Apr 26, 2024
10:30am - 10:45am
Room 420, Level 4, Summit
Shan-Wen Cheng1,Ding Xu1,Haowen Su1,James Baxter1,Luke Holtzman2,Kenji Watanabe3,Takashi Taniguchi3,James Hone2,Katayun Barmak2,Milan Delor1
Department of Chemistry, Columbia University1,Columbia University2,National Institute for Materials Science3
Shan-Wen Cheng1,Ding Xu1,Haowen Su1,James Baxter1,Luke Holtzman2,Kenji Watanabe3,Takashi Taniguchi3,James Hone2,Katayun Barmak2,Milan Delor1
Department of Chemistry, Columbia University1,Columbia University2,National Institute for Materials Science3
Hexagonal boron nitride (hBN) hosts phonon polaritons (PhP), hybrid light-matter states that facilitate electromagnetic field confinement and exhibit long-range ballistic transport. Extracting the spatiotemporal dynamics of PhPs usually requires tour-de-force experimental methods such as ultrafast near-field infrared microscopy. Here, we leverage the remarkable environmental sensitivity of excitons in two-dimensional transition metal dichalcogenides to image PhP propagation in adjacent hBN slabs. Using ultrafast optical microscopy on monolayer WSe2/hBN heterostructures, we image propagating PhPs from 3.5 K to room temperature with sub-picosecond and few-nanometer precision. Excitons in WSe2 act as transducers between visible light pulses and infrared PhPs, enabling visible-light imaging of PhP transport with far-field microscopy. We also report evidence of excitons in WSe2 co-propagating with hBN PhPs over several microns. Our results provide new avenues for imaging polar excitations over a large frequency range with extreme spatiotemporal precision, and new mechanisms to realize ballistic exciton transport at room temperature.