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Physics 241 Lab: Solenoids http://bohr.physics.arizona.edu/~leone/ua_spring_2009/phys241lab.html Name:____________________________ “When I Heard the Learn’d Astronomer” When I heard the learn’d astronomer, When the proofs, the figures, were ranged in columns before me, When I was shown the charts and diagrams, to add, divide, and measure them, When I sitting heard the astronomer where he lectured with much applause in the lecture-room, How soon unaccountable I became tired and sick, Till rising and gliding out I wander’d off by myself, In the mystical moist night-air, and from time to time, Look’d up in perfect silence at the stars. -Walt Whitman Important: In this course, every student has an equal opportunity to learn and succeed. How smart you are at physics depends on how hard you work. Work problems daily. Form study groups and meet as often as possible.. Join professional organizations. Physicists help people: science => technology => jobs. Section 1: 1.1. A current carrying wire creates a magnetic field around the wire. This magnetic field may be I ds rˆ found using the Biot-Savart Law dB o . However, this law can be difficult to use. If there 4 r2 is a high degree of symmetry, you may choose to find the magnetic field produced by the current carrying wire using Ampere’s Law B ds oItotal enclosed by. Ampere’s Law simplifies finding a whole Amperian loop Amperian loop magnetic field in the same manner that Gauss’s Law simplifies finding an electric field. Examine the ideal solenoid (also called “inductor”) where a very long coil of wire carries a current I is found to have a nearly uniform magnetic field inside the coils and a nearly zero magnetic sectional picture is provided: field outside the coils. A cross In the laboratory, an experimenter may easily control the current through a solenoid, and so it is desirable to determine the strength of the magnetic field inside the solenoid as a function of the current. Because of the high degree of symmetry in the ideal solenoid, Ampere’s Law may be used to find the magnetic field inside the solenoid. Go over the following derivation with your lab partner since you will need to understand it for your lab report. When the current in a wire changes, the strength of the magnetic field created by the current also changes. Therefore, if you know the time dependent behavior of the current, you can find the time dependent behavior of the magnetic field inside the solenoid. If the solenoid is carrying a sinusoidally oscillating current, then it will produce a sinusoidally varying magnetic field inside the coils. 1.2. A solenoid with 38,000 loops per meter is placed in series with a 10 resistor and driven by a sinusoidally varying source voltage. Using an oscilloscope, the voltage across the resistor is found to be Vres (t) 4.2sin 325t . Write a time dependent equation with numerical values to describe the time dependent strength of the magnetic field inside the solenoid. Then provide two specific times when the current and magnetic field have both simultaneously reached their respective amplitudes. Note that o=4x10-7 [Tm/A]. Your answers: Section 2: 2.1. Two very important concepts in the study of electricity and magnetism are Ampere’s Law and Faraday’s Law. Ampere’s Law states that a current in a wire creates a magnetic field. Faraday’s Law states that if the magnetic field changes (oscillates) the changing magnetic field will create a voltage in the wire. This voltage that is created by the changing magnetic field is call the “back EMF” or the “self-induced EMF”. Thus the logical flow of ideas is the changing current inside the solenoid wire causes a changing magnetic field between the solenoid coils that then causes a changing back EMF inside the solenoid wire. This is shown graphically for a sinusoidally oscillating circuit with a resistor and inductor in series: 2.2. Experimentally observe the 90o phase shift that shows that the oscillating voltage across an inductor leads the oscillating voltage across a resistor by /2. Use a sinusoidal source voltage to drive an inductor in series with a resistor. Use your oscilloscope to measure the voltage across the resistor and inductor simultaneously so that you can view the 90o phase shift. Make a quick sketch of your observations below. Record your choices for resistance values, driving frequencies, etc. that enabled you to see the inductor lead the resistor. Warning: at very low frequencies, the self-induced back EMF goes to zero because dB/dt is nearly zero so you would think that you would measure zero volts across the inductor. However, these inductors have ~1 km of wire and therefore some small resistance so at low frequencies you may register the voltage drop of the solenoid acting as a pure resistor. In this case, there is no phase shift. Check for yourself that the solenoid acts as a pure resistor at very low frequencies ~10 Hz. Your parameter choices and quick sketch: 2.3. If a magnetic field is changing through the area of a loop of wire, then Faraday’s law says that this changing magnetic field will induce a negative voltage (called the back EMF) in the circuit: d Faraday’s law: L (t) B , dt where the magnetic flux B is simply the magnetic field integrated over the cross sectional area of the wire loop: Magnetic flux: B Aarea B. Since a solenoid has N loops each with a cross sectional area that is constant in time, this means that: dB Faraday’s law for fixed area and N loops: L (t) NA . dt Due to the way we think about electronics, we need to remove the negative sign from this equation. This is similar to our use of V=IR for resistors in a circuit when technically the resistor causes a voltage drop (therefore a negative voltage change). Another way to think about this is that we adding all the voltages in a circuit together should yield can say that due to conservation of energy, zero: Vsource Vresistor 0. But we can always rearrange to have Vsource Vresistor. Thus you should write dB when measuring inductance in a circuit. L (t) NA dt 2.4. Find the time dependent back EMF created bythe RL circuit given in section 1.2. if the cross sectional area of the inductor is 0.006 m2 and the inductor is 9 cm long. Your answer: Restating the ideas of the previous section, if you take a single solenoid and apply an alternating source voltage, then it will have an alternating current. The alternating current of this single solenoid will produce an alternating magnetic field within the area of its own coils. Now, there is a changing magnetic field within the area of the coils. The changing magnetic field induces a voltage in this solenoid (the back EMF). This process is called self-inductance. The parameter L (SI units of Henry) is used to describe the solenoid’s ability to self-induce a back EMF L. This parameter is defined as: (t) Lsolenoid L . dI L dt dB Substituting the previous results L NA and Binside onIL gives: dt solenoid dB NA dB dt Lsolenoid NA A o N n . dI L dI L dt 2.3. Find the self-inductance parameter L for the inductor described in sections 1.2. and 2.3. Your answer: 2.4. If you allow a magnet to swing at the end of a pendulum just barely above some nonmagnetic sheet of copper, the pendulum-magnet will lose energy and come to a stop. Explain where the energy goes using the concepts of eddy currents &Lenz’s Law. Your explanation: Section 3: 3.1. Now you will experimentally examine the magnetic field produced by a solenoid with current flowing through it. Note that a real solenoid produces a magnetic field qualitatively similar to a bar magnet of the same dimensions. First check that your compass has not been “flipped”. The compass arrow should align itself with the local magnetic field produced by the Earth. Remember that the Earth’s north magnetic pole is at the geographic south pole. This causes the local magnetic field to point toward the north geographic pole. The compass aligns with this magnetic field and thus points toward the north geographic pole. If your compass has been flipped, fix it with a strong magnet or tell your TA so they can fix it. Examine the direction of the windings of your solenoid. You can tell which way the current circulates by how the wire enters the solenoid. Then you can use the right-handed screw rule to determine the direction of the magnetic field inside the solenoid (which side is north and which is south). Apply constant current using the constant voltage supply (a few volts should be good) to your solenoid. Use the right-handed screw rule to predict the positive direction (north pole) of the magnetic field produced within the solenoid and the magnetic field surrounding the solenoid in general. Test your prediction using the compass and sketch the magnetic field surrounding the solenoid below. Be sure to draw your solenoid in such a way as to show the reader how the current flows through the solenoid (see previous pictures in this manual for hints). Your sketch of the observed magnetic field within and surrounding a real solenoid with constant current: Section 4: 4.1. In this section you will experimentally observe the process of self-inductance. Place a solenoid in series with a 100 resistor and drive this simple RL circuit with a sinusoidal source voltage with 10 Hz (very slow) and 10 to 20 volts source amplitude. Set your oscilloscope to measure the voltage across the resistor. The resistor voltage tells you how much power the circuit is removing from the function generator. This also tells you about how much current is flowing through the resistor and therefore the solenoid. Qualitatively examine what happens to the current in the solenoid (via resistor voltage) as you increase the driving frequency from 100 Hz to higher frequencies. Your observations: The impedance L of an inductor is found to be L driveL where L is the self-inductance parameter of the solenoid and drive is the angular driving frequency. The total circuit impedance V without a capacitor is given by Z R2 L2 . Since Iresistor source, amplitude , explain how IR would Z amplitude change if drive was increased. (This is an alternate explanation of the previous question.) Your explanation: Section 5: 5.1. Restating previous ideas, Faraday’s Law states that a changing magnetic field will induce a d back EMF voltage: L B . Technically this equation shows that the back EMF produced is dt proportional to the rate of change of the magnetic flux, but the magnetic flux is just the magnetic field integrated over the surface area of the circuit. In simple situations this just becomes d B dA B dB . Since the presence of a back EMF is effectively like adding a battery to a A dt dt dt circuit, a current can be induced in a circuit without any other voltage source present! An example of this interesting situation is when a magnet approaches a solenoid in series with a resistor: Here the magnet’s north pole is approaching the solenoid from the left. The magnetic field dB strength is growing inside the inductor coils as the magnet approaches 0 . Lenz’s Law is a very dt simple rule that allows you to figure out the direction of the current flow caused by the induced back EMF. Lenz’s Law states that the back EMF will cause a current that generates it’s own reactionary magnetic field that opposes that change of the magnetic field inside the solenoid. In this case the states that there will be a reactionary magnetic field is growing to the right. Therefore, Lenz’s Law magnetic field growing to the left: Now you can simply use the right-hand screw rule to find the direction of the current traveling around the inductor coils that will produce the correct reactionary magnetic field and trace this current through the wires to find the direction of the current through the resistor. 5.2. Now solve some “simple” applications of Lenz’s Law and the right-hand screw rule for finding the current induced in a circuit with no source voltage present. Your answer: Your answer: Your answer: Your answer: Section 6: 6.1. Now you will experimentally observe how a changing magnetic field induces a voltage in an unpowered solenoid. Check your bar magnet with your compass to see that it is labeled correctly. Remember that the compass’s needle labeled “north” should point to south magnetic poles (like the north geographic pole of the earth). Hook up your solenoid to the oscilloscope so you can measure the electric potential difference between both ends. Don’t bother placing a resistor in series; there won’t be large enough currents to measure with the oscilloscope. Instead you will just examine the direction of the back EMF by checking the sign of the voltage across the solenoid caused by the back EMF. 6.2. Move the north pole slowly toward one side of your solenoid. Write what you see on your oscilloscope (positive or negative induced voltage). You should see some induced voltage or you are moving too slowly. Try using 500 ms/div and 50 mV/div to clearly see the response. Your observation: 6.3. Move the north pole quickly toward same side of your solenoid as in 6.2. Write what you see on your oscilloscope and compare the amplitude of the induced voltage with part 6.2. Your observation and comparison: 6.4. Use the equation for Faraday’s Law L d B to explain why the amplitude 6.3 was larger dt than 6.2. Your answer: 6.5. Now move the south pole quickly toward the same side of your solenoid as in 6.2. Write what you see on your oscilloscope and compare your result with that of 6.3. Your observation and comparison: 6.5. Use Lenz’s Law to explain the difference between your observations in 6.3 and 6.5. Your explanation: Section 7: 7.1. If you take a solenoid and drive it with an alternating current, it will produce an alternating magnetic field inside its coils. If you then take another solenoid that is unpowered and place it nearby so that the changing magnetic field of the first solenoid reaches inside the coils of the second solenoid, then a voltage will be induced in the second solenoid despite the fact that the wires of each solenoid in no way touch each other. This is the process of mutual inductance and is the basis of transformers in transmission lines. The definition of the mutual-inductance is: M transmitter receiver . dI to receiver transmitter dt The mutual inductance parameter M can be used to encapsulate all the geometric information of the combined solenoids. It is used in engineering so that you can calculate the transmitted voltage from an applied current without having to calculate the magnetic field and geometric factors. The equation for M istrue for all times so it is easiest to determine it experimentally using the time when the right hand side components have simultaneously reached their maximums: M transmitter receiver, amplitude dI transmitter dt amplitude Some digital oscilloscopes can measure derivatives in which case you could determine the dI 1 dV resistor, transmitter denominator using transmitter . If not, you would have to take the dt amplitude R dt amplitude dI Vresistor . derivative yourself to find that transmitter dt amplitude R transmitter to receiver amplitude Not a question. Section 8: 8.1. In this section you will experimentally study the process of mutual inductance. Use a function generator to drive a solenoid without any resistance. Use a sinusoidally oscillating source voltage of 10-20 volts amplitude. This solenoid is the transmitter. Hook up the other undriven solenoid directly to the oscilloscope. This solenoid is essentially the receiver. Place the solenoids together as close as possible so that you can measure the maximum induced voltage amplitude in the receiver. Placing soft iron inside the coils can increase the magnetic field inside the solenoids so that transmission is increased. 8.2. Now create a graph showing the maximum induced voltage amplitude in the receiver for several different driving frequencies. Collect about 10 data points (it is wisest to find fmax transmission first and collect data on either side). Then use your data to create a graph. A poor example of what you should see is provided. Find the frequency that maximizes transmission. Collect your data in the space below, make your graph on graph paper, and report your maximum transmission frequency below: 8.3. Use the mutual inductance equation and the self-inductance equation to explain which part of your graph is dominated by mutual inductance and which part of your graph is dominated by selfinductance. (Be sure to check your answer with your TA.) Your thorough explanation: Section 9: 9.1. Your answer to 2.1.b should state that L = R when you measure VR, amplitude = L, amplitude. If you find the frequency where this happens, you can use L driveL to find L. Use this single measurement method to find L for your solenoid. 9.2. There is a second multi-measurement method to find L. The voltage amplitudes of the sinusoidally driven RL circuit are very similar to those for the sinusoidally driven RC circuit you encountered a few weeks ago: R V (t) resistor Vsource sin drivet and V (t) inductor L Vsource sin drivet . Z amplitude Z amplitude 2 This gives the following relationships for the amplitudes: R Vresistor Vsource and Vinductor L Vsource . Z amplitude Z amplitude amplitude amplitude L Vsource amplitude Vinductor Vinductor Z L amplitude amplitude Dividing these two equations gives . Therefore, L R . R Vsource Vresistor Vresistor R amplitude amplitude amplitude Z In order to test the relationship L driveL and experimentally determine L for your solenoid, simply combine the last two equations: Vinductor driveL R amplitude . Vresistor amplitude Vinductor Therefore if you graph R amplitude Vresistor vs. drive, you should obtain a linear graph with a slope equal to L. amplitude Find L by collecting data for multiple driving frequencies, making a graph and finding the slope. Make your observations and graph now. Then write your work and result for L: Section 10: Authentic Assessment: 2 points. Use your solenoid to search for stray alternating magnetic fields in the lab. There are many strange high-frequency electromagnetic oscillations (radio waves) permeating the laboratory. Use an unpowered solenoid to detect the oscillating magnetic fields of these radio waves in order to measure the frequencies of these signals. This is the perfect opportunity to learn the use of your oscilloscopes FFT (fast Fourier transfer) math function. The FFT math operation changes the time-axis to a frequency-axis. You may then adjust the frequency scale using the “seconds/div knob”, zoom in using the “math > FFT zoom function”, horizontally scan using the “horizontal shift knob”, and Record your observations below for your TA to examine. Your observations: Show your TA once you are successful and have them initial here:______________ Section 11: (Open-ended question / creative lab design) Imagine you work for an engineering firm that constructs transformers for power lines. Your customers most likely don’t understand the intricate relation between Faraday’s Law, Ampere’s Law, etc. They just want to know what the output voltage is of the transformers your company sells if they put in a given current. With this in mind, determine the mutual inductance of your two-solenoid transformer with a soft iron core. At the following prompts, design an experiment to find the mutual inductance of your twosolenoid transformer. Then implement your experiment and record your observations. You may “cheat” by talking to other groups for ideas, but not “cheat” by already knowing the answer or looking it up. Your planned experiment, sketch of actual implementation and any theoretical calculations: Your observations: Your explanations & conclusion: I, the physics 241 laboratory TA, have examined this worksheet and found it to be thoroughly completed excepting any sections that I have marked herein. TA signature: ____________________ Report Guidelines: Write a separate section using the labels and instructions provided below. You may add diagrams and equations by hand to your final printout. However, images, text or equations plagiarized from the internet are not allowed! Title – A catchy title worth zero points so make it fun. Goals – Write a 3-4 sentence paragraph stating the experimental goals of the lab (the big picture). Do NOT state the learning goals (keep it scientific). [~1-point] Concepts & Equations – [8-points] Be sure to write a separate paragraph to explain each of the following concepts. Explain the following items in order: Explain Faraday’s Law and Ampere’s Law. Explain what causes the back EMF in a solenoid (self-inductance). Explain why L(t) (voltage across the inductor) is 90o phase-shifted before VR(t). Explain why IR decreases when the driving frequency drive is increased. Explain how to induce current in an unpowered circuit and the use of Lenz’s Law. Explain how to transmit electrical power in wires that don’t touch. Derive Binside onIL . solenoid dB . dt Derive Lsolenoid A o N n . Compare the frequency dependence of the inductive reactance to the capacitive reactance. Procedure – Do not write a procedure [0-points] Derive L NA Results – Summarize the quantitative or qualitative results of each section of the lab with a separate, short paragraph. Then write a lengthier paragraph(s) about your observed results in your open-ended experiment. Be sure to reference any graphs as results in the appropriate part this section (using the title of your graph). This must be written in sentence-paragraph form without bullet points. [1-points] Conclusion – Write at least three paragraphs where you analyze and interpret the results you observed or measured based upon your previous discussion of concepts and equations. It is all right to sound repetitive since it is important to get your scientific points across to your reader. Write a separate paragraph analyzing and interpreting your results from your open-ended experiment. Do NOT write personal statements or feeling about the learning process (keep it scientific). [5-points] Graphs – All graphs must be neatly hand-drawn during class, fill an entire sheet of graph paper, include a title, labeled axes, units on the axes, and the calculated line of best fit if applicable. [5-points] o The two graphs from sections 8 and 9. Worksheet – thoroughly completed in class and signed by your TA. [5-points & mandatory for report credit.] Introductory Electricity & Magnetism Laboratory Learning Outcomes: Introductory electricity & magnetism laboratory students should be prepared for leadership roles in an increasingly diverse, technological and highly competitive world. To this end, these students should… Understand the role of science in our society – How a solenoid affects an AC circuit. Have a firm grasp of the theories that form the basis of electricity and magnetism – Use of Faraday’s Law, Ampere’s Law and Lenz’s Law. Be able to apply the principles of physics to solve real world problems – Design an experiment to measure mutual inductance. Also to detect ambient electromagnetic radiation and determine its frequency. Be familiar with basic laboratory equipment, and should be able to design and carry out experiments to answer questions or to demonstrate principles. – Skills developed throughout lab especially the open-ended component. Use of modern digital oscilloscope. Be able to communicate their results through written reports – See the general report writing guidelines in the syllabus and the specific report writing guidelines at the end of the handout. Graduates of the introductory electricity & magnetism laboratory program should… Have a broad education that will allow them to succeed in diverse fields such as business, law, medicine, science writing, etc. – Writing skills, critical thinking skills, creative problem-solving skills, communicating ideas & information, teamwork skills, leadership skills, working with time constraints. Have mastered the introductory theoretical techniques and electricity and magnetism experimental techniques that are commonly expected for students at this level. – Across the world, all introductory electricity and magnetism students must be able to o Use a digital oscilloscope to measure rapidly changing voltages. o Build circuits and measure their properties. Be familiar with the principles and practice of engineering and should be able to apply their knowledge to solve state of the art problems, both individually and as part of a team. – Individuals must be able to build and test simple circuits. Teams must devise an experiment to measure mutual inductance. Teaching Tips: o Review the theory for finding a magnetic field: Ampere’s Law (compare structure to Gauss’s Law) & Biot-Savart Law. o Review right-hand wrap rule for finding direction of B inside a solenoid. o Review the theory for using a magnetic field: Faraday’s Law and Lenz’s Law. Demonstrate together: Quick demo of Faraday’s law with solenoid hooked directly to o-scope and bar magnet. Quick demo of mutual inductance. Instructional Equipment Needed: