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Study of Thermoluminescence of Centers

Study of Thermoluminescence of Centers

Code:
Study of Thermoluminescence of Centers
Features
  • FET based marginal R.F. Oscillator
  • Digital diaplay of frequency
  • Excellent peaks display
  • Digital display of Helmoltz Coil Current
  • Compatible with general pupose CRO in X-Y mode 
Introduction
In recent years Magnetic Resonance has developed into a very useful and powerful tool in solid state research. In this method, use is made of the Zeeman interaction of the magnetic dipoles associated with the nucleus or electron, when placed in an external magnetic field. Accordingly, they are identified as NMR (Nuclear Magnetic Resonance) or ESR (Electron Spin Resonance). This form of spectroscopy finds many applications in the investigation of crystal structures, environmental effects, dynamic effects, defects in solids and in many diverse branches of Physics, Chemistry and Biology.
Elementary Magnetic Resonance

We know that the intrinsic angular momentum (spin) of the electron S couples with the orbital angular momentum of the electron  to give a resultant  and this coupling gives rise to the ‘fine structure’ of the spectra. Further, under the influence of an external magnetic field (H) each of the level will split into (2j+1) sublevels (Zeeman effect) and the splitting of a level will be

DE = (gµ0H)mj

where µ0 is the Bhor magneton, g is the Lande’ g-factor and mj is the magnetic quantum number. As can be seen, the splitting is not same for all levels; it depends on the  and  of the level (s=½ always for one electron). However, the sublevels will split equally by an amount

DE = gµ0H or = hn0

where n0 is the frequency of the system. Now if the electron is subjected to a perturbation by an oscillating magnetic field with its direction perpendicular to the static magnetic field and its frequency n1such that the quantum n1 is equal to E=hn0, we say that there is a resonance between n1 and n0. This willinduce transition between neighbouring sublevels (mj=±1) and in turn will absorb energy from oscillating field. Thus, at resonance, we get a peak due to the absorption of energy by the system

Experimental Technique
If we consider a free electron and substitute the proper value of constants in the equation: g=2.00, µ0=0.927X10-20 erg/gauss & h=6.625 X l0-27 erg sec, we get

= 2.8MHz/gauss

That is ESR can be observed at radio frequencies in a magnetic field of a few gauss or in the microwave region in a magnetic field of a few kilogauss. The latter alternate has many advantages: improved signal-to-noise ratio, high resolution etc. and is always preferred for accurate work, though it is very sophisticated and expensive. However, if the basic understanding of the subject is the main criteria as is usually the requirement of class room experiments, the observation of ESR in low magnetic field and in a radio frequency region makes it a lot simple, inexpensive and within the reach of every post-graduate laboratory.

Basic Circuit
The first stage of the ESR circuit consists of a critically adjusted (marginal) radio frequency oscillator with 4-digit frequency display. This type of oscillator is required here, so that the slightest increase in its load decreases the amplitude of oscillation to an appreciable extent. The sample is kept inside the tank coil of the oscillator, which in turn, is placed in the 50Hz magnetic field, generated by the Helmholtz coils. At resonance, i.e. when the frequency of oscillation equal to the Larmour’s frequency of the sample, the oscillator amplitude registeres a dip due to the absorption of power by the sample. This obviously, occurs periodically four times in each complete cycle of the supply voltage. The result is an amplitude modulated carrier which is then detected using a FET demodulator and amplified by an op-amp circuit.
Highly stabilised and almost ripple free power supply for the above circuit is obtained using an integrated circuit regulator.
Phase Shifter
This can compensate the undermined phase difference which may be introduced in the amplification stages of the spectrometer and oscilloscope.
50Hz Sweep Unit
A 50Hz current flows through Helmholtz coils which provides a low frequency magnetic field to the sample. As the resonance is observed at few gauss only, no static magnetic field is applied.
Oscilloscope (not supplied with the Spectrometer)
Any inexpensive oscilloscope normally available in the laboratory would be quite suitable.
Advantages and Limitations of our Spectrometer
  1. The instrument is basically designed for postgraduate laboratories keeping in view their requirements and limitations.
  2. The observation of ESR at low magnetic fields and consequently in radio-frequency region makes its instrumentation and working a lot simple and within the reach of a postgraduate students. Good resonance peaks can be obtained as a class room exercise.
  3. The spectrometer is complete in all respects including a sample DPPH (except a CRO).
Ordering Information:
Model LSESR105
Description

Details

Study of Thermoluminescence of Centers
Features
  • FET based marginal R.F. Oscillator
  • Digital diaplay of frequency
  • Excellent peaks display
  • Digital display of Helmoltz Coil Current
  • Compatible with general pupose CRO in X-Y mode 
Introduction
In recent years Magnetic Resonance has developed into a very useful and powerful tool in solid state research. In this method, use is made of the Zeeman interaction of the magnetic dipoles associated with the nucleus or electron, when placed in an external magnetic field. Accordingly, they are identified as NMR (Nuclear Magnetic Resonance) or ESR (Electron Spin Resonance). This form of spectroscopy finds many applications in the investigation of crystal structures, environmental effects, dynamic effects, defects in solids and in many diverse branches of Physics, Chemistry and Biology.
Elementary Magnetic Resonance

We know that the intrinsic angular momentum (spin) of the electron S couples with the orbital angular momentum of the electron  to give a resultant  and this coupling gives rise to the ‘fine structure’ of the spectra. Further, under the influence of an external magnetic field (H) each of the level will split into (2j+1) sublevels (Zeeman effect) and the splitting of a level will be

DE = (gµ0H)mj

where µ0 is the Bhor magneton, g is the Lande’ g-factor and mj is the magnetic quantum number. As can be seen, the splitting is not same for all levels; it depends on the  and  of the level (s=½ always for one electron). However, the sublevels will split equally by an amount

DE = gµ0H or = hn0

where n0 is the frequency of the system. Now if the electron is subjected to a perturbation by an oscillating magnetic field with its direction perpendicular to the static magnetic field and its frequency n1such that the quantum n1 is equal to E=hn0, we say that there is a resonance between n1 and n0. This willinduce transition between neighbouring sublevels (mj=±1) and in turn will absorb energy from oscillating field. Thus, at resonance, we get a peak due to the absorption of energy by the system

Experimental Technique
If we consider a free electron and substitute the proper value of constants in the equation: g=2.00, µ0=0.927X10-20 erg/gauss & h=6.625 X l0-27 erg sec, we get

= 2.8MHz/gauss

That is ESR can be observed at radio frequencies in a magnetic field of a few gauss or in the microwave region in a magnetic field of a few kilogauss. The latter alternate has many advantages: improved signal-to-noise ratio, high resolution etc. and is always preferred for accurate work, though it is very sophisticated and expensive. However, if the basic understanding of the subject is the main criteria as is usually the requirement of class room experiments, the observation of ESR in low magnetic field and in a radio frequency region makes it a lot simple, inexpensive and within the reach of every post-graduate laboratory.

Basic Circuit
The first stage of the ESR circuit consists of a critically adjusted (marginal) radio frequency oscillator with 4-digit frequency display. This type of oscillator is required here, so that the slightest increase in its load decreases the amplitude of oscillation to an appreciable extent. The sample is kept inside the tank coil of the oscillator, which in turn, is placed in the 50Hz magnetic field, generated by the Helmholtz coils. At resonance, i.e. when the frequency of oscillation equal to the Larmour’s frequency of the sample, the oscillator amplitude registeres a dip due to the absorption of power by the sample. This obviously, occurs periodically four times in each complete cycle of the supply voltage. The result is an amplitude modulated carrier which is then detected using a FET demodulator and amplified by an op-amp circuit.
Highly stabilised and almost ripple free power supply for the above circuit is obtained using an integrated circuit regulator.
Phase Shifter
This can compensate the undermined phase difference which may be introduced in the amplification stages of the spectrometer and oscilloscope.
50Hz Sweep Unit
A 50Hz current flows through Helmholtz coils which provides a low frequency magnetic field to the sample. As the resonance is observed at few gauss only, no static magnetic field is applied.
Oscilloscope (not supplied with the Spectrometer)
Any inexpensive oscilloscope normally available in the laboratory would be quite suitable.
Advantages and Limitations of our Spectrometer
  1. The instrument is basically designed for postgraduate laboratories keeping in view their requirements and limitations.
  2. The observation of ESR at low magnetic fields and consequently in radio-frequency region makes its instrumentation and working a lot simple and within the reach of a postgraduate students. Good resonance peaks can be obtained as a class room exercise.
  3. The spectrometer is complete in all respects including a sample DPPH (except a CRO).
Ordering Information:
Model LSESR105
Additional Information

Additional Information

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