Difference between revisions of "Electron Spin Resonance"
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[http://hank.uoregon.edu/experiments/ESR/esr.html ESR Web Page] | [http://hank.uoregon.edu/experiments/ESR/esr.html ESR Web Page] | ||
− | '''Electron Spin Resonance''' is a phenomenon, useful for the investigation of materials which contain unpaired spins | + | '''Electron Spin Resonance''' is a phenomenon, useful for the investigation of materials which contain unpaired spins, caused by various sources. The more interesting ESR signals arise from different circumstances caused by defects in a material, such as detecting impurities in semiconductors or isolators which can trap electrons. This measuring technique is a powerful evaluation of material properties and is used in lots of research fields in physics, chemistry and biology. |
+ | |||
+ | |||
==Physical background== | ==Physical background== | ||
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[[File:vector_diagramm_precession.png|thumb|180px| Precession of the two Quantum Vectors <math> \vec{S} </math> and <math> \vec{\mu_S} </math> around the magnetic field <math> \vec{B_Z} </math>.|Precession of the two Quantum Vectors <math> \vec{S} </math> and <math> \vec{\mu_S} </math> around the magnetic field <math> \vec{B_Z} </math>]] | [[File:vector_diagramm_precession.png|thumb|180px| Precession of the two Quantum Vectors <math> \vec{S} </math> and <math> \vec{\mu_S} </math> around the magnetic field <math> \vec{B_Z} </math>.|Precession of the two Quantum Vectors <math> \vec{S} </math> and <math> \vec{\mu_S} </math> around the magnetic field <math> \vec{B_Z} </math>]] | ||
− | As the term Electron Spin Resonance already implies, | + | As the term Electron Spin Resonance already implies, an essential part is the spin, an intrinsic angular momentum of the electron. In an atom, most of the electrons are paired regarding spin. That is, each electron has a partner with an opposite spin, creating a zero net spin. Depending on the electron configuration of an atom, or even molecule, it is possible that there are one or more single electrons, depending on material. |
Generally the magnetic moment of an electron is given by | Generally the magnetic moment of an electron is given by | ||
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<math> \vec{\mu}=-\mu_B\left(\vec{L}+g_e\,\vec{S}\right) </math> , | <math> \vec{\mu}=-\mu_B\left(\vec{L}+g_e\,\vec{S}\right) </math> , | ||
− | where <math> \mu_B </math> is the Bohr | + | where <math> \mu_B </math> is the Bohr magneton and <math> g_e </math> the magnetogyric ratio, for a free electron it is <math> g_e=2.0023\approx 2 </math>. This quantity is a measure for the quantitative relation of an angular momentum and its corresponding magnetic momentum. The latter formula includes the orbital angular momentum as well. With ESR it is only possible to detect and investigate the spin component of the total magnetic moment. Hence, in the following section, we will look at the pure magnetic moment originating from the spin <math> \vec{S} </math>. |
− | If the spin <math> \vec{S} </math> and its magnetic moment <math> \vec{\mu_S} </math> | + | If the spin <math> \vec{S} </math> and its magnetic moment <math> \vec{\mu_S} </math> are placed in an externally applied magnetic field, the magnetic moment of the spin starts to precess around the axis of the magnetic field due to the torque |
<math> \vec{M}=\vec{\mu_S}\times\vec{B_Z} </math> . | <math> \vec{M}=\vec{\mu_S}\times\vec{B_Z} </math> . | ||
− | |||
− | |||
[[File:vector_diagramm_spin_quantization.png|thumb|left|250px|alt=A| The two allowed projections of <math> \vec{S} </math> onto the z-axis: <math> \pm m_S </math>|The two allowed projections of <math> \vec{S} </math> onto the z axis: <math> \pm m_S </math>]] | [[File:vector_diagramm_spin_quantization.png|thumb|left|250px|alt=A| The two allowed projections of <math> \vec{S} </math> onto the z-axis: <math> \pm m_S </math>|The two allowed projections of <math> \vec{S} </math> onto the z axis: <math> \pm m_S </math>]] | ||
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<math> E=-\vec{\mu}\cdot\vec{B_Z} </math> . | <math> E=-\vec{\mu}\cdot\vec{B_Z} </math> . | ||
− | The magnetic moment <math> \vec{\mu} </math> is related to the spin <math> \vec{S} </math>, which is a | + | The magnetic moment <math> \vec{\mu} </math> is related to the spin <math> \vec{S} </math>, which is a quantum vector with special properties: |
* Absolute value: <math> |S|=\sqrt{s\left(s+1\right)} </math> | * Absolute value: <math> |S|=\sqrt{s\left(s+1\right)} </math> | ||
* Projection onto the z-axis: <math> m_S=\pm\frac{\hbar}{2} </math> | * Projection onto the z-axis: <math> m_S=\pm\frac{\hbar}{2} </math> | ||
− | Incidentally, those two quantities are the best way to distinguish the state of the electron, because only their operator | + | Incidentally, those two quantities are the best way to distinguish the state of the electron, because only their operator commutes and thus, are measurable at the same time. For instance, it is not possible to measure two of the three Cartesian components of the spin vector simultaneously. |
[[File:vector_diagramm_energy_split.png|thumb|right|450px|alt=A| The split of one energy state into two, once a magnetic field gets applied.|The split of one energy state into two, once a magnetic field gets applied.]] | [[File:vector_diagramm_energy_split.png|thumb|right|450px|alt=A| The split of one energy state into two, once a magnetic field gets applied.|The split of one energy state into two, once a magnetic field gets applied.]] | ||
− | The equation for the energy of the electron | + | The equation for the energy of the electron spin in an applied magnetic field contains a dot product between the magnetic moment and the B-field: |
<math> E=\mu_B\,g_e\,\vec{S}\cdot\vec{B_Z} </math> | <math> E=\mu_B\,g_e\,\vec{S}\cdot\vec{B_Z} </math> | ||
− | + | Since we have chosen our magnetic field to point into the <math> z </math> direction, the spin is characterized by the projection onto the <math> z </math> axis, depicted by the Quantum number <math> m_S </math> thus the dot product cancels to | |
<math> E=\mu_B\,g_e\,m_S\,B_Z </math> | <math> E=\mu_B\,g_e\,m_S\,B_Z </math> | ||
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<math> m_S=\pm\frac{\hbar}{2} </math> . | <math> m_S=\pm\frac{\hbar}{2} </math> . | ||
− | Bohr | + | Bohr magneton <math> \mu_B </math> and the magnetogyric ratio <math> g_e </math> are both natural constants at this point. If a external magnetic field <math> B_Z </math> is applied, and chosen to be positive with the <math> z </math> orientation the coordinate system, the electron's energy is reduced or raised, depending whether <math> m_S </math> is respectively negative or positive. The original single energy state, which we still get out of the equation for <math> B_Z=0 </math>, is split into two different energy states. Moreover, the energy difference |
<math> \Delta E=E_{+1/2}-E_{-1/2}=+\frac{1}{2}\,\mu_B\,g_e\,B_Z-(-\frac{1}{2}\,\mu_B\,g_e\,B_Z)=\mu_B\,g_e\,B_Z</math> | <math> \Delta E=E_{+1/2}-E_{-1/2}=+\frac{1}{2}\,\mu_B\,g_e\,B_Z-(-\frac{1}{2}\,\mu_B\,g_e\,B_Z)=\mu_B\,g_e\,B_Z</math> | ||
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is proportional to the strength of the applied magnetic field. Therefore that difference can be tuned very precisely by the experimental setup, which is very important for the latter detection of the ESR signal. | is proportional to the strength of the applied magnetic field. Therefore that difference can be tuned very precisely by the experimental setup, which is very important for the latter detection of the ESR signal. | ||
− | For typical laboratory B-fields the energy difference <math> \Delta E </math> ranges in the microwave photon band, if you convert the energy to wavelength or rather frequency. This is the point, where the name of the entire phenomenon originates. Namely, if one irradiates the unpaired spin, which normally sits in the lower energy state (due to general energy minimization of nature), with the correct frequency, the energy gets absorbed, | + | For typical laboratory B-fields the energy difference <math> \Delta E </math> ranges in the microwave photon band, if you convert the energy to wavelength or rather frequency. This is the point, where the name of the entire phenomenon originates. Namely, if one irradiates the unpaired spin, which normally sits in the lower energy state (due to general energy minimization of nature), with the correct frequency, the energy gets absorbed, indicating a transition to an upper energy level. In this case, the energy of the photons match exactly the energy difference between both states. Physicists call this situation '''Electron Spin Resonance'''. |
In formula language the following becomes true: | In formula language the following becomes true: | ||
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where <math> h </math> is Planck's constant and <math> \nu </math> the frequency of the incident light. | where <math> h </math> is Planck's constant and <math> \nu </math> the frequency of the incident light. | ||
− | Other than the magnetogyric ratio <math> g_e </math> | + | Other than the magnetogyric ratio <math> g_e </math>, all other quantities are either constants or measured values. Technically the magnetogyric ratio is a constant, however it depends on the material and its compounds, especially spin stucture. Taking the previous equation as well as transferring it to an expression for the magnetogyric ratio |
<math> g_e=\frac{h\,\nu}{\mu_B\,B_Z} </math> | <math> g_e=\frac{h\,\nu}{\mu_B\,B_Z} </math> | ||
− | yields material properties with regard to the spin configuration. For example, the comparison to the definite value of a free electron is | + | yields material properties with regard to the spin configuration. For example, the comparison to the definite value of a free electron is a good indicator for various substances' features. |
==Experimental setup== | ==Experimental setup== | ||
[[File:Simple ESR block diagram.png|thumb|600px| A simple ESR diagram of the core components.]] | [[File:Simple ESR block diagram.png|thumb|600px| A simple ESR diagram of the core components.]] | ||
+ | [[File:Actual_setup_arrowed_desciption_magnet_bridge.png|thumb|600px|Description of the magnet bridge.]] | ||
+ | [[File:Actual_setup_arrowed_desciption_sample_holder.png|thumb|600px|Depiction of the sample holder.]] | ||
+ | [[File:Actual_setup_arrowed_desciption_main_console.png|thumb|600px|Explanation of the main console.]] | ||
− | An ESR setup can vary by its looks and equipment used, but there are many common elements between them. A microwave source is incident to a sample within a resonance cavity, which is flanked by magnets perpendicular to the light source. Our setup housed these elements in | + | An ESR setup can vary by its looks and equipment used, but there are many common elements between them. A microwave source is incident to a sample within a resonance cavity, which is flanked by magnets perpendicular to the light source. Our setup housed these elements in a single machine, the magnet bridge, but allowed control using another machine, the main console. |
===Theoretical setup=== | ===Theoretical setup=== | ||
− | The magnet bridge is where the resonance happens, and as a result is the most important machine of the two. It houses the electromagnets, klystron, and allows control of the frequency of light and attenuation of that light. The microwave source is generated by a klystron, which passes the light through waveguides, to various parts of the system. A simple diagram is shown, with a more detailed view shown in the [[ | + | The magnet bridge is where the resonance happens, and as a result is the most important machine of the two. It houses the electromagnets, klystron, and allows control of the frequency of light and attenuation of that light. The microwave source is generated by a klystron, which passes the light through waveguides, to various parts of the system. A simple diagram is shown, with a more detailed view shown in the [[#Desired and future ESR setup|desired and future ESR setup]] section. The connection to the main console is omitted in the diagram, as it's intended to be eliminated from the system eventually. For now, the main console serves a handful of purposes. |
The main console is responsible to set the magnetic field and magnetic sweep range and time, along with demodulating the signal from the magnet bridge. The demodulator on this console allows setting a time constant for the demodulation, along with a post-amplifier for the signal. At one point in time, it allowed use of an XY-recorder, but that function has since been removed. | The main console is responsible to set the magnetic field and magnetic sweep range and time, along with demodulating the signal from the magnet bridge. The demodulator on this console allows setting a time constant for the demodulation, along with a post-amplifier for the signal. At one point in time, it allowed use of an XY-recorder, but that function has since been removed. | ||
Line 84: | Line 87: | ||
===Actual setup=== | ===Actual setup=== | ||
− | + | Knowing the theoretical assembly, it is much easier to understand the actual machine with its numerous devices, knobs and dials. The following pictures depict the ESR system that is available in the Advanced Project Laboratory. | |
+ | |||
+ | <span style="color:red">Real devices</span> are displayed by <span style="color:red">red arrows</span>, <span style="color:blue">operating knobs, dial and switches</span> are indicated by <span style="color:blue">blue arrows</span>, <span style="color:green">green arrows</span> symbolize the <span style="color:green">microwave path</span>. | ||
+ | |||
+ | ====Magnet bridge==== | ||
+ | |||
+ | This table will explain the function of each part. | ||
+ | |||
+ | {| class="wikitable" | ||
+ | !colspan="6"|Function of all experimental parts | ||
+ | |- | ||
+ | |Klystron | ||
+ | |produces microwave radiation, which becomes incident to the sample in the cavity | ||
+ | |- | ||
+ | |Attenuator | ||
+ | |attenuates the power of the radiation from the klystron; unit is decibel | ||
+ | |- | ||
+ | |Frequency dial | ||
+ | |controls frequency of the radiation coming from the klystron roughly, the real set value around the resonance case is controlled by the AFC | ||
+ | |- | ||
+ | |Detector current | ||
+ | |indicates the total power of the reflected microwaves | ||
+ | |- | ||
+ | |AFC voltage | ||
+ | |Automated Frequency Control, holds the klystron frequency stable , and adjust it during resonance | ||
+ | |- | ||
+ | |Modulation coils | ||
+ | |create the 100 kHz alternating B-field that is required due to the detector technique as a lock-In-amplifier | ||
+ | |- | ||
+ | |Iris | ||
+ | |controls amount of radiation going into the cavity, largely used to assist finding resonance of the cavity | ||
+ | |- | ||
+ | |} | ||
+ | ====Main console==== | ||
+ | For concrete illustration of the main control panel review this table. Anything in <span style="color:blue">blue</span> has been eliminated by using other devices, specifically a lock-in amplifier. | ||
− | + | {| class="wikitable" | |
− | * | + | !colspan="6"|Function of all experimental parts |
− | * | + | |- |
− | * | + | |Main B-field - DC B-field |
+ | |sets the initial magnetic field, before the sweep. That is, the starting strength of the B-field sweep | ||
+ | |- | ||
+ | |<span style="color:blue">Gain</span> | ||
+ | |amplifies the detection signal to expose by noise hidden real signal | ||
+ | |- | ||
+ | |Modulation amplitude - AC B-field | ||
+ | |regulates the amplitude of the 100 kHz current sent to the modulation coils | ||
+ | |- | ||
+ | |<span style="color:blue">Signal filter</span> | ||
+ | |functions as a low pass filter for resolution purposes | ||
+ | |- | ||
+ | |<span style="color:blue">Pen level</span> | ||
+ | |provides a voltage offset going to the recorder/data acquisition | ||
+ | |- | ||
+ | |Side scan panel | ||
+ | |tunes the time parameters regulating the sweep settings | ||
+ | |- | ||
+ | |} | ||
+ | |||
+ | ====Miscellaneous useful information about various parts==== | ||
+ | |||
+ | Helpful and beneficial information about all the different and numerous components: | ||
+ | |||
+ | {| class="wikitable" | ||
+ | !colspan="6"|Multitudinous components of the magnet bridge | ||
+ | |- | ||
+ | |Klystron | ||
+ | | | ||
+ | *works with high voltage, hence should be covered during operation | ||
+ | *needs to be cooled as well: water cooling system must be turned on while using klystron, even when magnets are powered off | ||
+ | |- | ||
+ | |Attenuator | ||
+ | | | ||
+ | *verified to function properly revealed by nice exponential dependence, like one expects for a decibel based scale (review appendix or click on the [[Media:Detector_dial_current-voltage-attenuator.pdf|Link]]) | ||
+ | *for easier incident power estimation there is a conversion table in the appendix or click on the [[Media:Attenuation_conversion.pdf|Link]] | ||
+ | |- | ||
+ | |Frequency dial | ||
+ | | | ||
+ | *hard to read, suggested to crouch down and read the meter head on | ||
+ | |- | ||
+ | |Detector current | ||
+ | | | ||
+ | *does not go to zero, but minimum is at about 40 | ||
+ | |- | ||
+ | |AFC voltage | ||
+ | | | ||
+ | *works only in vicinity of the resonance, otherwise crazy | ||
+ | |- | ||
+ | |Modulation coils | ||
+ | | | ||
+ | *the power needed to apply the 40 G maximum is approximately 2 A at 5 V (review appendix or click on the [[Media:Modulation_coils_voltage-current-supply-resistance.pdf|Link]]) | ||
+ | *can get really hot, since the two tiny magnets are not water cooled | ||
+ | |- | ||
+ | |Iris | ||
+ | | | ||
+ | *cannot be closed entirely, however, cannot get screwed in further at one point, also by using a screwdriver | ||
+ | *defined the state closed when the slit is parallel to the magnet gap, at the point one feels quite a amount of friction, using a screwdriver | ||
+ | |- | ||
+ | |Miscellaneous | ||
+ | | | ||
+ | *does not function without the main console switched on, even though it gets power from the wall outlet, since the main power cable going into the main control panel is split into two circuits, one connecting into the main console and the other one directly into the magnet bridge without any "door" | ||
+ | *water drain manages the water flow rate for at least a couple of hours, though the water was never turned on entirely; it is simply not necessary and helps prevent damage | ||
+ | *in general, the whole magnet bridge apparatus looks good with respect to reliability and functionality | ||
+ | *when swapping samples, it is suggested to change the magnet bridge to 'tune', as it may damage the detector crystal | ||
+ | |- | ||
+ | |} | ||
+ | |||
+ | |||
+ | {| class="wikitable" | ||
+ | !colspan="6"|Function of devices of main control panel | ||
+ | |- | ||
+ | |B-field | ||
+ | | | ||
+ | *must be turned slowly | ||
+ | *applies DC current through side prongs, aside from the top one, of cable on the bottom right corner of the back | ||
+ | *coils are in series: output of one spool is the input of the other one | ||
+ | *resistance: about 1.1 ohm each coil | ||
+ | *power supplied: about 18 V at 6000 G: about 18 Ampere total going through both coils (review appendix or click on the [[Media:Magnets_voltage-current-supply.pdf|Link]]) | ||
+ | |- | ||
+ | |Gain | ||
+ | | | ||
+ | *not sure whether it works alright, maybe facilitating drift as well | ||
+ | |- | ||
+ | |Modulation amplitude | ||
+ | | | ||
+ | *seems that great set values enhance signal drift | ||
+ | |- | ||
+ | |Signal filter | ||
+ | | | ||
+ | *there are more knob position (20) than numbers written around it (16), although, the numbers might be the time of a low pass filter | ||
+ | |- | ||
+ | |Pen level | ||
+ | | | ||
+ | *seems to drift slowly, depending on the Gain value up or down | ||
+ | |- | ||
+ | |Side scan panel | ||
+ | | | ||
+ | *sweep is driven mechanically through the old XY-recorder on the horizontal panel, there is a mechanism below that board | ||
+ | |- | ||
+ | |Miscellaneous | ||
+ | | | ||
+ | *main switch enables magnet bridge as well | ||
+ | *main power cable at the bottom right corner on the back: top: ground, aside from the top: + and - electrodes (going through fuses and the get split into two, connecting to the main console and the magnet brigde without any "door", two lower prongs are connected (low resistance) on either sides (main console and magnet bridge), purpose is simply a mystery | ||
+ | *turn down the magnetic field slowly (not more than 1000 G in a jump) to prevent any damage to the electronics | ||
+ | |- | ||
+ | |} | ||
==Operating instructions== | ==Operating instructions== | ||
− | Operating the ESR setup is relatively simple, as long as you obey the following steps. However, there are some essential things to do and a few things not to do | + | Operating the ESR setup is relatively simple, as long as you obey the following steps. However, there are some essential things to do and a few things not to do. Review the tables of the recent section as well: [[#Miscellaneous other useful information about various parts|Link]] |
+ | |||
+ | Comply with these guidelines: | ||
===Starting the machine=== | ===Starting the machine=== | ||
− | # Turn on the water cooling system to a decent flow rate. It is not necessary open the | + | # Turn on the water cooling system to a decent flow rate. It is not necessary to open the valve entirely. That will cause quite a high pressure in the supply hose, perhaps leading to subtle damage. Moreover, long runs have shown that the outflow does not get warmer at all, even after hours at a high magnetic field. |
# Check else is shut down: | # Check else is shut down: | ||
## Switch at the back of the magnet bridge, which hosts the klystron and the detector. | ## Switch at the back of the magnet bridge, which hosts the klystron and the detector. | ||
Line 105: | Line 250: | ||
## Magnetic field set value is zero. | ## Magnetic field set value is zero. | ||
# Enable power switch on the lower left corner of the main console. | # Enable power switch on the lower left corner of the main console. | ||
− | # Clean your sample and place it inside the tube, made for holding the sample between the two | + | # Clean your sample and place it inside the tube, made for holding the sample between the two magnets. |
− | # Change mode first to | + | # Change mode first to tune and then to operate. Wait for a while (up to one minute). Dial the frequency once in a while and see whether the two scales AFC output and detector current respond. When they react to changes, set the AFC to zero. The frequency of the klystron equates the resonance frequency of the cavity now. |
# Adjust the Iris height by screwing the stick in or rather out. The aim is to minimize the detector current which correspond to the total power of reflected microwaves (The past has shown that the height ranges at approximately 3-4 rotations from closed entirely). | # Adjust the Iris height by screwing the stick in or rather out. The aim is to minimize the detector current which correspond to the total power of reflected microwaves (The past has shown that the height ranges at approximately 3-4 rotations from closed entirely). | ||
# Align the height of the sample inside the tube. The sample is sitting in the center of cavity and hence has an effect on the resonance frequency of the cavity. For the measurement later on, it is very desirable to reduce it to a minimum. The sample pipe is put into the holder tube by a little ring, which prevents it from falling into the tube. Carefully change the position of the ring and always put the sample pipe back and see where the AFC stops. You want the AFC to be as left as possible. This step is really sensitive. Normally the AFC changes just by pulling the sample pipe out and inserting it back, without sliding the ring. Even rotating the sample interacts with the AFC, especially when the material is not distributed uniformly at the very bottom of the pipe. That is the case for materials other than liquids and powders, for instance little solid plates. | # Align the height of the sample inside the tube. The sample is sitting in the center of cavity and hence has an effect on the resonance frequency of the cavity. For the measurement later on, it is very desirable to reduce it to a minimum. The sample pipe is put into the holder tube by a little ring, which prevents it from falling into the tube. Carefully change the position of the ring and always put the sample pipe back and see where the AFC stops. You want the AFC to be as left as possible. This step is really sensitive. Normally the AFC changes just by pulling the sample pipe out and inserting it back, without sliding the ring. Even rotating the sample interacts with the AFC, especially when the material is not distributed uniformly at the very bottom of the pipe. That is the case for materials other than liquids and powders, for instance little solid plates. | ||
# Check the Iris again (optional) | # Check the Iris again (optional) | ||
− | # | + | # Choose a value for Gain: too low leads to inability to distinguish whether there is a signal or not; values too high correlate to excess noise; Good starting value: 100 - 1000 |
− | # | + | #Choose your Modulation Amplitude: A value too small will not excite any transitions; values too great are related to unnecessary broadening of the absorption peak, for better resolution this area should be as narrow as possible; Good starting value: 1 - 4 G (10 - 40 G for weak samples) |
− | # Set the Signal Filter: | + | # Set the Signal Filter: a small time constant will let a lot of useless signal pass; a large time constant will lead to a cut-off of the desired signal; good starting value: position 4 - 10 |
# Select your Scan Time: Longer enhances resolution later on and too short disable the opportunity to detect the transition (however, it depend also on the magnetic field scan range); But longer is not always good, especially when your setup shows a drift in any of the other components: Good starting value: 1 minute | # Select your Scan Time: Longer enhances resolution later on and too short disable the opportunity to detect the transition (however, it depend also on the magnetic field scan range); But longer is not always good, especially when your setup shows a drift in any of the other components: Good starting value: 1 minute | ||
# Set the magnetic field start value and the sweep interval. | # Set the magnetic field start value and the sweep interval. | ||
Line 127: | Line 272: | ||
# Power off the magnetic field. | # Power off the magnetic field. | ||
− | # | + | # On the magnet bridge, switch the mode from operate to tune then to standby |
# Take your sample out of the cavity and store or shelf it. | # Take your sample out of the cavity and store or shelf it. | ||
# Disable magnet bridge by switch at the back. | # Disable magnet bridge by switch at the back. | ||
Line 135: | Line 280: | ||
==ESR measurements== | ==ESR measurements== | ||
− | We have a bunch of samples, which are supposed to be responsive to ESR. Unfortunately none of them, except two, are labeled or named. | + | We have a bunch of samples, which are supposed to be responsive to ESR. Unfortunately none of them, except two, are labeled or named. Throughout the project we tested numerous samples of this set. Most of them did not show any signal over the entire magnetic field scan range, however, at that point our familiarity of the consoles was really limited. We tried to tune and optimize the quantities though, and dedicated quite a lot of time to consistency and the attempt to repeat ESR spectra with different materials. We investigated about 10 different samples, again with the new Lock-In setup as well, but we could not find any resonance with those materials. |
− | ===DPPH=== | + | ===DPPH (Sample #1)=== |
− | The strongest signal shows DPPH, the organic chemical compound 2,2-diphenyl-1-picrylhydrazyl. The absorbance of the incident microwave | + | The strongest signal shows DPPH, the organic chemical compound 2,2-diphenyl-1-picrylhydrazyl. The absorbance of the incident microwave radiation is really strong, such that the various parameters of the entire experiment lose their importance. As long as reasonable values for the numerous setting are chosen, one can find the strength of the magnetic field, where the dip in the reflected power occurs - even when the magnetic field gets scanned kind of fast. Therefore, it's the perfect sample for beginning ESR, because you receive a response for regulations far off the optimum. Moreover, always when something is changed at the experimental setup and it seems that it does not work appropriately any more, it is the sample to verify any issues, misalignment and damage. |
One of our nicest DPPH spectrum is shown below. The figure depicts the linear sweep of the magnetic field strength as well, related to the sweep voltage: | One of our nicest DPPH spectrum is shown below. The figure depicts the linear sweep of the magnetic field strength as well, related to the sweep voltage: | ||
Line 156: | Line 301: | ||
* Gain: 1000 | * Gain: 1000 | ||
− | The characteristic wiggle crosses the imaginary baseline (constant offset of all data points) at 3313.6 G. Given that result, the magnetogyric ratio would be 1. | + | The characteristic wiggle crosses the imaginary baseline (constant offset of all data points) at 3313.6 G. Given that result, the magnetogyric ratio would be 1.993 ± 0.008. The error evaluation assumes 0.2 % error of the value of the magnetic field the resonance takes place and of the resonance frequency. The result deviates by a lot from the set value of approximately 2.0036, it is even outside the reasonably chosen error. Although, the measuring error is really hugh, considering various sources like the slow frequency drift, correctness of the B-field set point, ... among others. |
Incidentally, the sweep voltage is very important to find the actual start and end point of the sweep at this stage, because it is directly coupled to the mechanical sweep mechanism. One can use the trigger, but there is still a delay between the impulse and the real start of cycle. | Incidentally, the sweep voltage is very important to find the actual start and end point of the sweep at this stage, because it is directly coupled to the mechanical sweep mechanism. One can use the trigger, but there is still a delay between the impulse and the real start of cycle. | ||
Line 162: | Line 307: | ||
===ZnS (Sample #8)=== | ===ZnS (Sample #8)=== | ||
− | + | This sample contains inorganic ZnS (zinc sulfide) coated on a silicon wafer. Since silicon forms a perfect lattice, in theory, any observed ESR response should originate from the ZnS coat. Though, it is understood there are no perfect crystals in nature. Hence, it is possible that signals arise as well from impurities in the silicon lattice. | |
− | In fact, the exact magnetic field strength of this sample, we found by first looking up | + | In fact, the exact magnetic field strength of this sample, we found by first looking up where it should appear approximately. It is much weaker and therefore the influence of the experiment parameters are much more sensitive. If there is an incorrect setting, you will not obtain a clear spectrum. And due to the wear of the old setup, which was built with all likelihood decades ago, it is really tough to repeat a beautiful signal right away. |
After a long fight with the experiment setup and plenty of praying, we finally could measure a very nice spectrum of ZnS, how it is supposed to be: | After a long fight with the experiment setup and plenty of praying, we finally could measure a very nice spectrum of ZnS, how it is supposed to be: | ||
Line 170: | Line 315: | ||
[[File:ZnS_spectrum.JPG|center|700px|alt=A]] | [[File:ZnS_spectrum.JPG|center|700px|alt=A]] | ||
− | The ZnS spectrum was recorded not with the laptop oscilloscope, but with a normal external oscilloscope, which | + | The ZnS spectrum was recorded not with the laptop oscilloscope, but with a normal external oscilloscope, which facilitates data export onto a flash drive. With the run on the laptop oscilloscope we noticed a high constant voltage intercept, which prevented us from zooming in deep enough by changing the volts per division. At one point the curve was simply off range. We utilized the original main console for this material, too. The scan values were |
* Frequency (exterior wavecounter): n.a. | * Frequency (exterior wavecounter): n.a. | ||
* Attenuation: 16 dB | * Attenuation: 16 dB | ||
Line 181: | Line 326: | ||
* Gain: 320 | * Gain: 320 | ||
− | + | Technically ZnS should also have a so called side bands on both sides next to the main ESR peak. It can be the case that we can see them in the diagram above at about 3440 G and 3740 G. It is simply not possible to verify that they are symmetrically distributed aside from the main wiggle and that those are real resonance wiggles. The graph is not clear enough. Maybe due to unreliability of the apparatus we used for approximately three consecutive scans. It is worth to spend some time on this later, though. | |
===ZnS (Sample #9)=== | ===ZnS (Sample #9)=== | ||
− | After numerous measurements of ZnS sample #8 we regognized that there is a little part of scotch take on it. And since we had another tube indicating that it contains the material ZnS, we tried to verify it with sample #9. At this point we already bypassed the old internal | + | After numerous measurements of ZnS sample #8 we regognized that there is a little part of scotch take on it. And since we had another tube indicating that it contains the material ZnS, we tried to verify it with sample #9. At this point we already bypassed the old internal lock-in by an exterior one. Therefore it was a test of that device at the same time. |
− | Again, this sample it tough to deal with, because the resonance is quite weak | + | Again, this sample it tough to deal with, because the resonance is quite weak along with the mannerisms of the old main console: |
[[File:ZnS_spectrum_2nd-sample.JPG|center|700px|alt=A]] | [[File:ZnS_spectrum_2nd-sample.JPG|center|700px|alt=A]] | ||
− | As | + | As mentioned above, this time we used the external lock-in, but displayed the signal on the external oscilloscope, which we utilized for storing data as well. |
The scan values were | The scan values were | ||
− | * Frequency (exterior wavecounter): 9 | + | * Frequency (exterior wavecounter): 9.23216 GHz |
* Attenuation: 16 dB | * Attenuation: 16 dB | ||
* Iris (rotation from closed completely): 3.75 | * Iris (rotation from closed completely): 3.75 | ||
Line 206: | Line 351: | ||
* Lock-In - AC Gain: 10 dB | * Lock-In - AC Gain: 10 dB | ||
− | + | Be aware of the somewhat different B-field axis: It is shifted by 25 G. Given that and a normal error both graphs are identical, regarding the main wiggle. Although, we did not reveal the two side dips, which seemed fairly consistent for the previous sample. | |
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | + | The calculation of the magnetogyric ratio yields the value 1.843 ± 0.008 . Again, the error of the value for the magnetic field strength and microwave frequency, when the resonance takes place, were both estimated as 0.2 %. In literature one can find various expectation values, based on the doping. None of the tested materials were pure ZnS. Therefore, it is impossible to evaluate whether the result is good or not. | |
==Desired and future ESR setup== | ==Desired and future ESR setup== | ||
Line 224: | Line 362: | ||
===Schematic composition of the new setup=== | ===Schematic composition of the new setup=== | ||
− | |||
The future plan with the whole project is to replace as many old modules as fast as possible, preferably, all of the controlling parts, likely step by step. In consequence of the reasons above, preferably, we want to control each step in the data processing as well as in the magnet circuitry by external and much newer machines. The precision and resolution of essentially any modern device is better than the internally installed into the main control panel of decades ago. There following schematic displays the essential basic parts of ESR: | The future plan with the whole project is to replace as many old modules as fast as possible, preferably, all of the controlling parts, likely step by step. In consequence of the reasons above, preferably, we want to control each step in the data processing as well as in the magnet circuitry by external and much newer machines. The precision and resolution of essentially any modern device is better than the internally installed into the main control panel of decades ago. There following schematic displays the essential basic parts of ESR: | ||
Line 233: | Line 370: | ||
Most of it should be performed pretty easily, however, the alignment such that all the numerous parts function together properly and do not irritate one another can be quite a challenge. At this point there is basically only one thing that prevents fast progress on the hardware section. The klystron or maybe even the entire magnet bridge does not respond to operating it without turning on the main console. Perhaps there is some essential communication among the two big experimental machines, which enables the klystron and the detector, respectively. Once that is resolved and there is an idea how to manipulate that or provide it externally, there should nothing be in the way to build the ESR setup like in the diagram. | Most of it should be performed pretty easily, however, the alignment such that all the numerous parts function together properly and do not irritate one another can be quite a challenge. At this point there is basically only one thing that prevents fast progress on the hardware section. The klystron or maybe even the entire magnet bridge does not respond to operating it without turning on the main console. Perhaps there is some essential communication among the two big experimental machines, which enables the klystron and the detector, respectively. Once that is resolved and there is an idea how to manipulate that or provide it externally, there should nothing be in the way to build the ESR setup like in the diagram. | ||
+ | |||
+ | ==Appendix== | ||
+ | |||
+ | In most of our troubleshooting series we did the analysis via data depiction and occasionally by fitting curves. The following links forward to the graphs that were used to investigate and interpret the various processes. | ||
+ | |||
+ | '''Attenuator: conversion table''' | ||
+ | |||
+ | [[Media:Attenuation_conversion.pdf|Link]] | ||
+ | |||
+ | '''Detector dial: current-voltage-attenuator''' | ||
+ | |||
+ | [[Media:Detector_dial_current-voltage-attenuator.pdf|Link]] | ||
+ | |||
+ | '''Microwave resonance: AFC-detector-frequency''' | ||
+ | |||
+ | [[Media:Mircrowave_resonance_AFC-detector-frequency_sweep_up.pdf|Link to frequency sweep up]] | ||
+ | |||
+ | [[Media:Mircrowave_resonance_AFC-detector-frequency_sweep_down.pdf|Link to frequency sweep down]] | ||
+ | |||
+ | '''DC magnets: voltage-current-supply''' | ||
+ | |||
+ | [[Media:Magnets_voltage-current-supply.pdf|Link]] | ||
+ | |||
+ | '''AC magnets: voltage-current-supply-resistance''' | ||
+ | |||
+ | [[Media:Modulation_coils_voltage-current-supply-resistance.pdf|Link]] |
Latest revision as of 21:45, 10 December 2014
Contents
Electron Spin Resonance (ESR) Project
Electron Spin Resonance is a phenomenon, useful for the investigation of materials which contain unpaired spins, caused by various sources. The more interesting ESR signals arise from different circumstances caused by defects in a material, such as detecting impurities in semiconductors or isolators which can trap electrons. This measuring technique is a powerful evaluation of material properties and is used in lots of research fields in physics, chemistry and biology.
Physical background
As the term Electron Spin Resonance already implies, an essential part is the spin, an intrinsic angular momentum of the electron. In an atom, most of the electrons are paired regarding spin. That is, each electron has a partner with an opposite spin, creating a zero net spin. Depending on the electron configuration of an atom, or even molecule, it is possible that there are one or more single electrons, depending on material.
Generally the magnetic moment of an electron is given by
,
where is the Bohr magneton and the magnetogyric ratio, for a free electron it is . This quantity is a measure for the quantitative relation of an angular momentum and its corresponding magnetic momentum. The latter formula includes the orbital angular momentum as well. With ESR it is only possible to detect and investigate the spin component of the total magnetic moment. Hence, in the following section, we will look at the pure magnetic moment originating from the spin .
If the spin and its magnetic moment are placed in an externally applied magnetic field, the magnetic moment of the spin starts to precess around the axis of the magnetic field due to the torque
.
In general, the energy of a magnetic moment is defined as
.
The magnetic moment is related to the spin , which is a quantum vector with special properties:
- Absolute value:
- Projection onto the z-axis:
Incidentally, those two quantities are the best way to distinguish the state of the electron, because only their operator commutes and thus, are measurable at the same time. For instance, it is not possible to measure two of the three Cartesian components of the spin vector simultaneously.
The equation for the energy of the electron spin in an applied magnetic field contains a dot product between the magnetic moment and the B-field:
Since we have chosen our magnetic field to point into the direction, the spin is characterized by the projection onto the axis, depicted by the Quantum number thus the dot product cancels to
with
.
Bohr magneton and the magnetogyric ratio are both natural constants at this point. If a external magnetic field is applied, and chosen to be positive with the orientation the coordinate system, the electron's energy is reduced or raised, depending whether is respectively negative or positive. The original single energy state, which we still get out of the equation for , is split into two different energy states. Moreover, the energy difference
is proportional to the strength of the applied magnetic field. Therefore that difference can be tuned very precisely by the experimental setup, which is very important for the latter detection of the ESR signal.
For typical laboratory B-fields the energy difference ranges in the microwave photon band, if you convert the energy to wavelength or rather frequency. This is the point, where the name of the entire phenomenon originates. Namely, if one irradiates the unpaired spin, which normally sits in the lower energy state (due to general energy minimization of nature), with the correct frequency, the energy gets absorbed, indicating a transition to an upper energy level. In this case, the energy of the photons match exactly the energy difference between both states. Physicists call this situation Electron Spin Resonance.
In formula language the following becomes true:
,
where is Planck's constant and the frequency of the incident light.
Other than the magnetogyric ratio , all other quantities are either constants or measured values. Technically the magnetogyric ratio is a constant, however it depends on the material and its compounds, especially spin stucture. Taking the previous equation as well as transferring it to an expression for the magnetogyric ratio
yields material properties with regard to the spin configuration. For example, the comparison to the definite value of a free electron is a good indicator for various substances' features.
Experimental setup
An ESR setup can vary by its looks and equipment used, but there are many common elements between them. A microwave source is incident to a sample within a resonance cavity, which is flanked by magnets perpendicular to the light source. Our setup housed these elements in a single machine, the magnet bridge, but allowed control using another machine, the main console.
Theoretical setup
The magnet bridge is where the resonance happens, and as a result is the most important machine of the two. It houses the electromagnets, klystron, and allows control of the frequency of light and attenuation of that light. The microwave source is generated by a klystron, which passes the light through waveguides, to various parts of the system. A simple diagram is shown, with a more detailed view shown in the desired and future ESR setup section. The connection to the main console is omitted in the diagram, as it's intended to be eliminated from the system eventually. For now, the main console serves a handful of purposes.
The main console is responsible to set the magnetic field and magnetic sweep range and time, along with demodulating the signal from the magnet bridge. The demodulator on this console allows setting a time constant for the demodulation, along with a post-amplifier for the signal. At one point in time, it allowed use of an XY-recorder, but that function has since been removed.
Actual setup
Knowing the theoretical assembly, it is much easier to understand the actual machine with its numerous devices, knobs and dials. The following pictures depict the ESR system that is available in the Advanced Project Laboratory.
Real devices are displayed by red arrows, operating knobs, dial and switches are indicated by blue arrows, green arrows symbolize the microwave path.
Magnet bridge
This table will explain the function of each part.
Function of all experimental parts | |||||
---|---|---|---|---|---|
Klystron | produces microwave radiation, which becomes incident to the sample in the cavity | ||||
Attenuator | attenuates the power of the radiation from the klystron; unit is decibel | ||||
Frequency dial | controls frequency of the radiation coming from the klystron roughly, the real set value around the resonance case is controlled by the AFC | ||||
Detector current | indicates the total power of the reflected microwaves | ||||
AFC voltage | Automated Frequency Control, holds the klystron frequency stable , and adjust it during resonance | ||||
Modulation coils | create the 100 kHz alternating B-field that is required due to the detector technique as a lock-In-amplifier | ||||
Iris | controls amount of radiation going into the cavity, largely used to assist finding resonance of the cavity |
Main console
For concrete illustration of the main control panel review this table. Anything in blue has been eliminated by using other devices, specifically a lock-in amplifier.
Function of all experimental parts | |||||
---|---|---|---|---|---|
Main B-field - DC B-field | sets the initial magnetic field, before the sweep. That is, the starting strength of the B-field sweep | ||||
Gain | amplifies the detection signal to expose by noise hidden real signal | ||||
Modulation amplitude - AC B-field | regulates the amplitude of the 100 kHz current sent to the modulation coils | ||||
Signal filter | functions as a low pass filter for resolution purposes | ||||
Pen level | provides a voltage offset going to the recorder/data acquisition | ||||
Side scan panel | tunes the time parameters regulating the sweep settings |
Miscellaneous useful information about various parts
Helpful and beneficial information about all the different and numerous components:
Multitudinous components of the magnet bridge | |||||
---|---|---|---|---|---|
Klystron |
| ||||
Attenuator | |||||
Frequency dial |
| ||||
Detector current |
| ||||
AFC voltage |
| ||||
Modulation coils |
| ||||
Iris |
| ||||
Miscellaneous |
|
Function of devices of main control panel | |||||
---|---|---|---|---|---|
B-field |
| ||||
Gain |
| ||||
Modulation amplitude |
| ||||
Signal filter |
| ||||
Pen level |
| ||||
Side scan panel |
| ||||
Miscellaneous |
|
Operating instructions
Operating the ESR setup is relatively simple, as long as you obey the following steps. However, there are some essential things to do and a few things not to do. Review the tables of the recent section as well: Link
Comply with these guidelines:
Starting the machine
- Turn on the water cooling system to a decent flow rate. It is not necessary to open the valve entirely. That will cause quite a high pressure in the supply hose, perhaps leading to subtle damage. Moreover, long runs have shown that the outflow does not get warmer at all, even after hours at a high magnetic field.
- Check else is shut down:
- Switch at the back of the magnet bridge, which hosts the klystron and the detector.
- Mode switch on the front panel is set to standby.
- Magnetic field set value is zero.
- Enable power switch on the lower left corner of the main console.
- Clean your sample and place it inside the tube, made for holding the sample between the two magnets.
- Change mode first to tune and then to operate. Wait for a while (up to one minute). Dial the frequency once in a while and see whether the two scales AFC output and detector current respond. When they react to changes, set the AFC to zero. The frequency of the klystron equates the resonance frequency of the cavity now.
- Adjust the Iris height by screwing the stick in or rather out. The aim is to minimize the detector current which correspond to the total power of reflected microwaves (The past has shown that the height ranges at approximately 3-4 rotations from closed entirely).
- Align the height of the sample inside the tube. The sample is sitting in the center of cavity and hence has an effect on the resonance frequency of the cavity. For the measurement later on, it is very desirable to reduce it to a minimum. The sample pipe is put into the holder tube by a little ring, which prevents it from falling into the tube. Carefully change the position of the ring and always put the sample pipe back and see where the AFC stops. You want the AFC to be as left as possible. This step is really sensitive. Normally the AFC changes just by pulling the sample pipe out and inserting it back, without sliding the ring. Even rotating the sample interacts with the AFC, especially when the material is not distributed uniformly at the very bottom of the pipe. That is the case for materials other than liquids and powders, for instance little solid plates.
- Check the Iris again (optional)
- Choose a value for Gain: too low leads to inability to distinguish whether there is a signal or not; values too high correlate to excess noise; Good starting value: 100 - 1000
- Choose your Modulation Amplitude: A value too small will not excite any transitions; values too great are related to unnecessary broadening of the absorption peak, for better resolution this area should be as narrow as possible; Good starting value: 1 - 4 G (10 - 40 G for weak samples)
- Set the Signal Filter: a small time constant will let a lot of useless signal pass; a large time constant will lead to a cut-off of the desired signal; good starting value: position 4 - 10
- Select your Scan Time: Longer enhances resolution later on and too short disable the opportunity to detect the transition (however, it depend also on the magnetic field scan range); But longer is not always good, especially when your setup shows a drift in any of the other components: Good starting value: 1 minute
- Set the magnetic field start value and the sweep interval.
- Press the start knob on the horizontal board of the main console, right to the old data plotting mechanism.
Changing sample
- You may shut down the magnetic field first.
- Switch the mode from operate to tune (on the magnet bridge).
- Replace the sample. Do not forget to clean it.
- Repeat steps 5 to 11 of the list above.
Shutting down
- Power off the magnetic field.
- On the magnet bridge, switch the mode from operate to tune then to standby
- Take your sample out of the cavity and store or shelf it.
- Disable magnet bridge by switch at the back.
- Press main power switch on the main control panel.
- Close water supply.
ESR measurements
We have a bunch of samples, which are supposed to be responsive to ESR. Unfortunately none of them, except two, are labeled or named. Throughout the project we tested numerous samples of this set. Most of them did not show any signal over the entire magnetic field scan range, however, at that point our familiarity of the consoles was really limited. We tried to tune and optimize the quantities though, and dedicated quite a lot of time to consistency and the attempt to repeat ESR spectra with different materials. We investigated about 10 different samples, again with the new Lock-In setup as well, but we could not find any resonance with those materials.
DPPH (Sample #1)
The strongest signal shows DPPH, the organic chemical compound 2,2-diphenyl-1-picrylhydrazyl. The absorbance of the incident microwave radiation is really strong, such that the various parameters of the entire experiment lose their importance. As long as reasonable values for the numerous setting are chosen, one can find the strength of the magnetic field, where the dip in the reflected power occurs - even when the magnetic field gets scanned kind of fast. Therefore, it's the perfect sample for beginning ESR, because you receive a response for regulations far off the optimum. Moreover, always when something is changed at the experimental setup and it seems that it does not work appropriately any more, it is the sample to verify any issues, misalignment and damage.
One of our nicest DPPH spectrum is shown below. The figure depicts the linear sweep of the magnetic field strength as well, related to the sweep voltage:
This spectrum is taken with the original main console as central controlling panel (future plans are to bypass this entire part) and the digital oscilloscope on the laptop, using the data acquisition board from Measurement Computing. The concrete set values were
- Frequency (exterior wavecounter): 9.2437 GHz
- Attenuation: 20 dB
- Iris (rotation from closed completely): 3.75
- B field start: 3290 G
- B field delta: 40 G
- Scan time: 1 min
- Signal filter: position 7
- Modulation amplitude: 4 G
- Gain: 1000
The characteristic wiggle crosses the imaginary baseline (constant offset of all data points) at 3313.6 G. Given that result, the magnetogyric ratio would be 1.993 ± 0.008. The error evaluation assumes 0.2 % error of the value of the magnetic field the resonance takes place and of the resonance frequency. The result deviates by a lot from the set value of approximately 2.0036, it is even outside the reasonably chosen error. Although, the measuring error is really hugh, considering various sources like the slow frequency drift, correctness of the B-field set point, ... among others.
Incidentally, the sweep voltage is very important to find the actual start and end point of the sweep at this stage, because it is directly coupled to the mechanical sweep mechanism. One can use the trigger, but there is still a delay between the impulse and the real start of cycle.
ZnS (Sample #8)
This sample contains inorganic ZnS (zinc sulfide) coated on a silicon wafer. Since silicon forms a perfect lattice, in theory, any observed ESR response should originate from the ZnS coat. Though, it is understood there are no perfect crystals in nature. Hence, it is possible that signals arise as well from impurities in the silicon lattice.
In fact, the exact magnetic field strength of this sample, we found by first looking up where it should appear approximately. It is much weaker and therefore the influence of the experiment parameters are much more sensitive. If there is an incorrect setting, you will not obtain a clear spectrum. And due to the wear of the old setup, which was built with all likelihood decades ago, it is really tough to repeat a beautiful signal right away.
After a long fight with the experiment setup and plenty of praying, we finally could measure a very nice spectrum of ZnS, how it is supposed to be:
The ZnS spectrum was recorded not with the laptop oscilloscope, but with a normal external oscilloscope, which facilitates data export onto a flash drive. With the run on the laptop oscilloscope we noticed a high constant voltage intercept, which prevented us from zooming in deep enough by changing the volts per division. At one point the curve was simply off range. We utilized the original main console for this material, too. The scan values were
- Frequency (exterior wavecounter): n.a.
- Attenuation: 16 dB
- Iris (rotation from closed completely): 3.5
- B field start: 3375 G
- B field delta: 400 G
- Scan time: 1 min
- Signal filter: position 10
- Modulation amplitude: 40 G
- Gain: 320
Technically ZnS should also have a so called side bands on both sides next to the main ESR peak. It can be the case that we can see them in the diagram above at about 3440 G and 3740 G. It is simply not possible to verify that they are symmetrically distributed aside from the main wiggle and that those are real resonance wiggles. The graph is not clear enough. Maybe due to unreliability of the apparatus we used for approximately three consecutive scans. It is worth to spend some time on this later, though.
ZnS (Sample #9)
After numerous measurements of ZnS sample #8 we regognized that there is a little part of scotch take on it. And since we had another tube indicating that it contains the material ZnS, we tried to verify it with sample #9. At this point we already bypassed the old internal lock-in by an exterior one. Therefore it was a test of that device at the same time.
Again, this sample it tough to deal with, because the resonance is quite weak along with the mannerisms of the old main console:
As mentioned above, this time we used the external lock-in, but displayed the signal on the external oscilloscope, which we utilized for storing data as well. The scan values were
- Frequency (exterior wavecounter): 9.23216 GHz
- Attenuation: 16 dB
- Iris (rotation from closed completely): 3.75
- B field start: 3400 G
- B field delta: 400 G
- Scan time: 1 min
- Signal filter: bypassed
- Gain: bypassed
- Modulation amplitude: 40 G
- Lock-In - Sensitivity: 10 mV
- Lock-In - Time constant: 1 s
- Lock-In - AC Gain: 10 dB
Be aware of the somewhat different B-field axis: It is shifted by 25 G. Given that and a normal error both graphs are identical, regarding the main wiggle. Although, we did not reveal the two side dips, which seemed fairly consistent for the previous sample.
The calculation of the magnetogyric ratio yields the value 1.843 ± 0.008 . Again, the error of the value for the magnetic field strength and microwave frequency, when the resonance takes place, were both estimated as 0.2 %. In literature one can find various expectation values, based on the doping. None of the tested materials were pure ZnS. Therefore, it is impossible to evaluate whether the result is good or not.
Desired and future ESR setup
Unreliability of the old setup
Basically, the only part, which work perfectly are magnets, both the big and powerful DC's and the small AC's, the klystron for the microwaves, the attenuator as well as the detector. At least so far there was not a simple moment were we experienced something to pass out or anything else, not as the main console, which freaks out once in a while. Because of that happens more and more often, the urgent task is to understand what essential control signals are sent to the magnet bridge. We encountered various strange moments from a spontaneous tremendous magnetic field offset, which mysteriously was gone after minutes, to a complete strike, where a scan could not be started any more. Those incidents certainly affected the magnet bridge, too. This part did not response any more or was weird in another way. Essentially every time such an occurrence happened, it was definitely not due to an operator, came just out of the blue. Hence, we could not determine the reason, all attempts to distinguish the origin were a dead end. The sole solution that worked as shutting down all the devices and wait. The time after the machine surprisingly decided to function again was completely random. I can be just the fact to be power off and turned on again, however, also half an hour.
Schematic composition of the new setup
The future plan with the whole project is to replace as many old modules as fast as possible, preferably, all of the controlling parts, likely step by step. In consequence of the reasons above, preferably, we want to control each step in the data processing as well as in the magnet circuitry by external and much newer machines. The precision and resolution of essentially any modern device is better than the internally installed into the main control panel of decades ago. There following schematic displays the essential basic parts of ESR:
The blue devices are the ones that are kept from the original machine, although some of them are now regulated by exterior equipment. The green devices are the mentioned external controllers. The red arrows correspond to the communication between all the various devices.
Most of it should be performed pretty easily, however, the alignment such that all the numerous parts function together properly and do not irritate one another can be quite a challenge. At this point there is basically only one thing that prevents fast progress on the hardware section. The klystron or maybe even the entire magnet bridge does not respond to operating it without turning on the main console. Perhaps there is some essential communication among the two big experimental machines, which enables the klystron and the detector, respectively. Once that is resolved and there is an idea how to manipulate that or provide it externally, there should nothing be in the way to build the ESR setup like in the diagram.
Appendix
In most of our troubleshooting series we did the analysis via data depiction and occasionally by fitting curves. The following links forward to the graphs that were used to investigate and interpret the various processes.
Attenuator: conversion table
Detector dial: current-voltage-attenuator
Microwave resonance: AFC-detector-frequency
DC magnets: voltage-current-supply
AC magnets: voltage-current-supply-resistance