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The chemical equilibrium is optimized using N-dodecylbenzene sulfonic acid for enhancing the crystal integrity and structural rigidity of CsPbBr3 perovskite nanoplatelets, resulting in their spectrally stable, bright and extremely narrow color-saturated blue emission.
Illustration of entangled photon pair generation in an integrated silicon carbide (SiC) platform. This achievement, coupled with SiC’s potential to integrate various electrical, photonic and quantum technologies in the same device platform, offers promises for the scalable implementation of quantum information processing.
A novel, single-shot probing technique visualizes the ultrafast laser-induced solid-to-plasma transition. The entire target dynamics (ionization to overdense plasma) is elucidated by combining solid-state interaction model and kinetic plasma description.
The pure-high-even-order dispersion bound solitons complexes, which build up in high-order dispersion management ultra-fast fiber laser, are revealed both theoretically and experimentally, enriching the framework towards multi-soliton complexes.
We propose a general theory concerning Bloch oscillations in photonic Floquet lattices and report the first visual observation of the Bloch-like oscillations, which are termed the “photonic Floquet–Bloch oscillations.”
Non-Hermitian skin states, an exotic form of quantum states condensed at the boundary of certain dissipative systems, are disclosed in incoherent models of quantum walks in synthetic photonic matter.
The stereoscopic photoacoustic microscopy is proposed to achieve wide-field intravital imaging of the lymphatic system in mice, facilitating three-dimensional high-resolution visualization of meningeal lymphatic vessels on the meninges.
This work studies luminescence from monocrystalline gold flakes down to 13 nm thick. It reveals this signal is photoluminescence, with signals reproduced by density functional theory, resolving a decade-old puzzle.