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THE SCHOOL OF MATERIALS SCIENCE AND ENGINEERING
GEORGIA INSTITUTE OF TECHNOLOGY
Under the provisions of the regulations for the degree
DOCTOR of PHILOSOPHY
on Wednesday June 6, 2018
1:30 PM
in MoSE 1201A
will be held the
DISSERTATION DEFENSE
for
Chun Hao Lin
“CONTROLLING LIGHT-MATTER INTERACTIONS IN QD
PHOTONIC SOURCES VIA OPTICAL GAIN AND LOSS”
Committee Members:
Dr. Vladimir Tsukruk, Advisor, MSE
Prof. Zhiqun Lin, MSE
Prof. Wenshan Cai, MSE/ECE
Prof. Dong Qin, MSE
Prof. Eric Vogel, MSE
Abstract:
The goal of this research is to control light-matter interactions in three levels of hierarchical robust photonic systems: individual and assembled nanostructures, individual local assemblies and coupled local assemblies. Specifically, controlled optical properties of individual nanostructures such as emission/absorption peak position and photoluminescence intensity will be investigated via the selection of materials and dimensions. In addition, spatial arrangements of assembled nanostructures will be examined to see the effect on the degree of light amplification/attenuation and real refractive index which are important variables for the design of novel photonic systems that obey parity-time symmetry. Finally, manipulation of optical activity of local assemblies including cavity modes, emission output and mode splitting will be investigated by altering coupling strength between assemblies, localized gain/loss contrast and arrangement of engineered defects.
Conventionally, two types of materials have been used to fabricate common photonic systems: inorganic and organic systems. The inorganic system typically relies on the epitaxially-grown inorganic materials where lattice mismatch between different layers greatly limits the selection of materials and substrates. On the other hand, the organic system typically utilizes organic dyes as emitters whose photoluminescence intensity decreases significantly under strong optical pumping, known as photobleaching effect. It would be of great interest to develop new type of material that can mitigate all the issues encountered in these conventional systems by providing tunable optical properties, solution processability and stable lasing output. In this research, quantum dots are used as the optically active component due to their tunable emission and absorption properties that arise from the confinement of exciton within nanoscale quantum dots. In addition, they are solution- processable via the unique combination of organic ligands and inorganic cores, leading to improved material processing. Specifically, core/shell and ligand engineering were adopted to develop high quality assembled quantum dot solids with superior lasing properties such as tunable gain/loss values, low lasing thresholds and stable lasing output. Microscale and nanoscale deposition and microfabrication techniques were used to further arrange quantum dots into photonic cavities. In addition, physical and non-physical method are proposed to manipulate the optical gain/loss values in localized region to achieve the exceptional point. The design and fabrication principles in this work will help guide the development of miniaturized photonic system with highly tunable optical properties, tunable mode activity and other optical phenomena such as parity-time symmetry.
