Natalie Fardian-Melamed1,Changhwan Lee1,Hye Sun Park2,Ayelet Teitelbaum3,Kevin Kwock1,Thomas Darlington1,Bruce Cohen3,Emory Chan3,Sang Hwan Nam2,Yung Doug Suh2,P. James Schuck1
Columbia University1,Korea Research Institute of Chemical Technology2,Lawrence Berkeley National Laboratory3
Natalie Fardian-Melamed1,Changhwan Lee1,Hye Sun Park2,Ayelet Teitelbaum3,Kevin Kwock1,Thomas Darlington1,Bruce Cohen3,Emory Chan3,Sang Hwan Nam2,Yung Doug Suh2,P. James Schuck1
Columbia University1,Korea Research Institute of Chemical Technology2,Lawrence Berkeley National Laboratory3
It has recently been demonstrated that ensembles of upconverting nanoparticles (UCNPs) exhibit changes in their emission spectra due to applied stress [1, 2]. Avalanching UCNPs (ANPs) [3], possessing steeply nonlinear optical responses, are ideally suited for sensing minute changes in their environments, as small perturbations are expected to usher large changes in signal. Because ANPs absorb and emit tissue-penetrating near-infrared (NIR) light, they are uniquely positioned for sensing within biological cells and fluids. To characterize and understand the response of these ANPs to local stress, it is important to study their mechano-opto-physics on a <i>single particle level. </i>Utilizing a custom designed combined AFM and inverted optical microscope system, we correlate sub-nano-Newton applied forces and observable changes in hyperspectral optical signals for isolated single UCNPs, demonstrating their potential as local force sensors.<br/>[1] Lay A, et al. <i>Nano Letters</i> 2017, 17(7), 4172-4177<br/>[2] Lay A, et al. <i>ACS Central Science </i>2019, <i>5</i>(7), 1211-1222<br/>[3] Lee C, et al. <i>Nature </i>2021, <i>589</i>(7841), 230-235<br/>NFM acknowledges support from the European Union's Horizon 2020 research and innovation program under the Marie Sklodowska-Curie grant agreement No 893439, the Fulbright Scholarship Program, the Zuckerman-CHE STEM Leadership Program, and the ISEF Foundation.