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Light-Matter Interaction and Quantum Computing in Rare-Earth-Ion-Doped Crystals Kinos, Adam PDF

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Light-Matter Interaction and Quantum Computing in Rare-Earth-Ion-Doped Crystals Kinos, Adam 2018 Document Version: Publisher's PDF, also known as Version of record Link to publication Citation for published version (APA): Kinos, A. (2018). Light-Matter Interaction and Quantum Computing in Rare-Earth-Ion-Doped Crystals. [Doctoral Thesis (compilation), Atomic Physics]. Atomic Physics, Department of Physics, Lund University. Total number of authors: 1 Creative Commons License: CC BY-NC General rights Unless other specific re-use rights are stated the following general rights apply: Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal Read more about Creative commons licenses: https://creativecommons.org/licenses/ Take down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. LUND UNIVERSITY PO Box 117 221 00 Lund +46 46-222 00 00 Download date: 06. Feb. 2023 ABEL 3041 0903 ADAM KIN OL O N EC S A C SW Media-Tryck, Lund 2018 NORDI Light-Matter Inte LQiughant-tMumat tCero Imnpteurtaicntgio inn aRnadr e- Printed by ractio Earth-Ion-Doped Crystals n a n d Q ADAM KINOS u DEPARTMENT OF PHYSICS | FACULTY OF ENGINEERING | LUND UNIVERSITY a n t u m C o m p u t i n g i n R a r e - E a r t h - I o n - D This thesis, written by Adam Kinos, contains o research on wave propagation in absorbing p e birefringent crystals, slow light applications, d C and quantum computing using rare-earth- r ion-doped crystals, as well as extensive ys t light-matter interaction discussions surroun- a ls ding the same topics. ISIBSNBFN:a D9c: u7i9v8l7iDts-8yi9eo- 1op9n-1fLa7 -UorE77tfnN57m I3gA5SDe-iS3t n5noNU-4e5tm N3 e04oIi-r24cVf0i8n - EPP71(gRhhp -(,2Syyrp L7iIssdnTTii6ccftHY2ss)) 9177535430 20 Lund Reports on Atomic Physics, LRAP-543 (2018) 78 18 9 Light-matter interaction and quantum computing in rare-earth-ion-doped crystals Adam Kinos Doctoral Thesis 2018 Akademisk avhandling som f¨or avla¨ggande av teknologie doktorsexamen vid tekniska fakulteten vid Lunds Universitet kommerattoffentligenf¨orsvarasden2mars2018,kl. 09.15iRydbergssal,p˚aFysiskaInstitutionen,Professorsgatan1, Lund. Fakultetsopponent: Dr. CharlesW.Thiel MontanaStateUniversity,USA Academicthesiswhich,byduepermissionoftheFacultyofEngineeringatLundUniversity,willbepubliclydefendedon 2ndofMarch2018,at09.15a.m. inRydberg’shall,attheDepartmentofPhysics,Professorsgatan1,Lund,forthedegree ofDoctorofPhilosophyinEngineering. Faculty opponent: Dr. CharlesW.Thiel MontanaStateUniversity,USA Organization Document name LUND UNIVERSITY DOCTORAL DISSERTATION Date of issue Division of Atomic Physics January, 2018 Department of Physics P.O. Box 118 Sponsoring organization SE-221 00 Lund, Sweden Author Adam Kinos Title and subtitle Light-Matter Interaction and Quantum Computing in Rare-Earth-Ion-Doped Crystals Abstract In this thesis, crystals of yttrium orthosilicate (Y2SiO5) that are randomly doped with another rare-earth element, such as praseodymium (Pr), europium (Eu), or cerium (Ce), are investigated with lasers locked to ultra-stable cavities using the Pound-Drever-Hall locking technique. Many of these rare-earth elements have long-lived 4f-4f transitions, hundreds of microseconds to a few milliseconds, with even longer ground hyperfine lifetimes of up to several days. The coherence properties are, to the best of the author's knowledge, the longest achieved for any material, currently with a record of six hours for the nuclear spin states of Eu3+:Y2SiO5 measured at cryogenic temperatures. Furthermore, due to natural trapping and differences in the local environments, each dopant ion experiences a slightly different crystal field, and thus an inhomogeneity in the 4f-4f transition exists between all ions in a crystal. Since the homogeneous linewidth is in the order of kHz or below, whereas the inhomogeneous profile can be several GHz wide, these materials have dense storing capabilities. This thesis explores how light interacts with such rare-earth-ion-doped crystals; how the absorption and light polarization varies during propagation; how spectral features in the inhomogeneous absorption profile can be tailored to create narrowband spectral filters; how the speed of light is slowed down significantly in such narrow transmission windows; and how that can be used to either frequency shift incoming light, control its group velocity, or temporally compress pulses. It also uses rare-earth-ions to research quantum computing, the field of using quantum mechanical effects such as superpositions and entanglements to outperform classical computers on certain specific problems. This is done by examining how two-color pulses can be used to rapidly induce coherence from an initially mixed state; how qubit-qubit interactions can be performed experimentally using ensemble qubits, which opens the door to two-qubit experiments such as the CNOT-gate and entanglements; how a scalable quantum computer might be constructed using a single ion qubit approach with a dedicated readout ion and buffer ion(s) to improve readout fidelity; and how cerium is investigated as a candidate for such a dedicated readout ion. Key words: Rare-earth-ion-doped crystals, Light-matter interaction, Quantum computing, Slow light Classification system and/or index terms (if any): Supplementary bibliographical information: Language English ISSN and key title: ISBN ISSN 0281-2762, Lund Reports on Atomic Physics, LRAP-543 978-91-7753-543-0 Recipient’s notes Number of pages Price 219 Security classification I, the undersigned, being the copyright owner of the abstract of the above-mentioned dissertation, hereby grant to all reference sources permission to publish and disseminate the abstract of the above-mentioned dissertation. Signature Date January 22nd 2018 Light-matter interaction and quantum computing in rare-earth-ion-doped crystals Adam Kinos Doctoral Thesis 2018 Light-matter interaction and quantum computing in rare-earth- ion-doped crystals '2018AdamKinos Allrightsreserved PrintedinSwedenbyMedia-Tryck,Lund,2018 DivisionofAtomicPhysics DepartmentofPhysics FacultyofEngineering,LTH LundUniversity P.O.Box118 SE–22100Lund Sweden http://www.atomic.physics.lu.se ISSN: 0281-2762 LundReportsonAtomicPhysics,LRAP-543 (2018) ISBN(print): 978-91-7753-543-0 ISBN(pdf): 978-91-7753-544-7 Abstract In this thesis, crystals of yttrium orthosilicate (Y SiO ) that 2 5 are randomly doped with another rare-earth element, such as praseodymium (Pr), europium (Eu), or cerium (Ce), are inves- tigatedwithlaserslockedtoultra-stablecavitiesusingthePound- Drever-Hall locking technique. Many of these rare-earth elements have long-lived 4f-4f transi- tions, hundreds of microseconds to a few milliseconds, with even longer ground hyperfine lifetimes of up to several days. The co- herence properties are, to the best of the author’s knowledge, the longest achieved for any material, currently with a record of six hoursforthenuclearspinstatesofEu3+:Y SiO measuredatcryo- 2 5 genictemperatures. Furthermore,duetonaturaltrappinganddif- ferences in the local environments, each dopant ion experiences a slightly different crystal field, and thus an inhomogeneity in the 4f-4f transition exists between all ions in a crystal. Since the ho- mogeneous linewidth is in the order of kHz or below, whereas the inhomogeneous profile can be several GHz wide, these materials have dense storing capabilities. This thesis explores how light interacts with such rare-earth- ion-doped crystals; how the absorption and light polarization varies during propagation; how spectral features in the inhomo- geneous absorption profile can be tailored to create narrowband spectral filters; how the speed of light is slowed down significantly in such narrow transmission windows; and how that can be used to either frequency shift incoming light, control its group velocity, or temporally compress pulses. Italsousesrare-earth-ionstoresearchquantumcomputing,the field of using quantum mechanical effects such as superpositions and entanglements to outperform classical computers on certain specificproblems. Thisisdonebyexamininghowtwo-colorpulses can be used to rapidly induce coherence from an initially mixed state; how qubit-qubit interactions can be performed experimen- tally using ensemble qubits, which opens the door to two-qubit experiments such as the CNOT-gate and entanglements; how a scalable quantum computer might be constructed using a single iii ion qubit approach with a dedicated readout ion and buffer ion(s) to improve readout fidelity; and how cerium is investigated as a candidate for such a dedicated readout ion. iv Popula¨rvetenskaplig sammanfattning Ljus-materia v¨axelverkan ¨ar n˚agot som finns ¨overallt: ljus gener- eras i lampor; absorberas eller reflekteras av material; fokuseras p˚a n¨athinnorna med hj¨alp av linserna i v˚ara ¨ogon; tapparna och stavarna absorberar ljuset; och signaler skickas via synnerven vi- dare till hj¨arnan s˚a att vi kan tolka v¨arlden runtom oss i f¨arger, m¨orker, och ljus. V¨aldigt kortfattat fungerar det enligt f¨oljande: det inkom- mande ljusets sv¨angningar f˚ar atomernas elektroner att b¨orja sv¨anga och skicka ut sitt eget ljus, som tillsammans med det ursprungliga ljuset, likt tv˚a vattenv˚agor, kan sl¨acka ut eller f¨orst¨arka varandra. Samtidigt kan atomerna absorbera energin fr˚an ljusv˚agen och exciteras. Denna avhandlingen handlar om hur ljus interagerar med ett specifikt material, n¨amligen kristaller dopade med s¨allsynta jor- dartsmetaller som, t.ex., praseodymium eller europium. S˚adana atomer ¨ar intressanta att unders¨oka eftersom de har v¨aldigt l˚anga livstider, vilket betyder att de kan vara exciterade en rel- ativt (millisekunder) l˚ang tid innan de ˚ater faller tillbaka till grundtillst˚andet, ibland genom att skicka ut nytt ljus. Dedopadekristallernaunders¨oksianknytningtillkvantdatorer som,ikontrastmedenvanligdatorvarsbitarendastkanvaranol- lor och ettor, har kvantbitar som ¨aven kan vara i tillst˚and som ¨ar b˚ade noll och ett samtidigt, s˚a kallade superpositioner. Man kan s¨agaattenkvantdatorhartillg˚angtillflervalm¨ojligheterf¨orvarje kvantbit. Dock, n¨ar man ska l¨asa ut vad en kvantbit ¨ar, f˚ar man alltid antingen noll eller ett som svar, ¨aven om kvantbiten innan man gjorde utl¨asningen var lite av b˚ada samtidigt. Detta betyder att utl¨asningen av en vanlig bit och en kvantbit b˚ada inneh˚aller endast en enhet av information (¨aven kallat en bit av informa- tion). Vid f¨orsta anblicken kan man d¨arf¨or tro att en kvantdator inte tillf¨or n˚agot som en klassisk dator inte redan har, men tack varaenkvantdatorsf¨orm˚agaattanv¨andakvantmekaniskafenomen s˚asom superpositioner och sammanfl¨atningar (engelska: entangle- v

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It also uses rare-earth-ions to research quantum computing, the field of using quantum mechanical effects such as .. istry, or biology. My work here has taught me about light-matter interaction and quantum mechanics, and it is my sincerest hope that this thesis will convey some of that knowledge to
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