Phase Sensitive Faraday Rotation in. and various Diamagnetic liquid Samples

Transcription

1 Phase Sensitive Faraday Rotation in TERBIUM GALLIUM GARNET crystal and various Diamagnetic liquid Samples Supervisor: Dr. Saadat Anwar Siddiqi Co-Supervisor: Dr. Muhammad Sabieh Anwar Presented by: Aysha Aftab Roll. No M.Phil ( ) 7/30/2010 1

2 Outlines Magneto optics Polarization of light Jones Calculus l Faraday Rotation Lock-in Amplifier ; PSD Why PSD in Faraday rotation? Schematic of the experiment. Results Determination of V using higher harmonics. References 7/30/2010 2

3 Magneto Optics Historical background 1813 Morrichini 1814 Faraday 1826 S. H. Christie 1834 Faraday 1844 Magnetic force and light were proved to have relation to each other. 7/30/2010 3

4 Magneto Optics (cont ) Optical radiation Interaction Magnetic medium or Optically inactive medium placed in Magnetic field Faraday rotation Kerr effect 7/30/2010 4

5 Polarization of light 1.Linear polarization Orientation of E field remains constant, magnitude and sign varies. Unpolarized light Plane of oscillation, containing E and K Electromagnetic wave with E field oscillating parallel to y axis. Linearly polarized 7/30/2010 5

6 Linear polarization (cont ) Horizontally polarized light propagating in z direction E x ( z, t ) i E cos( kz t ) ox E x ( z, t) Vertically polarized at phase difference ε, E y ( z, t) j E cos( kz t ) oy 7/30/2010 6

7 Linear polarization (cont ) Superposition of the two E( z, t) i E cos( kz t) j E cos( kz t ) ox oy 7/30/2010 7

8 2. Circular polarization Two orthogonal waves have equal amplitudes. Relative phase shift of 90 Direction of E is time varying, magnitude remains constant. a) Right Circularly polarized light relative phase difference of 90 o 2m rotating clockwise o E Eo[ i cos( kz t) j sin( kz t)] 7/30/2010 8

9 2. Circular polarization (cont..) Right circular Left circularly polarized, phase shift of 90 o 2m rotating anti clockwise E Eo [ i cos( kz t ) j sin( kz t )] 7/30/2010 9

10 2. Circular polarization (cont..) Left circular Linearly polarized is sum of R.C.P and LCP L.C.P E( z, t) 2Eo i cos( kz t) 7/30/

11 Jones calculus R. Clark Jones in 1941 For perfectly polarized light E( z, t) i E cos( kz t) j E cos( kz t ) E ( z, t ) ox Eox E e oy i For linearly polarized light cos E ( z, t ) sin 7/30/ oy y x

12 Jones calculus (cont ) E i Incident Jones vector is related to transmitted jones vector through matrix, J E t E t JE i For beam passing through a series of optical elements Et J n... J 3 J 2 J1 E i 7/30/

13 Faraday rotation Linearly ypolarized monochromatic light while transmitting through an optically inactive material, under the influence of an axial magnetic field, is rotated by an angle θ. Is non-reciprocal. 7/30/

14 Faraday rotation ti (cont ) For uniform B field VBd For non uniform B field d V 0 B( z). dz Where, d= length of the sample V= material parameter called Verdet constant, is a function of wave length of light. of the order of micro rad /G cm. 7/30/

15 Faraday rotation (cont ) Induced circular birefringence n r n l n The plane of polarization of plane-polarized light gets rotated 7/30/

16 Phase Sensitive Detection (PSD) V 10nV sin wave at 20 khz Amplifier input noise 4 nv Hz Q 1000 Bandwidth 1MHz V V o noise nV 4mV 10 V 7/30/

17 Phase Sensitive Detection (cont ) Band pass filter at 50 khz Q 1000 PSD V noise 500(4nV)(1000) 89V Band width Hz V noise 1.4V 7/30/

18 Lock in Amplifier A lock-in amplifier amplifies a small frequency band around a certain reference frequency. A lock-in can be used to Measure sinusoidal voltage amplitudes and phase Measure noise around a certain frequency. Consists of Signal channel Reference channel PSD : Heart of lock-in amplifier 7/30/

19 Lock in Amplifier (cont ) Lock in amplifier, block diagram 7/30/

20 Lock in Amplifier (cont ) Mixer V in Asin( t) V ref AB V o 2 Bsin( t ) [cos( ) cos(2t )] 7/30/

21 Lock in Amplifier (cont ) Low pass filter AB V cos( ) o 2 Noise close and closer to the reference frequency is removed. 7/30/

22 Why PSD in Faraday rotation? 7/30/

23 Why PSD in Faraday rotation? (cont ) Noise and signal amplitude as a function of frequency. Modulating the signal to a region of low noise. 7/30/

24 Schematic of the experiment Light source Source of magnetic field Detecting devices 7/30/

25 Schematic of the experiment (cont ) Light source Laser (A) (B) He-Ne gas laser (C) AlGaN diode laser 7/30/

26 Schematic of the experiment (cont ) Linear polarizer Malus s law Source of magnetic field Dc source large, expansive, bulky water cooled electromagnets. 7/30/

27 Schematic of the experiment (cont ) 7/30/

28 Schematic of the experiment (cont ) Ac source Low magnetic field is required. Signal of interest can be extracted successfully through PSD. Solenoid, Helmholtz coil. Helmholtz coil Two identical coils with separation equal to their common radius. B B In superposition B o 4 ( ) 5 (1 c x c6 x o N a i...) 7/30/

29 Schematic of the experiment (cont ) Magnetic lines of force of our Helmholtz coil drawn in Vizimag 7/30/

30 Schematic of the experiment (cont ) 7/30/2010 Helmholtz coil 30

31 Schematic of the experiment (cont ) Parameters of coil 18 gauge copper wire, d=1.2 mm N=324, l=2.7 cm, R=1.5Ω D1=6.5 cm, D2=10.2 cm, a=4.8 cm L=7 mh Connected a capacitor of 0.97µF to resonate the coil at 1.22 khz to maximize the current and hence B f 1 2 LC 7/30/

32 Schematic of the experiment (cont ) Gauss meter Resonance in Helmholtz coil B 6.7 Q i T 7/30/

33 Schematic of the experiment (cont ) Magnetic field varies linearly with the current applied. 7/30/

34 Schematic of the experiment (cont ) 7/30/

35 Setup for the experiment 7/30/

36 Working principle Jones vector of horizontally polarized light traveling in zdirection E o 1 1 A 0 o exp i ( kz t ) For rotated polarized light, after sample E o cos A sin o expi( kz t) 7/30/

37 Working principle (cont ) After analyzer cos( E o )cos( ) A cos( )sin( ) Intensity measured by photodiode I E *. E 2 A o 2 A o cos 2 o ( ) I (1 2 ) 2 I I sin( t) 0 i 2 ac i dc expi( kz t) 7/30/

38 Resistance measurement through Lock-in Amplifier R a V c V B R s 7/30/

39 Using optical chopper with Lock-in Amplifier 7/30/

40 Results TGG at 405 nm 7/30/

41 TGG at 405 nm 7/30/

42 TGG at 633 nm 7/30/

43 CS 2 at 405 nm 7/30/

44 CS 2 at 633 nm 7/30/

45 Methanol at 405 nm 7/30/

46 Methanol at 633 nm 7/30/

47 Water at 405 nm 7/30/

48 Water at 633 nm 7/30/

49 Isopropanol at 405 nm 7/30/

50 Isopropanol at 633 nm 7/30/

51 Determination of V using higher harmonics 7/30/

52 Summary sample Wave length Verdet constant (nm) (rad/g cm) TGG 633 (0.146±0.003) ) 10-3 TGG 405 (1.70±0.02) 10-3 CS (0.97±0.07) 10-5 CS (0.50±0.01) Methanol 633 (0.24±0.02) 10-5 Methanol 405 (1.20±0.05) /30/

53 Summary (cont ) sample Wave length Verdet constant (nm) (rad/g (ad/gc cm) Water 633 (0.30±0.02) 10-5 Water 405 (1.50±0.08) 10 08) 10-5 Isopropanol 633 (3.55±0.02) 10-6 Isopropanol 405 (2.2±0.06) /30/

54 References 1. Aloke Jain, Jayant Kumar, Fumin Zhou and Lian Li, A simple experiment for determining Verdet constant using alternating magnetic fields Am. J. Phys. 67, (1999). 2. Eugene Hetch and A. R. Ganesan, Optics", 4th edition, Pearson Education, Inc, India, Frank L. Pedrotti and Peter Bandettini, Faraday rotation in the undergraduate advanced laboratory", Am. J. Phys. 58, (1990). 4. Frank J. Loeffier, A Faraday rotation experiment for the Undergraduate physics laboratory", Am. J. Phys. 51, (1983). 7/30/

55 Reference 5. K. Turvey, Determination of Verdet constant from combined ac and dc measurents, "Am. J. Phys. 64, (1993) Lock-in amplifier, user Manual, Stanford Research System, SR 510, 7/30/