Spatial Characterization Of Two-Photon States - GAP-Optique

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1. General description of two-photon states When the amplitude of the electric field increases, the higher orders term in equation 1.2 become relevant, and then a nonlinear response of the material to the field appears. Optical nonlinear phenomena resulting from this kind of interaction include the generation of harmonics, the Kerr effect, Raman scattering, self-phase modulation, and cross-phase modulation [34]. Spontaneous parametric down-conversion, and other second order nonlinear processes, result from the second order polarization, defined as the first nonlinear term in the polarization tensor P (2) = ɛ0χ (2) EE. (1.4) The quantization of the electromagnetic field leads to a quantization of the second order polarization, so that the nonlinear polarization operator ˆ P (2) becomes ˆP (2) = ɛ0χ (2) ( Ê(+) + Ê(−) )( Ê(+) + Ê(−) ), (1.5) where Ê(+) and Ê(−) are the positive and negative frequency parts of the field operator [36]. The positive frequency part of the electric field operator is a function of the annihilation operator â(k), and is defined at position rn xnˆxn + ynˆyn + znˆzn and time t as = Ê (+) 1/2 ωn n (rn, t) = ien 2ɛ0v dkn exp [ikn · rn − iωnt]â(kn), (1.6) where the magnitude of the wave vector k satisfies k 2 = ωn/c. The volume v contains the field, and en is the unitary polarization vector. The negative frequency part of the field is the Hermitian conjugate of the positive part, Ê (−) n (rn, t) = Ê(+)† n (rn, t). Thus, the negative frequency part is a function of the creation operator â † (k). Following references [37] and [38], in first order perturbation theory, the interaction of a volume V of a material with a nonlinear polarization ˆ P (2) and the field Êp(rp, t), produces a system described by the state |ΨT 〉 ∝ |1〉p|0〉s|0〉i − i τ 0 dt ˆ HI|1〉p|0〉s|0〉i, (1.7) where τ is the interaction time, |1〉p|0〉s|0〉i is the initial state of the field, and the interaction Hamiltonian reads ˆHI = − dV ˆ P (2) Êp(rp, t). (1.8) V The first term at the right side of equation 1.7 describes a one photon system, while the second term describes a two-photon system. In what follows we will consider only the second term as we are mainly interested in the generation of pairs of photons. The two-photon system state is given by |Ψ〉 = i τ 0 dt ˆ HI|1〉p|0〉s|0〉i, (1.9) or ˆρ = |Ψ〉〈Ψ| in the density matrix formalism. Seven of the eight terms that compose the interaction Hamiltonian vanish when they are applied over the state |1〉p|0〉s|0〉i. The remaining term is proportional to the annihilation 4
1.3. Approximations and other considerations operator in mode p, and the creation operators in modes s and i. Assuming constant χ (2) , the two-photon state reduces to (2) τ iɛ0χ |Ψ〉 = dt dV 0 V Ê(+) p (rp, ωp) Ê(−) s (rs, ωs) Ê(−) i (ri, ωi)|1〉p|0〉s|0〉i, (1.10) which can be written as |Ψ〉 ∝ dks dkiΦ(ks, ωs, ki, ωi)a † (ks)a † (ki)|0〉s|0〉i; (1.11) where Φ(ks, ωs, ki, ωi) is known as the mode function and, assuming that the pump has certain spatial distribution Ep(kp), is given by τ Φ(ks, ωs, ki, ωi) ∝ dt dV dkpEp(kp) 0 V × exp [ikp · rp − iks · rs − iki · ri − i(ωp − ωs − ωi)t] × â(kp)|1〉p. (1.12) The mode function contains all the information about the generated two-photon system in space and frequency, not only about their individual state but about their correlations. This function is therefore highly complex, and to calculate any feature of the two-photon state it is necessary to simplify it, as the next section shows. 1.3 Approximations and other considerations Analytical calculations of any features of the down converted photons require simplification of the mode function in equation 1.12. This section lists the most important approximations used in this thesis, as well as the restrictions that they impose. Separation of transversal and longitudinal components A field with a wave vector k almost parallel to its propagation direction spreads only a little in the transversal direction. It is then possible, to consider the longitudinal and transversal components of the wave vector separately, k = kzˆz + q. (1.13) As the wave vector’s magnitude k = ωn/c is bigger than the transversal component’s magnitude q = |q| = (k 2 x + k 2 y) 1/2 , the magnitude of the longitudinal component kz is always a real number, kz = k 2 1 − q 2 2 . (1.14) Assuming that the pump, the signal, and the idler are such fields, the mode function becomes τ Φ(qs, ωs, qi, ωi) ∝ 0 dt dV V dqpEp(qp) exp [ik z pzp − ik z szs − ik z i zi] × exp [iq p · r ⊥ p − iq s · r ⊥ s − iq i · r ⊥ i − i(ωp − ωs − ωi)t] × â(q p)|1〉p. (1.15) where r ⊥ n = xnˆxn + ynˆyn is the transversal position vector. 5
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DOCTORAL THESIS IN PHOTONICS ICFO B
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Spatial Characterization Of Two-Pho
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Contents Contents vii Acknowledgeme
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Acknowledgements This thesis compil
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Abstract In the same way that elect
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Resumen De la misma manera que la e
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Introduction The role of photons in
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This thesis is based on the followi
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1. General description of two-photo
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CHAPTER 2 Correlations and entangle
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2.1. The purity as a correlation in
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2.2. Correlations between space and
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2.2. Correlations between space and
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2.3. Correlations between signal an
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2.3. Correlations between signal an
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Signal purity 1 0 (a) 0.1 3 2.3. Co
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CHAPTER 3 Spatial correlations and
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3.2. OAM transfer in general SPDC c
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3.2. OAM transfer in general SPDC c
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Phase front 3.3. OAM transfer in co
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4. OAM transfer in noncollinear con
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5. Spatial correlations in Raman tr
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Page 81 and 82: CHAPTER 6 Summary This thesis chara
Page 83 and 84: APPENDIX A The matrix form of the m
Page 85 and 86: v =γ 2 L 2 Np sin ϕi − γ 2 L 2
Page 87: The matrix C is given by C = 1 ⎛
Page 90 and 91: B. Integrals of the matrix mode fun
Page 92 and 93: C. Methods for OAM measurements Inp
Page 94 and 95: Bibliography [13] M. Barbieri, C. C
Page 96 and 97: Bibliography [41] C. I. Osorio, A.
Page 98: Bibliography [68] S. Chen, Y.-A. Ch
Page 103: Spatial Characterization Of Two-Pho
Page 107: A Luz Stella y Luis Alfonso, mis pa
Page 110 and 111: Contents B Integrals of the matrix
Page 112 and 113: When he [Kepler] found that his lon
Page 114 and 115: Abstract The matrix notation, intro
Page 116 and 117: Abstract La notación matricial int
Page 118 and 119: Introduction the transfer of oam fr
Page 121 and 122: CHAPTER 1 General description of Tw
Page 123: y y x z z pump s i (a) signal idle
Page 127 and 128: x 1.3. Approximations and other con
Page 129 and 130: x Wave fronts 1.3. Approximations a
Page 131 and 132: 1 0 -0.2 1.3. Approximations and ot
Page 133: 1.4. The mode function in matrix fo
Page 136 and 137: 2. Correlations and entanglement (a
Page 138 and 139: 2. Correlations and entanglement ch
Page 140 and 141: 2. Correlations and entanglement th
Page 142 and 143: 2. Correlations and entanglement Fi
Page 144 and 145: 2. Correlations and entanglement q
Page 146 and 147: 2. Correlations and entanglement Si
Page 148 and 149: 2. Correlations and entanglement ri
Page 150 and 151: 3. Spatial correlations and OAM tra
Page 157 and 158: CHAPTER 4 OAM transfer in noncollin
Page 159 and 160: 4.2. Effect of the pump beam waist
Page 161 and 162: 1.0 0.0 4.2. Effect of the pump bea
Page 163 and 164: Coincidences 800 0 -4 4.2. Effect o
Page 165 and 166: Weight 1 0 4.3. Effect of the Poynt
Page 167 and 168: 4.3. Effect of the Poynting vector
Page 169 and 170: Before the crystal 4.3. Effect of t
Page 171 and 172: CHAPTER 5 Spatial correlations in R
Page 173 and 174: 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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