- All Categories
- Featured Events
- Alumni
- Application Deadline
- Arts
- Campus Discourse
- Careers
- BU Central
- Center for the Humanities
- Charity & Volunteering
- Kilachand Center
- Commencement
- Conferences & Workshops
- Diversity & Inclusion
- Examinations
- Food & Beverage
- Global
- Health & Wellbeing
- Keyword Initiative
- Lectures
- LAW Community
- LGBTQIA+
- Meetings
- Orientation
- Other Events
- Religious Services & Activities
- Special Interest to Women
- Sports & Recreation
- Social Events
- Study Abroad
- Weeks of Welcome
- Bodhi DayAll day
- Immaculate ConceptionAll day
- Behind the Scenes of COM Graduate Student Life10:00 am
- Coffee with A Cop11:00 am
- Joshua Lo Dissertation Defense2:30 pm
- Tai Po Fire Support Group4:00 pm
- Aurora Borealis: A Festival of Light and Dance7:00 pm
- Aurora Borealis: A Festival of Light and Dance7:00 pm
- Clockwork7:00 pm
- Boston University Symphony Orchestra7:30 pm
- Aurora Borealis: A Festival of Light and Dance9:00 pm
- ECE PhD Thesis Defense: Danchen Jia11:00 am
- How Setting Up Informational Interviews NOW will Advance Your Career LATER12:00 pm
- ECE PhD Prospectus Defense: Zeynep Ece Kizilates2:00 pm
- ECE PhD Thesis Defense: Daniel Shahar2:00 pm
- Employee Commuter Benefit Party4:00 pm
- Pre-Law Basics for Freshmen4:00 pm
- [UMich] ROMS Postdoc Fellowship 2025 Virtual Information Session4:00 pm
- The Limits of "Mixedness": Ethno-National Conflicts in post-1948 Israel’s “Mixed Cities”4:30 pm
- Winter Movie Night5:00 pm
- 2025 Springboard Series7:00 pm
- Tuesday Night Lecture Series: Jennifer Roberts7:00 pm
- Directors' Project7:30 pm
ECE PhD Thesis Defense: Daniel Shahar
ECE PhD Thesis Defense: Daniel Shahar
Title: High-Dimensional Orbital Angular Momentum Entanglement in Optical Fibers
Presenter: Daniel I. Shahar
Advisor: Professor Siddharth Ramachandran
Chair: Professor Eshed Ohn-Bar
Committee: Professor Siddharth Ramachandran, Professor Alexander Sergienko, Professor David Bishop, Dr. Dashiell Vitullo, Professor Virginia Lorenz
Google Scholar Link: https://scholar.google.com/citations?user=unPOkGoAAAAJ&hl=en
Abstract: Quantum states encoded in high-dimensional Hilbert spaces provide advantages over conventional two-level systems, including increased information capacity per photon, enhanced robustness against noise, and stronger violations of local realism in entanglement tests. The photon’s orbital angular momentum (OAM), with its unbounded integer values, is a natural platform for such encoding. Traditionally, OAM states are generated through spontaneous parametric downconversion (SPDC) in bulk crystals, but the resulting free-space modes are not directly compatible with optical fiber networks and typically require lossy post-selection to equalize mode-dependent emission amplitudes.
This work investigates the generation of high-dimensional OAM states in multimode ring-core fibers (RCFs) using intermodal spontaneous four-wave mixing (SFWM). The stability and scalability of OAM propagation in RCFs are analyzed, followed by the principles of SFWM between guided modes. A versatile inverse-design algorithm enables complete control over the amplitude and phase of the pump field, supporting arbitrary OAM superpositions and processing of the generated states. The spectral correlations of the emitted photon pairs, described by the joint spectral amplitude (JSA), are shown to depend on mode selection and can be tuned nondestructively from correlated to uncorrelated to anti-correlated distributions. High single-photon performance is demonstrated with heralded second-order correlations below 0.005 and coincidence-to-accidental ratios above 4000, which to the best of current knowledge represent the highest values reported for fiber-based systems using avalanche photodetectors. Furthermore, through enforcement of JSA overlap, OAM correlations spanning 15 transverse dimensions in fiber are identified, each maintaining high single-photon performance. This result establishes a foundation for fiber-based high-dimensional transverse-mode entanglement and outlines a scalable pathway toward quantum networks.
| When | 2:00 pm - 4:00 pm on 9 December 2025 |
|---|---|
| Building | PHO 339 |