Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
Cr3+-sensitized lanthanide-doped nanoparticles afford high-brightness luminescence in the near-infrared region for applications in in vivo non-invasive bioimaging.
Integrating an organic photodiode with a tandem OLED enables positive photonic feedback that results in bistable behaviour. Devices show giant hysteresis in their current–voltage–luminance characteristic and upconversion of near-infrared to visible light with 100-fold photon-to-photon gain.
A Brillouin laser-driven terahertz oscillator is developed. The phase noise level of the generated terahertz waves is less than –100 dBc Hz–1, translating to timing noise below 10 as Hz–1/2 at 10 kHz Fourier frequency, over a carrier frequency range from 300 GHz to 3 THz.
Dual-comb spectroscopy with time–frequency dissemination and high-power frequency combs enables sensing CO2 and H2O over a 113 km turbulent open-air path, with a sensing precision as high as 2 parts per million of CO2.
Silicon photonic circuits offer a promising solution for the interconnect bottleneck for advanced computing systems, but they typically require additional materials, such as germanium for photodetection. An all-silicon receiver capable of handling a data stream at 1.28 terabits per second is paving the way for future optical interconnects.
The field of plasmonics continues to show its potential scientific and technological impact, as new companies exploiting plasmonics beyond sensing applications emerge.
The nonlinear optical response of achiral molecules spread on chiral nanostructured substrates and subjected to circularly polarized light is examined. The experiment is a step towards confirming a long-standing theoretical prediction: hyper-Raman optical activity.
Short-wave infrared photothermal microscopy enables deep-tissue vibrational imaging at millimetre depth with high sensitivity and sub-cellular spatial resolution, offering potential for applications in biological and medical fields.
Terahertz waveforms can now be measured with atomic-scale spatial resolution as a result of a new form of terahertz time-domain spectroscopy that uses tunnelling electrons as an ultrafast, localized probe. The approach paves the way for ultrafast optical surface analysis at the scale of individual molecules or atoms.
The mitigation of climate change requires major transformations in the ways we generate energy and operate technologies that release carbon dioxide. Photonic concepts and novel light-driven technologies provide many potential solutions, transforming our current modes of energy use into more effective and sustainable ones.
Nathalie Picqué, the new director at the Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy (MBI) in Berlin, Germany, tells us all we need to know about frequency combs and dual-comb spectroscopy, and shares with us some golden tips on becoming a successful scientist.
Using a gas–solid mixture approach, researchers used a transparent, scintillating nanoporous material for real-time detection of 85Kr and 3H, two pure beta emitters. They also simultaneously measure a mixture of them. The broadly applicable approach may be useful for nuclear industry and environmental safeguarding.
The researchers synthesize organic–inorganic hybrid inverse perovskites that exhibit excellent carrier lifetime and mobility–lifetime product and high resistivity, enabling stable X-ray detectors with performance arguably outperforming state-of-the-art perovskite single-crystal detectors.
Highly twisted multi-boron-based multiple-resonance thermally activated delayed fluorescence emitters enable deep-blue organic light-emitting diodes with high colour purity, a narrow full-width at half-maximum of 14 nm and a peak external quantum efficiency of 39.2%.
Based on the acquisition of a multi-spectral reflection matrix at a high frame rate, a fully digital microscope overcomes aberrations and multiple scattering to provide a three-dimensional image of an ex vivo opaque cornea at a resolution of 0.29 μm and 0.5 μm in the transverse and axial directions, respectively.
A direct lead-halide perovskite CT imager has been demonstrated. The detector arrays have 980 μm absorber thickness and exhibit detection quantum efficiency of 80% and noise-equivalent dose of 153 pGyair.
Using electrostatic doping, the real and imaginary parts of the refractive index along the extraordinary axis of semiconducting, highly aligned, single-walled carbon nanotubes over 4″ wafers can be tuned by up to 5.9% and 14.3% in the infrared at 2,200 nm and 1,660 nm, respectively.