As a Post-Doctoral Associate, I lead cutting-edge experimental and theoretical research on parametric amplifiers, nonlinear effects in all-optical signal regeneration, and quantum networks using multi-core and multimode fibers. I mentor graduate and undergraduate students and actively contribute to academic publications, advancing the field.Below listed are some of my achievements within this role:• Chosen for participation in the prestigious university-funded RISE 100 program.• Contributed to organizing and coordinating events and activities as a member of the UTA Photonic Center organizing committee.• Installed the superconductive nanowire single photon detector• Successfully demonstrated first experimental implementation of Mamyshev-regenerator-based phase-preserving amplitude regenerator utilizing periodic group delay managed media.

I led innovative research on parametric amplifiers, nonlinear effects in few-mode fiber, and all-optical signal regeneration. By aligning the zero-dispersion wavelength through temperature-tuning multi-segment highly nonlinear fiber, I successfully suppressed stimulated Brillouin scattering. I pioneered the experimental implementation of a hybrid S-band optical amplifier, integrating erbium-doped fiber amplifiers with parametric wavelength converters. Additionally, I demonstrated dynamic reconfigurability in spatial-mode-selective frequency conversion and spatially entangled photon generation in few-mode optical fiber.Below listed are some of my achievements within this role:• Filed patent for all-optical phase-preserving regeneration and demonstrated performance of single-channel system.• Achieved first experimental demonstration of a Mamyshev-regenerator-based phase-preserving amplitude regenerator using LEAF fiber.• Published three journal articles and contributed to 22 conference papers presented at top optical communication events, including OFC, CLEO, and IPC.

• Performed repair and maintenance operations on superconducting nanowire single-photon detectors (SNSPD) to ensure optimal performance and reliability.• Achieved exceptional 12.5 bits/photon photon-information efficiency in experimental demonstration of optical clock transmission and recovery, overcoming 77 dB of optical path loss.• Conducted experimental and theoretical research on optical clock recovery for deep space communication by utilizing superconducting nanowire single-photon detectors and pulse-position modulation formats.

• Spliced multi-core and multimode fibers to ensure optimal performance in various applications.• Designed and fabricated photonic lanterns using 3-mode elliptical-core few-mode fiber structures. • Conducted experimental and simulation research on photonic lanterns and pulse-position modulation techniques.

I conducted in-depth experimental and theoretical analysis on frequency-modulated continuous wave (FMCW) LiDAR systems, driving the experimental generation of Nyquist pulses for cutting-edge signal processing. I designed and implemented innovative microwave photonic systems, enhancing FMCW LiDAR applications for advanced research.Below listed are some of my achievements within this role:• Authored two journal articles and four conference papers on advanced research topics.• Executed experimental demonstration of Nyquist pulse generation utilizing digital multi-tone synthesis methods.• Conducted experimental demonstration of wideband frequency sweeping of light via single-sideband modulation techniques.