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Harald Schwefel

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Harald Schwefel
Harald Schwefel in November 2018
Alma materBrandenburg University of Technology, Yale University
Scientific career
InstitutionsYale University, University of Erlangen–Nuremberg, University of Otago, Dodd-Walls Centre
Doctoral advisorDouglas Stone

Harald Schwefel is a German-born physicist currently based in New Zealand. He is an associate professor in the Department of Physics at the University of Otago and a principal investigator in the Dodd-Walls Centre. His research focuses on the interaction of light and matter in dielectric materials, and his speciality is whispering gallery mode resonators (WGMRs), small disks of dielectric which confine and store laser light to facilitate nonlinear interactions. He uses these to generate optical frequency combs and to coherently convert between microwave and optical photons.

Biography

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Born in Berlin,[1][2] Schwefel spent his undergraduate years from 1994 till 1998 studying physics and maths at Brandenburg University of Technology (BTU) Cottbus in Germany.[3][4] During this time he took an active part in student politics as a member and then chairman of the student council StuRa.[5] He organised strikes and demonstrations in response to savings plans proposed by Science Minister Steffen Reiche in a draft of the Brandenburg Higher Education Act that granted unlimited rights to close and merge universities.[6][7] Schwefel was motivated to maintain the small size of universities in East Germany which offered educational advantages.[8] He encouraged students to be active, enjoy student life and study subjects they found fun. He also ran the Berlin marathon and climbed Mount Elbrus while at BTU.[5][6][9][7]

In 1998 Schwefel received a graduate student scholarship from Yale University and studied the topic of chaotic dielectric resonators at Yale University[5] with adviser Douglas Stone.[10][11][4] During this time he worked as a maths and science tutor at Davenport College.[5][4] He graduated with a PhD in 2004 and took a postdoctoral position in the same department, spending seven years in total at the Yale Physics Department.[1] In 2005 he visited ATR Wave Engineering Laboratories in Kyoto Japan as a postdoctoral researcher.[12]

In 2005 Schwefel joined the Max Planck Research Group at the University of Erlangen as a postdoctoral fellow [1][3] and then established a research programme as a group leader at the Max Planck Institute for the Science of Light in Erlangen.[13][14][15]

Schwefel moved to New Zealand in September 2015 where he has reestablished his research programme as a senior lecturer in the Department of Physics at the University of Otago[13][10] and a principal investigator in the Dodd-Walls Centre for Photonic and Quantum Technologies.

Research

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Schewefel and PhD student Bianca Sawyer

Schwefel leads the Resonant Optics group at the University of Otago. His research focuses on resonantly enhanced interaction of light and matter in dielectric materials.[16] This includes both theoretical and experimental work in the linear and nonlinear domains. He specialises in whispering gallery mode resonators (WGMRs), small disks of dielectric materials which are used to confine, store and therefore intensify light to facilitate nonlinear interactions.[17] These devices are based on the whispering gallery wave phenomenon, where laser light bounces around the inner surface of a dielectric disc, confined by total internal reflection.[18] Schwefel began research on WGMRs at the Max Planck Institute and has further developed fabrication techniques to achieve high quality factors,[19][20][14] which means that large amounts of laser light can be confined and stored within the resonator with very little leakage. The resulting high electric field strengths enable efficient nonlinear interactions.[21] Schwefel's group are exploring the use of WGMRs for generating optical frequency combs, coherently converting microwave and terahertz radiation into the optical domain as well as other fundamental investigations.[17]

Optical frequency combs and telecommunication

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Schwefel and his team have used WGMRs made of second order nonlinear crystals, such as lithium niobate, to generate optical frequency combs of record efficiency.[22] These devices show potential to significantly improve the efficiency of the internet by reducing the power required to encode data and the information-carrying capacity of optical fibres. The frequency combs are generated by sending low power microwave and optical signals into a WGMR; the crystal is electro-optically active, so its optical properties change under the influence of an electric field. The electric field of the microwaves influences the light waves and as a result a cascade of over a hundred new optical frequencies are generated from the original optical frequency.[21] The device produces 160 coherent laser frequencies at low power. They have potential use in submarine optical networks and data centres where a single optical frequency comb could replace over a hundred lasers currently used to encode and send data on optical fibres. Because all the laser lines generated are from the same source, they have the same noise characteristics and stable phase relation. This would allow the transport of more light down a single optical fibre, increasing its information-carrying capacity. Unlike the more common microresonator optical frequency combs, which are based on the third-order nonlinear Kerr effect, these optical frequency combs rely on a second-order nonlinear effect, which has enabled improvements in efficiency. Schwefel and his team are collaborating with New Zealand-based optical technology company Coherent Solutions to develop applications and are also investigating the use of their frequency combs for high-precision spectroscopy.[23][22][14][24][25][26][19]

The WGMRs also show potential for reducing the line-width of fibre lasers. Schwefel and his team have found that placing a WGMR as a passive filtering element within the loop of a fibre laser reduces the line width to sub-kHz levels, which improves the stability of the system.[27]

Quantum computing and communication

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Schwefel's team have used their WGMRs to coherently convert microwave photons into optical photons. This offers a method for coherent optical telecommunication between individual quantum computers.[28] Some superconducting quantum computers use microwave photons as the qubits for quantum information processing. As microwave photons are lost outside the ultra-cold environment of a cryostat, they cannot be used to communicate through ambient temperatures between quantum computers. Converting microwave signals into the optical domain and vice versa enables the use of conventional optical telecommunications networks for communication. Schwefel and his team have achieved coherent conversion by sending microwave photons into their WGMRs along with an optical signal. The two signals interact producing a third optical output signal that is coherent with the original microwave signal.[29][30]

They are working with researchers at the Max Planck Institute for the Science of Light to study the quantum properties of light that has been converted from optical to microwave light in a lithium niobate WGMR.[31][30]

In 2017 Schwefel won the Bright Ideas Competition, sponsored by the Optical Society of America Foundation and the international laser manufacturer Quantel Laser. He won the competition for his proposal to generate photon triplets, a new quantum optical state of light with applications in quantum optics and secure communications. The prize was $30,000 (US) worth of laser equipment, which he proposed to use to generate the photon triplets.[32][33][34][35]

Archeology collaboration

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Along with other researchers and students at the Dodd-Walls Centre, Schwefel has been working with American archeologist Leslie Van Gelder to develop an LED lamp that mimics the flickering torch light that palaeolithic cave artists worked by many thousands of years ago. The lamps will enable cave art to be seen in a more authentic light and help archaeologists answer questions about palaeolithic people and their techniques for creating cave art.[36][37]

Awards and honours

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References

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  1. ^ a b c "Yale Club Newsletter - 6 June 2006". www.yaleclub.de. Retrieved 25 August 2020.
  2. ^ "Harald G. L. Schwefel Profile". IEEE. 26 August 2020. Retrieved 25 August 2020.
  3. ^ a b "5. Alumnitreffen 2011 5. Alumnitreffen 2011 : Institut für Informatik". www.b-tu.de. Retrieved 25 August 2020.
  4. ^ a b c "Harald Schwefel". www.eng.yale.edu. Retrieved 25 August 2020.
  5. ^ a b c d ""You just have to try" Harald Schwefel has a scholarship from Yale University (USA) and is doing his doctorate there". Lausitzer Rundschau. 1 August 1998.
  6. ^ a b "Exam, internship and party, party ... 1,000 interested parties came to the BTU Info Day". Lausitzer Rundschau. 1 January 1998.
  7. ^ a b "500 students went on strike in Cottbus". Lausitzer Rundschau. 4 December 1997.
  8. ^ "Learning in the East offers students many advantages". Lausitzer Rundschau. 26 November 1997.
  9. ^ "Spring rolls and worry lines". Lausitzer Rundschau. 13 June 1997.
  10. ^ a b Physics, Department of. "Dr Harald Schwefel". www.otago.ac.nz. Retrieved 26 August 2020.
  11. ^ "Physics Tree - A Douglas Stone". academictree.org. Retrieved 25 August 2020.
  12. ^ "History of Japan Trust | NICT-情報通信研究機構". www.nict.go.jp. Retrieved 25 August 2020.
  13. ^ a b Board, Otago Bulletin. "Otago Physicist wins international competition". University of Otago. Retrieved 26 August 2020.
  14. ^ a b c Gibb, John (20 April 2019). "Device developed in Dunedin could revolutionise internet". Otago Daily Times Online News. Retrieved 26 August 2020.
  15. ^ "cv [Harald G. L. Schwefel]". www.wgmr.eu. Retrieved 26 August 2020.
  16. ^ Physics, Department of. "Dr Harald Schwefel". www.otago.ac.nz. Retrieved 28 August 2020.
  17. ^ a b Schwefel, Harald G. L. "Resonant Optics". Resonant Optics. Retrieved 28 August 2020.
  18. ^ "Lichtkamm für die Datenkommunikation getrimmt". wissenschaftler.de (in German). Retrieved 20 September 2020.
  19. ^ a b "Breakthrough research to revolutionise internet communication". Opli. Retrieved 21 September 2020.
  20. ^ Rueda, Alfredo; Sedlmeir, Florian; Kumari, Madhuri; Leuchs, Gerd; Schwefel, Harald G. L. (17 April 2019). "Resonant electro-optic frequency comb". Nature. 568 (7752): 378–381. arXiv:1808.10608. Bibcode:2019Natur.568..378R. doi:10.1038/s41586-019-1110-x. ISSN 1476-4687. PMID 30996319. S2CID 115811275.
  21. ^ a b "Lichtkamm für die Datenkommunikation getrimmt". wissenschaftler.de (in German). Retrieved 21 September 2020.
  22. ^ a b Rueda, Alfredo; Sedlmeir, Florian; Kumari, Madhuri; Leuchs, Gerd; Schwefel, Harald G. L. (April 2019). "Resonant electro-optic frequency comb". Nature. 568 (7752): 378–381. arXiv:1808.10608. Bibcode:2019Natur.568..378R. doi:10.1038/s41586-019-1110-x. ISSN 1476-4687. PMID 30996319. S2CID 115811275.
  23. ^ Gibb, John (18 April 2019). "Otago Uni research could change the internet with crystals". Otago Daily Times Online News. Retrieved 21 September 2020.
  24. ^ "Breakthrough research to revolutionise internet communication". phys.org. Retrieved 21 September 2020.
  25. ^ "Breakthrough research to revolutionise internet communication". Voxy. 18 April 2019.
  26. ^ Corner, Stuart (23 April 2019). "NZ team's laser breakthrough will boost optic network capacity". Computerworld. Retrieved 21 September 2020.
  27. ^ Sprenger, B.; Schwefel, H. G. L.; Lu, Z. H.; Svitlov, S.; Wang, L. J. (1 September 2010). "CaF2 whispering-gallery-mode-resonator stabilized-narrow-linewidth laser". Optics Letters. 35 (17): 2870–2872. arXiv:1208.0244. Bibcode:2010OptL...35.2870S. doi:10.1364/OL.35.002870. ISSN 1539-4794. PMID 20808352. S2CID 25038410.
  28. ^ Rueda, Alfredo; Sedlmeir, Florian; Collodo, Michele C.; Vogl, Ulrich; Stiller, Birgit; Schunk, Gerhard; Strekalov, Dmitry V.; Marquardt, Christoph; Fink, Johannes M.; Painter, Oskar; Leuchs, Gerd (20 June 2016). "Efficient microwave to optical photon conversion: an electro-optical realization". Optica. 3 (6): 597. arXiv:1601.07261. Bibcode:2016Optic...3..597R. doi:10.1364/OPTICA.3.000597. ISSN 2334-2536. S2CID 33887205.
  29. ^ "Harald Schwefel: A breakthrough to help quantum computers talk to each other". YouTube. 23 September 2019.
  30. ^ a b Schwefel, Harald G. L. (22 February 2018). "Nonlinear and Quantum Optics". Resonant Optics. Retrieved 21 September 2020.
  31. ^ Förtsch, Michael; Schunk, Gerhard; Fürst, Josef U.; Strekalov, Dmitry; Gerrits, Thomas; Stevens, Martin J.; Sedlmeir, Florian; Schwefel, Harald G. L.; Nam, Sae Woo; Leuchs, Gerd; Marquardt, Christoph (11 February 2015). "Highly efficient generation of single-mode photon pairs from a crystalline whispering-gallery-mode resonator source". Physical Review A. 91 (2): 023812. arXiv:1404.0593. Bibcode:2015PhRvA..91b3812F. doi:10.1103/PhysRevA.91.023812. S2CID 118910860.
  32. ^ Board, Otago Bulletin. "Otago Physicist wins international competition". University of Otago. Retrieved 21 September 2020.
  33. ^ Magazine, Otago. "Seeing the light". www.otago.ac.nz. Retrieved 21 September 2020.
  34. ^ Physics, Department of. "Dr Harald Schwefel Wins International Competition". University of Otago. Retrieved 21 September 2020.
  35. ^ "We are the finalist of OSA/Quantel Bright Idea Competition | Photoacoustic Imaging Lab". photoacoustics.pratt.duke.edu. Retrieved 21 September 2020.
  36. ^ "Quantum physicists shining new light on cave art". The Archaeology News Network. Retrieved 21 September 2020.
  37. ^ "Day of light: Quantum physics and ancient cave art". RNZ. 16 May 2019. Retrieved 21 September 2020.
  38. ^ Lewis, John (9 December 2022). "Physicist recognised for pioneering work". Otago Daily Times Online News. Archived from the original on 8 December 2022. Retrieved 8 December 2022.
  39. ^ "Optica Announces 2023 Fellows Class". Optica. 8 November 2022. Archived from the original on 8 November 2022. Retrieved 8 December 2022.