Spatial Characterization Of Two-Photon States - GAP-Optique

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1. General description of two-photon states In order to obtain more convenient units, the filter in momentum is defined in a different way than the filter in frequency. While Bs,i → 0 implies a single frequency collection, the condition for a single q vector collection is ws,i → ∞. Finally, after all the approximations and taking into account the filters, the mode function equation 1.12 becomes Φ(qs, Ωs, qi, Ωi) ∝ exp − w2 p 4 ∆20 − w2 p 4 ∆21 × exp − (γL)2 4 ∆2k − T 2 0 4 (Ωs + Ωi) 2 × exp − w2 s 2 q2 s − w2 i 2 q2 i − 1 2B2 Ω s 2 s − 1 2B2 Ω i 2 i . (1.34) The approximations listed in this chapter were introduced by several authors, and can be found for example in references [39, 40, 30]. In reference [41], we introduced a novel matrix notation based on the simplified mode function equation 1.34. The next section explains the details and the advantages of that notation. 1.4 The mode function in matrix form The argument of the exponential function in equation 1.34 is a second order polynomial of the mode function variables. Such a function can be written in matrix form, as is shown in appendix A. The mode function then becomes Φ(qs, Ωs, qi, Ωi) ∝ exp − 1 2 xt Ax (1.35) where all the parameters of the spdc process are contained in A, a positivedefinite real 6 × 6 matrix given by A = 1 ⎛ a ⎜ h ⎜ i 2 ⎜ j ⎝ k h b m n p i m c s t j n s d v k p t v f l r u w z ⎞ ⎟ , ⎟ ⎠ (1.36) l r u w z g x is the vector including all variables of the mode function, defined as ⎛ ⎞ ⎜ x = ⎜ ⎝ q x s q y s q x i q y i Ωs Ωi ⎟ , (1.37) ⎟ ⎠ and x t is the transpose of x. This matrix representation of the mode function, introduced in reference [41], is an important result of this thesis. The use of this notation reduces the calculation time for integrals over the mode function, 12
1.4. The mode function in matrix form and allows to solve some of those integrals analytically. For instance, the mode function normalization requires six integrals over the modulus square of the mode function. As appendix B shows, the matrix notation provides a way to calculate the normalization constant analytically, dx exp − 1 2 xt (2A)x and thus the normalized mode function reads = Φ(qs, Ωs, qi, Ωi) = [det(2A)]1/4 (2π) 3/2 (2π) 3 , (1.38) [det(2A)] 1/2 exp − 1 2 xt Ax . (1.39) In the same way, many other integrals over the mode function can be solved analytically using the matrix representation of the mode function. Conclusion The two-photon mode function can be written in a matrix form after a series of approximations. The matrix notation makes it possible to calculate several features of the down-conversion photons analytically, and reduces the numerical calculation time of others. The next chapter describes the different correlations in the two-photon state using the purity as a correlation indicator. The use of the approximate mode function in matrix notation makes it possible to find an analytical expression for the purity, and to study the effect of the different parameters on it. 13
Page 1: DOCTORAL THESIS IN PHOTONICS ICFO B
Page 5: Spatial Characterization Of Two-Pho
Page 9 and 10: Contents Contents vii Acknowledgeme
Page 11 and 12: Acknowledgements This thesis compil
Page 13 and 14: Abstract In the same way that elect
Page 15 and 16: Resumen De la misma manera que la e
Page 17 and 18: Introduction The role of photons in
Page 19: This thesis is based on the followi
Page 22 and 23: 1. General description of two-photo
Page 35 and 36: CHAPTER 2 Correlations and entangle
Page 37 and 38: 2.1. The purity as a correlation in
Page 39 and 40: 2.2. Correlations between space and
Page 41 and 42: 2.2. Correlations between space and
Page 43 and 44: 2.3. Correlations between signal an
Page 45 and 46: 2.3. Correlations between signal an
Page 47 and 48: Signal purity 1 0 (a) 0.1 3 2.3. Co
Page 49 and 50: CHAPTER 3 Spatial correlations and
Page 51 and 52: 3.2. OAM transfer in general SPDC c
Page 53 and 54: 3.2. OAM transfer in general SPDC c
Page 55: Phase front 3.3. OAM transfer in co
Page 58 and 59: 4. OAM transfer in noncollinear con
Page 72 and 73: 5. Spatial correlations in Raman tr
Page 81 and 82: CHAPTER 6 Summary This thesis chara
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APPENDIX A The matrix form of the m
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v =γ 2 L 2 Np sin ϕi − γ 2 L 2
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The matrix C is given by C = 1 ⎛
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B. Integrals of the matrix mode fun
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C. Methods for OAM measurements Inp
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Bibliography [13] M. Barbieri, C. C
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Bibliography [41] C. I. Osorio, A.
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Bibliography [68] S. Chen, Y.-A. Ch
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Spatial Characterization Of Two-Pho
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A Luz Stella y Luis Alfonso, mis pa
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Contents B Integrals of the matrix
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When he [Kepler] found that his lon
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Abstract The matrix notation, intro
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Abstract La notación matricial int
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Introduction the transfer of oam fr
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CHAPTER 1 General description of Tw
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y y x z z pump s i (a) signal idle
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1.3. Approximations and other consi
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x 1.3. Approximations and other con
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x Wave fronts 1.3. Approximations a
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1 0 -0.2 1.3. Approximations and ot
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1.4. The mode function in matrix fo
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2. Correlations and entanglement (a
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2. Correlations and entanglement ch
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2. Correlations and entanglement th
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2. Correlations and entanglement Fi
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2. Correlations and entanglement q
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2. Correlations and entanglement Si
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2. Correlations and entanglement ri
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3. Spatial correlations and OAM tra
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CHAPTER 4 OAM transfer in noncollin
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4.2. Effect of the pump beam waist
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1.0 0.0 4.2. Effect of the pump bea
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Coincidences 800 0 -4 4.2. Effect o
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Weight 1 0 4.3. Effect of the Poynt
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4.3. Effect of the Poynting vector
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Before the crystal 4.3. Effect of t
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CHAPTER 5 Spatial correlations in R
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x y z 5.1. The quantum state of Sto
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where 5.2. Orbital angular momentum
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weight 1 0.6 -180º -90º 0º 90º
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5.3. Spatial entanglement 5.20 is s
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6. Summary Experiments that explain
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A. The matrix form of the mode func
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A. The matrix form of the mode func
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APPENDIX B Integrals of the matrix
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APPENDIX C Methods for OAM measurem
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Bibliography [1] M. A. Nielsen and
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Bibliography [27] J. P. Torres, A.
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Bibliography [55] M. C. Booth, M. A
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Spatial Characterization Of Two-Photon States - GAP-Optique

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