fulcrum.
Having established the position of the CM and knowing the mass of the stick, the same procedure can be used to determine the unknown mass of another object.
SUPPLIES & EQUIPMENT:
Weighted meter stickKnife edge clampScissors
Metal cube
Electronic balance
Knife-edge standHooked massesLight string
PROCEDURE:
A. CENTER OF MASS OF A NON-UNIFORM METER STICK
1.Record the mass of the non-uniform meter stick m1 indicated on the electronic balance.
2.Set up the apparatus as shown in Fig. 1, making sure that the fulcrum is at the midpoint of the stick. Slide m2 in along the stick until the stick is in equilibrium. Record m2 and d2. Be sure to include the mass of the string in the mass of m2.
3.Use Eq. 1 to estimate the lever arm, d1, the distance of the meter stick CM from fulcrum. Then calculate x, the position of the meter sticks CM relative to the weighted end of the stick. This equation is obtained from the equilibrium condition:
counter-clockwise+ clockwise= F1d1 - F2d2 = 0
F1d1= F2d2
d1= d2 = d2
d1 = d2 = distance of CM from fulcrum
Eq. 1
x = position of CM from weighted end
= fulcrum position minus d1
Fig. 1
4.Move the fulcrum 5.0 cm away from the midpoint, toward the weighted end of the stick as shown in Fig. 2. Slide m2 to establish equilibrium. Record m1 and m2 and the new value of d2, the lever arm measured from the new fulcrum position. Use Eq. 1 to calculate the new value of d1 from the fulcrum position to obtain your second estimate of x. The position of the CM of the stick is x.
Fig. 2
5. To obtain your third estimate of x, remove m2 and balance the stick on a knife edge clamp. The meter stick is balanced because its CM is resting on the knife-edge clamp which is at the fulcrum of the system. Record x, the position of the CM from the weighted end of the stick.
B. DETERMINATION OF AN UNKNOWN MASS1.Having calculated the position of the center of mass on the previous page, set up the apparatus as shown in Fig. 1 by moving the fulcrum back to the midpoint of the stick. m2, a metal cube, will be the unknown mass.
2.Using a string, hang the unknown mass on the stick and slide it along the stick to balance.
3.Record the new value of d2. Use Eq. 2 to obtain your estimate of the unknown mass, m2.
= 0 , so F1d1 + ((F2d2) = 0 and F2 = d1 , giving m2g = d1.
m2 = d1
Eq. 2
4.Weigh the metal cube on the electronic balance and find the percent difference between the two measurements of m2.
C. MULTIPLE-TORQUE SYSTEM: FINDING THE MASS OF A METAL CUBE
(Use the same m2 as in Part B)
1. The equilibrium condition can be used even when there are several torques involved. Set up the apparatus as shown below:
Fig. 3
2. Use Eq. 3 to obtain another estimate of the unknown mass m2.
= 0 , so F1d1 + F2d2 ( F3d3 - F4d4 = 0 giving F2 =
m2 = Eq. 3
3.Find the percent difference between this measurement and the value obtained directly from the electronic balance.
DATA SHEET: TORQUE AND CENTER OF GRAVITYData Table A: Determination of the Center of Gravity
Fulcrum Position
m1 (stick)
(kg)m2(kg)d1(m)d2(m)x
(m)
At midpoint
(Steps 1 3) Fig. 1*
At 5.0 cm from midpoint
(Step 4) Fig. 2
At CM
(Step 5)
Data Table B: Unknown Mass m2
m1 (stick)
(kg)d1(m)d2(m)m2 (from Eq. 2)
(kg)
= 0
(Steps 1-3) Fig. 1*
Unknown mass from weighing
(Step 4)
Percent Difference _________________
Data Table C: Multiple Torque System. (Unknown mass m2, same mass as in Part B.)m1(kg)d1(m)m3(kg)d3(m)m4(kg)d4(m)d2(m)m2 (from Eq. 3)
(kg)
Fig. 3
= 0*
Percent Difference ___________________
Experiment 11: ARCHIMEDES' PRINCIPLE PURPOSE:
Archimedes' Principle will be used to determine: a) the density of a symmetrically-shaped object; b) the density of an irregularly-shaped object; and c) the specific gravity of a liquid.
INTRODUCTION:
Archimedes' Principle states that an object that is submerged in a fluid is buoyed up by a force that is equal in magnitude to the weight of the fluid displaced by the object. This force is called the buoyant force, or the buoyancy. The buoyant force can be determined experimentally with the following setup:
Fig. 1
Fig. 2
T1 = Wo (Weight of object in air)
T2 = Waw (Apparent weight of object in water)
Wo = mog
T2 = Wo ( FB
Waw = Wo ( FB
Therefore FB = Wo ( Waw (Eq. 1)According to Archimedes' principle, the buoyant force,
FB = Ww
or
FB = mwg Since
mw = wVw then FB = wVwg, and the volume of water displaced by the immersed object can be expressed as
Vw = FB /wg
(Eq. 2)Key to symbols:
mo = mass of object (in air) , W o= weight of object in air
Vo = volume of object
maw = apparent mass of object in water (fluid)
Waw = apparent weight of object in watermw = mass of water displaced
Ww = weight of water displaced
w = density of water = 1000 kg/m3
Vw = volume of water displacedTHE DENSITY OF AN OBJECT
When an object is totally submerged in water (a fluid) , the volume of water displaced is equal to the volume of the object.
(Volume of submerged object) Vo = Vw (Volume of water displaced) (Eq. 3)Since the volume of an object is Vo = mo / o , and volume of the fluid displaced is
Vw = FB /wg., then (Eq. 3) becomes
mo / o = FB /wg
Density of the object can be expressed as
o = w
(Eq. 4)The buoyant force FB can be determined from the apparent weight loss, FB = (Wo - Waw). It can also be determined from the weight of the water displaced.
SUPPLIES & EQUIPMENT:
Double pan balance150-ml beaker
Lab jack
600-ml beaker
250-ml graduated cylinder
Rock sample
Unknown fluid
Vernier caliper
Hydrometer
Short support rod
Table clamp
Overflow can
String & scissors
Small paper clips
Metal cube
PROCEDURE:
A.DENSITY OF A METAL CUBE1.Measure the length of one side of the metal cube. Calculate the volume of the cube Vo.
2.Suspend the cube from a beam balance mounted on a support rod as in Figure 1 and determine its mass, mo.
3.Immerse the suspended cube in a beaker of water as in Figure 2. Determine the apparent mass of the cube in water, maw.
4.Determine the buoyant force (FB = Wo ( Waw) in newtons. (Eq. 1)
5.Determine the density of the cube from o = w. (Eq. 4)
B.DENSITY OF AN IRREGULARLY-SHAPED ROCK
1.Suspend a rock from the beam balance and determine its mass, mo in kilograms.
2.Immerse the suspended rock in a beaker of water as in Figure 2.
3. Determine the apparent mass of the rock immersed in the fluid, maw in kilograms.
4.Determine the buoyant force, FB = Wo ( Waw, in newtons (N). (Eq. 1)
5.Determine the density of the rock from o = w. (Eq. 4)
6Determine the mass of a 150-ml beaker mb = _______________ kg.
7.Place the displacement can on a level surface near the edge of a sink. Fill it with water, and let the excess drain off into the sink.
8.Slowly lower the rock into the water, allowing the displaced water to flow into the small beaker. Weigh the beaker with displaced water. mb+w = _______________ kg.
9. Determine the mass of the water displaced,( mw = mb+w mb).__________kg
10. Determine the weight of water displaced, Ww= mwg = ____________N. This is equal
in magnitude to the buoyant force FB, according to Archimedes principle.
11 .Determine the density of the rock by applying (Eq.4), o = w. _________kg/m3C.SPECIFIC GRAVITY OF AN UNKNOWN LIQUID.
1With the same cube used in Part A, determine the buoyant force, FB (fluid) on the metal cube by immersing it in an unknown fluid.
FB (fluid) = Wo ( Waf.
Wo = weight of object in air.
FB (fluid) = mog ( maf g
Waf = apparent weight of object in fluid.
2.Calculate the density of the fluid using equation (5).
In Water: o = =
In Fluid: o = =
Therefore, = ,and f =
Eq. 5)where o = density of metal cube in air, w = density of water and f = density of Fluid
3. Calculate the specific gravity, S.G. = .
4.Fill a tall measuring cylinder with the unknown fluid. Use a hydrometer to measure the specific gravity of the fluid.DATA SHEET: ARCHIMEDES' PRINCIPLE
A. Metal Cube
Mass of cubemo= __________ kg
(i)Apparent mass of cube in watermaw= __________ kg
Buoyancy FB = mog ( mawgFB= __________ N
Density of cube o = w= __________ kg/ m3
(ii)Length of sideL= __________ m
Volume of cube V= __________ m3
Density of cubeo =
= __________ kg / m3 (iii)Density (known)= __________ kg / m3B. Rock
Mass of rockmo= __________ kg
(i)Apparent mass of rock in watermaw= __________ kg
Buoyancy FB = mog ( mawgFB= __________ N
Density of rock o = w =__________kg/ m3
(ii)Mass of water displaced mw= __________ kg
Weight of water displaced Ww = mwg = FB= __________ N
Density of rock o = w =__________ kg/ m3C. Specific Gravity
Mass of cube (from part A)mo= __________ kg
Apparent mass of cube in fluid maf= __________ kg
Buoyancy FB(fluid) = mog ( mafgFB= __________ N
Density of fluid f = w =__________kg/ m3
Specific gravity f / w
= __________
Specific gravity measured with hydrometer
= __________
Experiment 12: T HE COEFFICIENT OF
LINEAR EXPANSION PURPOSE:
The purpose of this experiment is to measure the coefficient of linear expansion for various metals and to compare the results with the known values.
INTRODUCTION:
In most cases, when materials are heated or cooled, they undergo expansion or contraction respectively. From the standpoint of materials science, this process must be taken into account when designing structures that are subjected to temperature variations. Otherwise, tensile or compressive stresses might develop which could destroy the structure.
The linear (one-dimensional) coefficient of expansion is defined as the fractional increase in length divided by the temperature change. This coefficient is designated by the Greek letter alpha (), and is found to be almost constant over a wide range in temperature. In equation form, the definition of is:
=
where L is the change in length, Lo is the original length, and T is the temperature change in degrees Celsius.
In this experiment, the value of the linear coefficient of expansion of several rods of common metals will be determined. The length of the rod is measured at room temperature, then steam is passed over the rod with the resulting temperature increase causing it to expand. The amount of expansion is measured with a dial indicator. The coefficient is then determined using the data gathered.
SUPPLIES & EQUIPMENT:
Linear expansion apparatus
Dial indicator
Aluminum, copper and steel rods
Electric steam generator
0 - 100 oC Thermometer
Glycerine
Meter stick
PROCEDURE:
1. Measure and record the initial length of the rod Lo, to the nearest millimeter. Determine and record the ambient temperature (room temperature).
2. Set up the apparatus as shown in Figure 1. The steam jacket for the rod has an opening for steam, thermometer, and rod ends, and an outlet for the condensed steam. Fill the steam generator about 2/3 full of water and turn on the generator, but do not connect the generator to the expansion apparatus as yet. Insert the rod in the apparatus until it just makes contact with the dial indicator probe and is in firm contact with the screw at the other end.
Fig. 1. Linear Expansion Apparatus with Associated Equipment
3.Make sure that the dial indicator is firmly screwed onto its holder and that the graduated ring is tightened down. See Fig. 2. Record the initial reading of the dial indicator, to the nearest 0.01 mm (= 0.00001m).
Fig. 2 Dial Indicator (Micrometer Gauge)READING THE DIAL INDICATOR:
Example:
The gauge to the left indicates 0.07mm
The gauge below indicates 0.14 mm
4. When the generator is generating steam briskly, connect the steam tube to the inlet on the apparatus. Warning! Be careful not to scald yourself.
5. Allow the steam to warm up the rod to a constant maximum temperature, Tmax. When the rod stops expanding, record the final reading of the dial indicator.
Calculate T = (Tmax ( T ambient).
6.Calculate the change in length, L = Final reading - Initial reading.
7. Calculate the coefficient of expansion and record it on the data sheet. Compare your values with the known values of the coefficient of linear expansion by calculating the percent difference.
8. Repeat the above procedure for two other rods. Be careful not to burn yourself on the hot metal. When finished, dry the equipment thoroughly.
DATA SHEET: COEFFICIENT OF LINEAR EXPANSIONAmbient Temperature _________________ oC
Data and Calculations Table:
Type of Rod
Aluminum
Copper
Steel
Lo (m)
Initial Reading of Dial Indicator (m)
Final Reading of Dial Indicator (m)
Tmax (oC)
T (oC)
L (m)
(oC-1)
Known (oC-1)
2.4 X 10-51.7 X 10-51.1 X 10-5
Percent difference
Experiment 13: THE HEAT OF FUSION OF ICEPURPOSE:
The value of the latent heat of fusion for water will be determined by the method of calorimetry.
INTRODUCTION:
When a substance such as water undergoes a change of state from the solid phase to the liquid phase, not all of the heat energy that is added to the system is reflected in a change of temperature of the substance. Some energy is needed to break the bonds between the molecules of the substance and this energy is called the latent heat of fusion of the substance.
In today's experiment the latent heat of fusion will be determined by the method of mixtures and by applying the principle that the heat lost is equal to the heat gained (conservation of energy).
In this experiment, an ice cube is placed into a measured amount of warmed water and is left to melt, cooling the water in the process. By noting the temperatures before and after melting, the heat of fusion is then calculated as follows:
HEAT GAINED:by ice cube = (heat needed to melt the ice) + (heat for warming the melted ice)
Qi = mi Lf + micw(Tf - 0oC)
HEAT LOST:by water = (mass of water) X (1.00 cal / g.oC) X (temperature change)
Qw = mwcw(To - Tf)
cw = Specific heat of water.
by calorimeter = (mass of calorimeter) X (0.22 cal / g.oC) X (temperature change)
Qc = mccc(To - Tf)
cc = Specific heat of calorimeter.
CONSERVATION OF ENERGY:
Heat Gained = Heat Lost
Qi = Qw + Qc
Eq. (1)
mi Lf + micw(Tf - 0oC) = mwcw(To - Tf) + mccc(To - Tf)
mi Lf = mwcw(To - Tf) + mccc(To - Tf) - micw(Tf - 0oC)Eq. (2) Lf =
Eq. (3)
SUPPLIES & EQUIPMENT:
Double-walled calorimeter
Ice cubes
Steam Generator
Thermometer
Electronic balance
Beaker
Forceps/TongsPROCEDURE:
1.Determine the mass of the plastic collar. Slip the collar back on the inner cup.
2.Determine the mass of the inner cup, stirrer and plastic collar of the calorimeter.
3.Fill the inner cup of the calorimeter to about 2/3 full with warm water at about 40o.4.Re-determine the mass of the inner cup, stirrer, collar, and water. Calculate the mass of water in the cup.
5.Place the cup, stirrer, collar, and water into the outer calorimeter jacket and record the exact temperature just before the ice cube is placed in the water.
6.Wipe any excess water from an ice cube and place it carefully into the calorimeter cup.
7.Stir the contents occasionally while constantly observing the ice cube. As soon as the ice cube is completely melted, record the temperature. This temperature is Tf.
8.Re-determine the mass of the cup, stirrer, collar, and contents. The mass of the ice cube can now be calculated.
9.Compute the heat of fusion of ice and compare this to the accepted value by calculating the percent error.
10. Repeat the experiment. Comment on the reproducibility of the results.
DATA: THE HEAT OF FUSION OF ICE
Data and Calculations Table:
Trial12
Mass of inner cup,collar and
stirrer of calorimeter (g)
Mass of inner cup, collar,
stirrer and water (g)
Mass of water (g)
Initial temperature
of water (oC)
Final temperature
of contents (oC)
Mass of inner cup, collar
stirrer and contents (g)
Mass of ice cube (g)
HEAT
LOST:by water (cal)
by calorimeter (cal)
HEAT
GAINED:by ice cube (cal)
Heat of fusion (cal/gram)
Known value of
Heat of fusion (cal/gram)79.7 cal/gram79.7 cal/gram
% error
Experiment 14: STANDING WAVES ON STRINGSPURPOSE:
In this experiment we will study the relationship between tension in a stretched string and the wavelength and frequency of the standing waves produced in it.
INTRODUCTION:
Standing waves are produced by the interference between two traveling waves with the same wavelength, velocity, frequency and amplitude traveling in opposite directions. The equation for the velocity of propagation of transverse waves on a stretched string is:
.
(Eq. 1)
where T is the tension in the string and is the linear density (the mass per unit length of the string). The velocity of propagation v, the frequency of vibration f, and the wavelength are related this way:
v = f
(Eq. 2)
A stretched string has many modes of vibration. It may vibrate as a single segment, in which case its length is half of a wavelength. It may vibrate in two segments with a node (zero displacement) at the center as well as at each end; then the wavelength is equal to the length of the string. The wavelengths of the many modes of vibration are given by the relation:
,
so,
(Eq. 3)
where L is the length of the string, is the wavelength, and n is an integer called the harmonic number, indicating the number of segments.
SUPPLIES & EQUIPMENT:
Electric tuning fork
5- rheostat
Thick string
Stroboscope
Ruler
Thin string
Electronic balance
Meter stick
Slotted masses
Power supply for tuning forkLeads & connectors
Table clamp
Rod pulley
50-gram mass hangerScissors
5-gram mass hanger
6-inch "C" Clamp
PROCEDURE:1.Cut off a piece of the string about 2 meters long and determine its length, mass and linear density.
2.Clamp the apparatus to one end of your table and clamp the pulley to the other end, as shown in Figure 1. Knot the string to one end of the tuning fork and knot the other end to the mass hanger. Suspend the string over the pulley, and adjust the pulley until the string is horizontal. Write down the mass of the hanger.
3.Connect the fork to the rheostat, as your source of current as shown in Figure 1, with the tap on top of the rheostat set very close to the positive end. Use no more than a 6 V setting. Set the fork into vibration by adjusting the contact point screw above and to the left of the two terminals of the tuning fork apparatus. The rheostat may need to be adjusted to create noticeable but not violent vibrations.
4.Measure the frequency of the tuning fork using a stroboscope. Start with the highest strobe frequency possible and lower it until one stationary image of the tuning fork is obtained. When lowering the frequency of the strobe, also observe that a stationary image is obtained when the strobe frequency is , , , etc., times that of the tuning fork. Divide the number that appears on the stroboscope by 60 to get the frequency of the tuning fork in cycles per second (Hertz).
5.Vary the tension of the string by adding masses to the hanger until the string vibrates in five segments with maximum amplitude. Measure the length of one segment from a point vertically over the center of the pulley wheel to a node (zero amplitude). The wavelength will be twice the length of one segment. Record in the data table the added mass in kilograms. Then record the total mass (added mass plus the mass hanger) in the data table. Record the resulting tension T = mg in Newtons.
6.Repeat the procedure for 4, 3 and 2 segments by adding more mass to the pulley.
7.Compare the experimental velocity (v = f) with the theoretical velocity () by computing the percent difference.
Fig. 1: Standing Waves on Strings Apparatus
LABORATORY REPORT: STANDING WAVES ON STRINGS
Length of string ___________ m
Mass of string ___________ kg
= Linear Density of String __________ kg / m
Mass of hanger ___________ kg
f = Frequency of vibrating tuning fork __________ Hz
Number of
Segments
5
432
Length of one
segment (m)
Wavelength (m)
Velocity from
v = f (m/s)
Added mass (kg)
Total mass (kg)
Tension T (N)
Velocity from
v = (m/s)
% difference
Experiment 15: THE SPEED OF SOUND IN AIR
PURPOSE:
The speed of sound in air will be determined by means of an adjustable air column resonance tube, driven by a known frequency.
INTRODUCTION:
When a tuning fork is set into vibration over the open end of a tube which is closed at the other end, a series of compressions and rarefactions occur within the length of the tube. If the length of the tube is such that an odd number of quarter wavelengths just fit into the tube, a condition known as resonance occurs and the sound heard emanating from the tube is greatly enhanced.
When resonance occurs, the gas particles just outside the mouth of the open tube are oscillating up and down with their maximum amplitude. This location is called the displacement antinode, and is symbolized in Figure 1 by curved lines showing a maximum displacement from the center of the column (although the actual displacement is vertical, not horizontal). There must be a displacement node at the bottom of the air column, as the water prevents the gas particles from oscillating up and down.
Since resonance occurs at odd multiples of quarter wavelengths, one is able to determine the wavelength, , by noting the length of the tube at which resonance occurs. Thus:
Fig. 1.
From the above equations, the wavelength () can be calculated as:
= (L3 - L1)
(Eq. 1)
= 2(L2 - L1)
(Eq. 2)
Once the wavelength is determined, the speed can be calculated from the relationship:
Speed = Wavelength X Frequency
or,
v = f.
(Eq. 3)
The theoretical speed of sound in meters per second is given by the relation:
v = 331.5 + 0.607 T.
(Eq. 4)
where 331.5 m/s is the speed of sound at 0O C in meters per second and T is the temperature in Celsius degrees.
SUPPLIES & EQUIPMENT:
Resonance apparatusThermometer512 Hz tuning fork
Beaker
480 Hz tuning fork
Turkey basterRubber mallet
PROCEDURE:
1.Adjust the water level in the tube by raising the reservoir until the water level is about 10 cm from the top of the tube. See Figure 2.
EMBED Word.Picture.8
Fig. 2.
2.Strike the fork with the rubber mallet and hold it (horizontally) close to the top of the tube, with the prongs vibrating vertically. Lower the reservoir until the first resonance is heard. Record this position as L1.
3.Determine the lengths for the other two resonance positions as in step 2.
4.Take the average of three readings at each resonance position for calculating the speed of sound in air. Compare this to the theoretical value.
5.Repeat the procedure for another fork of a different frequency.
DATA: THE SPEED OF SOUND IN AIR
Data for tuning fork of frequency 512 Hz
Averages
L1 = _________ m, _________ m, _________ m
L1 = _________
L2 = _________ m, _________ m, _________ m
L2 = _________
L3 = _________ m, _________ m, _________ m
L3 = _________
= L3 - L1 = ____________ m
Average ____________
= 2 (L2 - L1) = __________ m
Experimental value for the speed of sound, v = f = ___________ m/s
Theoretical value for the speed of sound = ___________ m/s (Eq. 4)
% Error = ___________
Data for tuning fork of frequency 480 Hz
Averages
L1 = _________ m, _________ m, _________ m
L1 = _________
L2 = _________ m, _________ m, _________ m
L2 = _________
= 2 (L2 - L1) = __________ m
Experimental value for the speed of sound = _______________ m/s
Theoretical value for the speed of sound = ________________ m/s (Eq. 4)
% Error = __________________
Physics 6 Laboratory Assignment Part I.
View the video produced by the Jet Propulsion Laboratory, NASA Space Agency, Pasadena California. The segments that will be shown are:
a) Space Flight Operations Facility
b) Magellan: Exploration of Venus
c) Tracking and Data Acquisition
d) L.A. The Movie
e) Miranda The Movie
f) Earth The Movie
g) Mars The Movie
Write one or two sentences on each segment. Make sure that your report is neat and legible.
Part II. EXTRA CREDIT
Find an article in a periodical or book (not an encyclopedia ) that is related to satellites, space craft or space technology. You may want to consider using the cumulative index in the library. The following are some examples of the type of literature that you may consider, but are certainly not limited to:
National Geographic
Discover Magazine
Popular Science
Physics Today
Time Magazine
Newsweek
US News Report
Newspapers
Scientific American
Science Digest
Various textbooks
Books
Etc.
Write a summary of the article. The length of this summary should be about one page of neatly and legibly hand-written text or half page of type-written text.
Attach the article (a Xerox copy is okay) to your report.
This assignment can earn up to 10 points extra credit depending on the quality of the work.
0o
180o
Object
W
(Load)
A
B
FA
FB
FR
0o
180o
W
A
FA
FB
B
FA
FxA
FyA
F
B
yB
xB
xA
yA
A
F
F
F
F
F
vo
s
y
PAGE - 52 -
_1018083367.doc
Place wire here
Gauge #
Front:
Back:
Diameter
in inches
1 .00 inch = 2.54 cm
_1027771926.unknown
_1027830958.unknown
_1027831395.unknown
_1027852378.unknown
_1153215050.doc
Fulcrum at midpoint of stick
x
d1
F2 = m2g
m2
clockwise
is a negative torque
= F1d1 + ((F2d2) = 0
counter-clockwise
is a positive torque
d2
F1 = m1g
_1153220914.doc
T
m2g
m1
f
T
_1153135829.unknown
_1027852328.unknown
_1027831171.unknown
_1027831207.unknown
_1027831024.unknown
_1027772301.unknown
_1027830564.unknown
_1027830590.unknown
_1027830545.unknown
_1027829620.unknown
_1027829760.unknown
_1027772321.unknown
_1027772259.unknown
_1018101660.unknown
_1018245043.unknown
_1018245393.unknown
_1018246449.unknown
_1018247174.unknown
_1018250316.unknown
_1018247135.unknown
_1018245677.unknown
_1018245136.unknown
_1018245295.unknown
_1018245125.unknown
_1018179485.doc
f
Slope = EMBED Equation.3 = k
FN
f
FN
Descriptive Title
(Newtons)
(Newtons)
_1018179248.unknown
_1018179329.unknown
_1018244701.unknown
_1018245001.unknown
_1018244221.unknown
_1018102010.doc
m2
F (Applied Force) = m2g
f
FN
mg ( = W)
T
T
_1018178816.unknown
_1018101691.unknown
_1018089609.unknown
_1018093739.doc
f
y
mg sin
mg cos
mg sin
x
FN
_1018100565.doc
f
mg sin
y
mg sin
mg cos
x
FN
_1018091021.doc
m
1
m2
W
_1018086790.unknown
_1018089576.unknown
_1018088836.unknown
_1018089479.unknown
_1018084288.unknown
_1016342690.doc
mvo
Before Impact
_1016356553.unknown
_1016358963.unknown
_1016434116.doc
Steam inlet tube
Thermometer
Rod
Dial indicator
Steam
Generator
Steam outlet tube
To sink
_1018083017.doc
Each division is 0.01 mm
= 0. 00001 m
0 1 2 3 4
4 0
4 5
0
5
Each division is 1 mm
= 0. 001 m
Object to be measured
_1018083126.doc
Read the line at the contact point.
If there is no line there, read the
line just before the contact point.
(
)
An example of how to read the micrometer when making a measurement:
4
4 . 5 m m
0 . 4 75 m m
4 . 9 7 5 m m
+
0
4 5
0
4 5
4 7.5 div. X 0.01 mm/div. = 0.475 mm
Read to the nearest hundredth of a millimeter.
_1016437690.doc
4
3
0.01 mm
0
1 cm/div
10
1 mm/div
Secure movable ring firmly
1
0
9
8
7
6
2
5
0
1
2
80
60
40
20
30
50
90
70
per div.
_1016886441.unknown
_1016952154.doc
L1= (1/4)L2 = (3/4)L3 = (5/4)
L2
L3
L1
_1016440018.unknown
_1016437493.doc
0
1
4
0
1
2
3
0
10
20
_1016430507.doc
Beam Balance
Lab Jack
Beam Balance
T2
T1
B
mg
ma
mg
m
Paper Clip
_1016432763.unknown
_1016362409.unknown
_1016356828.unknown
_1016357563.doc
Fulcrum at midpoint of stick
x
d1
F3
m3
m2
d4
d2
F1
m4
F2
d3
F2
_1016356571.unknown
_1016345271.unknown
_1016354672.unknown
_1016355107.doc
Midpoint of stick
x
d1
F2 = m2g
m2
Fulcrum
d2
F1 = m1g
_1016354496.unknown
_1016343606.doc
(m+M)V
Immediately
After Impact
_1016343944.unknown
_1016343138.doc
h
KE = 0
h1
At Rest
PE = (m+M)gh
h2
_1013516947.unknown
_1015838100.unknown
_1015843096.doc
L
H
d
D
_1016342401.unknown
_1015841393.doc
m1
m2
Photogate #1
Photogate #2
_1015837094.unknown
_1015837997.doc
m
1
m2
a
W = m2g
_1014635151.doc
Gun
Initial
Position
Of Projectile
y
vo
x
x
voy = vocos
y
\
Final
Position
Of Projectile
vox = vocos
Fig. 2, Part B
_1014024826.doc
r
Revolving mass, m
Thistle Tube
Mark
(Actual Centripetal Force = Mg)
Hanging mass, M
_1012628153.unknown
_1012636951.unknown
_1012637557.unknown
_1012639283.unknown
_1012650263.doc
D
d
H
h
_1012637540.unknown
_1012631669.doc
Inclinometer
Front
Lock
_1012632194.unknown
_1012628476.unknown
_1011433436.doc
Sample Graph
DESCRIPTIVE TITLE
Average
Velocity
(m/s)
v
x
| | | | | | |
0 1 2 3 4 5 6 7
Time (s) X 1/60 sec
_1012628030.doc
0
Distance =
x
t = second
1
2
x
x
t
t
0
0
1
1
1
30
_1012628126.unknown
_1011446404.doc
String
Pulley
+ -
L
6 V Battery
Charger
_1011522530.unknown
_1011434244.doc
t = 0 1/60 1/30 2/30 3/30
Spark
x
Interval # 0 1 2 3
Tape
_1011424911.unknown
_1011427083.unknown
_1010482354.doc
Object to be measured
0 1 2 3 4 5 6
0 5 10
5 on the vernier scale
The zero line on the vernier scale lines up with the
main scale at 2.1 cm plus a fraction of a millimeter.
2.1 on the main scale
Read to the nearest tenth of a millimeter.
_1010310533.unknown