38 research outputs found
On-chip optical parametric oscillation into the visible: generating red, orange, yellow, and green from a near-infrared pump
Optical parametric oscillation (OPO) in a microresonator is promising as an
efficient and scalable approach to on-chip coherent visible light generation.
However, so far only red light at < 420 THz (near the edge of the visible band)
has been reported. In this work, we demonstrate on-chip OPO covering > 130 THz
of the visible spectrum, including red, orange, yellow, and green wavelengths.
In particular, using a pump laser that is scanned 5 THz in the near-infrared
from 386 THz to 391 THz, the signal is tuned from the near-infrared at 395 THz
to the visible at 528 THz, while the idler is tuned from the near-infrared at
378 THz to the infrared at 254 THz. The widest signal-idler separation we
demonstrate of 274 THz corresponds to more than an octave span and is the
widest demonstrated for a nanophotonic OPO to date. Our work is a clear
demonstration of how nonlinear nanophotonics can transform light from readily
accessible compact near-infrared lasers to targeted visible wavelengths of
interest, which is crucial for field-level deployment of spectroscopy and
metrology systems.Comment: 6 pages, 5 figure
A universal frequency engineering tool for microcavity nonlinear optics: multiple selective mode splitting of whispering-gallery resonances
Whispering-gallery microcavities have been used to realize a variety of
efficient parametric nonlinear optical processes through the enhanced
light-matter interaction brought about by supporting multiple high quality
factor and small modal volume resonances. Critical to such studies is the
ability to control the relative frequencies of the cavity modes, so that
frequency matching is achieved to satisfy energy conservation. Typically this
is done by tailoring the resonator cross-section. Doing so modifies the
frequencies of all of the cavity modes, that is, the global dispersion profile,
which may be undesired, for example, in introducing competing nonlinear
processes.Here, we demonstrate a frequency engineering tool, termed multiple
selective mode splitting (MSMS), that is independent of the global dispersion
and instead allows targeted and independent control of the frequencies of
multiple cavity modes. In particular, we show controllable frequency shifts up
to 0.8 nm, independent control of the splitting of up to five cavity modes with
optical quality factors , and strongly suppressed frequency
shifts for untargeted modes. The MSMS technique can be broadly applied to a
wide variety of nonlinear optical processes across different material
platforms, and can be used to both selectively enhance processes of interestand
suppress competing unwanted processes.Comment: 13 pages, 8 figure