Articles in 2018

Linewidth broadening of a phonon laser operated at an exceptional point of a compound optomechanical system is experimentally demonstrated.

By seeding a non-resonant aluminium-gallium-arsenide-on-insulator nanowaveguide with 10-GHz picosecond pulses at a low pump power of 85 mW, a single energy-efficient frequency comb source carrying 661 Tbit s^–1 of data, equivalent to more than the total Internet traffic today, is achieved.

The observation of spin-dependent lateral displacements of anisotropic and inhomogeneous media with the naked eye is reported, allowing structured light–matter interaction to move from a scientific curiosity to a new asset for the optical manipulation toolbox.

Interferometric analysis of the weak light scattered from proteins makes it possible to determine their mass.

Efficient photon upconversion is desired for applications ranging from molecular sensing to solar-energy harvesting. Now, the population of hidden triplet state electrons, created on dye antennas and rare-earth-doped nanoparticles, has been amplified to brighten upconversion by five orders of magnitude.

The International Day of Light is an achievement that the entire photonics community can be proud of. Let’s be inspired by the celebrations to begin planning for next year’s event.

The finding that the quasi-1D crystal BaTiS₃ features a large optical anisotropy and a broadband birefringence spanning the infrared is likely to reignite interest in quasi-1D optical materials.

The demonstration of broadband, electrically tunable third-order nonlinear optical responses in graphene is promising for a host of nonlinear optical applications.

A nonlinear charge oscillation driven by a 6 fs light field of 11 MV cm^–1 is observed in a layered organic superconductor. The initial response time of the oscillation on the timescale of 10 fs clarifies that Coulomb repulsion is essential for the superconductivity.

Using high-temperature gas mixtures as the generation medium to increase the translational velocity of Xe atoms through the focus of a femtosecond enhancement cavity, phase-matched extreme-ultraviolet emission at a repetition rate of 77 MHz and with an average power of ~ 2 mW in a single harmonic order is achieved.

Near-infrared femtosecond laser pulses are sent to a Si or ZnO crystal to generate high-harmonic waves via static or transient field-induced optical nonlinearities. The beam profile of the high-harmonic emission is controlled by electronic methods.

Highly crystalline BaTiS₃ has been shown to exhibit record-breaking birefringence of 0.76 in the wavelength range of 7–16 μm. The large anisotropy is a result of its quasi-one-dimensional structure.