Quasi-phase-matching is a technique in nonlinear optics which allows a positive net flow of energy from the pump frequency to the signal and idler frequencies by creating a periodic structure in the nonlinear medium. Momentum is conserved, as is necessary for phase-matching, through an additional momentum contribution corresponding to the wavevector of the periodic structure. Consequently, in principle any three-wave mixing process that satisfies energy conservation can be phase-matched. For example, all the optical frequencies involved can be collinear, can have the same polarization, and travel through the medium in arbitrary directions. This allows one to use the largest nonlinear coefficient of the material in the nonlinear interaction.[1][2]

Quasi-phase-matching ensures that there is positive energy flow from the pump frequency to signal and idler frequencies even though all the frequencies involved are not phase locked with each other. Energy will always flow from pump to signal as long as the phase between the two optical waves is less than 180 degrees. Beyond 180 degrees, energy flows back from the signal to the pump frequencies. The coherence length is the length of the medium in which the phase of pump and the sum of idler and signal frequencies are 180 degrees from each other. At each coherence length the crystal axes are flipped which allows the energy to continue to positively flow from the pump to the signal and idler frequencies.

The most commonly used technique for creating quasi-phase-matched crystals has been periodic poling.[3] A popular material choice for this is lithium niobate.[4][5][6] More recently, continuous phase control over the local nonlinearity was achieved using nonlinear metasurfaces with homogeneous linear optical properties but spatially varying effective nonlinear polarizability.[7][8][9] Optical fields are strongly confined within or surround the nanostructures, nonlinear interactions can therefore be realized with an ultra-small area down to 10 nm to 100 nm and can be scattered in all directions to produce more frequencies.[10][11] Thus, relaxed phase matching can be achieved at the nanoscale dimension.[12]

Mathematical description

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In nonlinear optics, the generation of new frequencies is the result of the nonlinear polarization response of the crystal due to a typically monochromatic high-intensity pump frequency. When the crystal axis is flipped, the polarization wave is shifted by 180°, thus ensuring that there is a positive energy flow to the signal and idler beam. In the case of sum-frequency generation, where waves at frequencies   and   are mixed to produce  , the polarization equation can be expressed by

 

where   is the nonlinear susceptibility coefficient,   represents the imaginary unit,   are the complex-valued amplitudes, and   is the wavenumber. In this frequency domain vector representation, the sign of the   coefficient is flipped when the nonlinear (anisotropic) crystal axis is flipped,

 

Development of signal amplitude

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[citation needed]

Let us compute the nonlinearly-generated signal amplitude in the case of second harmonic generation, where a strong pump at   produces a frequency-doubled signal at  , assuming a constant pump amplitude (undepleted pump approximation).

The signal wavelength can be expressed as a sum over the number of domains that exist in the crystal. In general the spatial rate of change of the signal amplitude is

 

where   is the generated frequency amplitude and   is the pump frequency amplitude and   is the phase mismatch between the two optical waves. The   refers to the nonlinear susceptibility of the crystal.

In the case of a periodically poled crystal the crystal axis is flipped by 180 degrees in every other domain, which changes the sign of  . For the   domain   can be expressed as

 

where   is the index of the poled domain. The total signal amplitude   can be expressed as a sum

 

where   is the spacing between poles in the crystal. The above equation integrates to

 

and reduces to

 

The summation yields

 

Multiplying both sides of the above equation by a factor of   leads to

 

Adding both equation leads to the relation

 

Solving for   gives

 

which leads to

 

The total SHG intensity can be expressed by

 

For the case of   the right part of the above equation is undefined so the limit needs to be taken when   by invoking L'Hôpital's rule.

 

Which leads to the signal intensity

 

In order to allow different domain widths, i.e.  , for  , the above equation becomes

 

With   the intensity becomes

 

This allows quasi-phase-matching to exist at different domain widths  . From this equation it is apparent, however, that as the quasi-phase match order   increases, the efficiency decreases by  . For example, for 3rd order quasi-phase matching only a third of the crystal is effectively used for the generation of signal frequency, as a consequence the amplitude of the signal wavelength only third of the amount of amplitude for same length crystal for 1st order quasi-phase match.

Calculation of domain width

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The domain width is calculated through the use of Sellmeier equation and using wavevector relations. In the case of DFG this relationship holds true  , where   are the pump, signal, and idler wavevectors, and  . By calculating   for the different frequencies, the domain width can be calculated from the relationship  .

Orthogonal quasi-phase-matching

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This method enables the generation of high-purity hyperentangled two-photon state. In orthogonal quasi-phase matching (OQPM),[13] a thin-layered crystal structure is combined with periodic poling along orthogonal directions. By combining periodic down-conversion of orthogonally polarized photons along with periodic poling that corrects the phase mismatch, the structure self corrects for longitudinal walkoff (delay) as it happens and before it accumulates. The superimposed spontaneous parametric downconversion (SPDC) radiation of the superlattice creates high-purity two-photon entangled state.

References

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  1. ^ Hu, X. P.; Xu, P.; Zhu, S. N. (2013). "Engineered quasi-phase-matching for laser techniques [Invited]" (PDF). Photonics Research. 1 (4): 171. doi:10.1364/PRJ.1.000171. ISSN 2327-9125.
  2. ^ Xu, P.; Zhu, S. N. (2012). "Review Article: Quasi-phase-matching engineering of entangled photons". AIP Advances. 2 (4): 041401. Bibcode:2012AIPA....2d1401X. doi:10.1063/1.4773457. ISSN 2158-3226.
  3. ^ Paschotta, Rüdiger. "Quasi-phase matching." Encyclopedia of Laser Physics and Technology. Retrieved April 30, 2006
  4. ^ Sun, Dehui; Zhang, Yunwu; Wang, Dongzhou; Song, Wei; Liu, Xiaoyan; Pang, Jinbo; Geng, Deqiang; Sang, Yuanhua; Liu, Hong (2020-12-10). "Microstructure and domain engineering of lithium niobate crystal films for integrated photonic applications". Light: Science & Applications. 9 (1): 197. Bibcode:2020LSA.....9..197S. doi:10.1038/s41377-020-00434-0. ISSN 2047-7538. PMC 7729400. PMID 33303741.
  5. ^ Hum, David S.; Fejer, Martin M. (2007-03-01). "Quasi-phasematching". Comptes Rendus Physique. Recent advances in crystal optics. 8 (2): 180–198. Bibcode:2007CRPhy...8..180H. doi:10.1016/j.crhy.2006.10.022. ISSN 1631-0705.
  6. ^ Miller, G.D.; Batchko, R.G.; Tulloch, W.M.; Weise, D.R.; Fejer, M.M.; Byer, R.L. (1997). "42% efficient single-pass second-harmonic generation of continuous wave Nd:YAG laser output in 5.3-cm-length periodically poled lithium niobate". CLEO '97., Summaries of Papers Presented at the Conference on Lasers and Electro-Optics. Vol. 11. pp. 58–59. doi:10.1109/cleo.1997.602238. ISBN 0-7803-4125-2. S2CID 124874832. Retrieved 2023-12-05.
  7. ^ Li, Guixin; Chen, Shumei; Pholchai, Nitipat; Reineke, Bernhard; Wong, Polis Wing Han; Pun, Edwin Yue Bun; Cheah, Kok Wai; Zentgraf, Thomas; Zhang, Shuang (2015). "Continuous control of the nonlinearity phase for harmonic generations". Nature Materials. 14 (6): 607–612. Bibcode:2015NatMa..14..607L. doi:10.1038/nmat4267. ISSN 1476-1122. PMID 25849530. S2CID 205411257.
  8. ^ J. Lee (2014). "Giant nonlinear response from plasmonic metasurfaces coupled to intersubband transitions". Nature. 511 (7507): 65–69. Bibcode:2014Natur.511...65L. doi:10.1038/nature13455. PMID 24990746. S2CID 4466098.
  9. ^ T. Huang (2020). "Planar nonlinear metasurface optics and their applications" (PDF). Reports on Progress in Physics. 83 (12): 126101–61. Bibcode:2020RPPh...83l6101H. doi:10.1088/1361-6633/abb56e. PMID 33290268. S2CID 225340324.
  10. ^ G. Rosolen (2018). "Metasurface-based multi-harmonic free-electron light source". Light: Science & Applications. 7 (1): 64–70. Bibcode:2018LSA.....7...64R. doi:10.1038/s41377-018-0065-2. PMC 6143620. PMID 30245811.
  11. ^ G. Li (2017). "Nonlinear metasurface for simultaneous control of spin and orbital angular momentum in second harmonic generation". Nano Letters. 17 (12): 7974–7979. Bibcode:2017NanoL..17.7974L. doi:10.1021/acs.nanolett.7b04451. PMID 29144753.
  12. ^ L. Carletti (2018). "Giant nonlinear response at the nanoscale driven by bound states in the continuum". Physical Review Letters. 121 (3): 033903–09. arXiv:1804.02947. Bibcode:2018PhRvL.121c3903C. doi:10.1103/PhysRevLett.121.033903. hdl:1885/160465. PMID 30085788. S2CID 51940608.
  13. ^ Hegazy, Salem F.; Obayya, Salah S. A.; Saleh, Bahaa E. A. (December 2017). "Orthogonal quasi-phase-matched superlattice for generation of hyperentangled photons". Scientific Reports. 7 (1): 4169. Bibcode:2017NatSR...7.4169H. doi:10.1038/s41598-017-03023-1. ISSN 2045-2322. PMC 5482903. PMID 28646199.
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