Optical nonlinearities in excess of 500 through sublattice reconstruction

Article

Chen, Jiaye; Liu, Chang; Xi, Shibo; Tan, Shengdong; He, Qian; Liang, Liangliang; Liu, Xiaogang

National University of Singapore; Xiamen University; Agency for Science Technology & Research (A*STAR); National University of Singapore; Agency for Science Technology & Research (A*STAR); A*STAR - Institute of Materials Research & Engineering (IMRE); National University of Singapore

Nature

0028-3091

10.1038/s41586-025-09164-y

2025-07-17

The ability of materials to respond to stimuli with significant optical nonlinearity is crucial for technological advancement and innovation1, 2-3. Although photon-avalanche upconversion nanomaterials with nonlinearities exceeding 60 have been developed, further enhancement remains challenging4, 5-6. Here we present a method to increase photon-avalanche nonlinearity beyond 500 by reconstructing the sublattice and extending the avalanche network. We demonstrate that lutetium substitution in the host material induces significant local crystal field distortions. These distortions strengthen cross-relaxation, the key process governing population accumulation. As a result, the optical nonlinearity is significantly amplified, enabling sub-diffraction imaging through single-beam scanning microscopy, achieving lateral and axial resolutions of 33 nm (about 1/32 of lambda Exc) and 80 nm (around 1/13 of lambda Exc), respectively (where lambda Exc is the excitation wavelength). Moreover, our research shows regional differentiation within photon-avalanche nanocrystals, in which photon-avalanche performance varies across different regions at the single-nanoparticle level. This effect, coupled with extreme optical nonlinearity, enables visualization of nanoemitters at resolutions beyond their physical size using simple instrumentation. These advancements open new possibilities for super-resolution imaging, ultra-sensitive sensing, on-chip optical switching and infrared quantum counting.