The first two α-sila-dipeptides, 7 and cyclo-sila-dipeptide 8, were synthesized and characterized by several methods, including X-ray crystallography. Bulky t-BuMe Si substituents provide some kinetic stabilization to the synthesized molecules. 7 and 8 are the first examples of a "Si for C switch" in the central α-position of an amino acid or a peptide, in which silicon is bonded to both the amino and the carbonyl groups.
The first two a-sila-dipeptides, 7 and cyclo-siladipeptide 8,w ere synthesized and characterized by several methods,i ncluding X-rayc rystallography.B ulkyt -BuMe 2 Si substituents provides ome kinetic stabilization to the synthesized molecules. 7 and 8 are the first examples of a" Si for C switch"inthe central a-position of an amino acid or apeptide, in whichsilicon is bonded to both the amino and the carbonyl groups.
Thermal tuning of the optical refractive index in the
waveguides
to control light phase accumulation is essential in photonic-integrated
systems and applications. In silicon photonics, microheaters are mainly
realized by metal wires or highly doped silicon lines, placed at a
safe distance (∼1 μm) from the waveguide to avoid considerable
optical loss. However, this poses a significant limitation for heating
efficiency because of the excessive free-carrier loss when a heater
is brought closer to the optical path. In this work, we present a
new concept of using optically transparent 2D semiconductors (e.g.,
MoS2) for realizing highly efficient waveguide-integrated
heaters operating at telecom wavelengths. We demonstrate that a single-layer
MoS2 heater with negligible optical absorption in the infrared
can be placed in close proximity (only 30 nm) to the waveguide and
show the best-reported power consumption of P
π ∼ 7.5 mW for waveguide-integrated heaters (no
thermal insulations) without sacrificing the optical insertion loss.
The heater’s response time is ∼25 μs, which is
limited by the Au/1L-MoS2 Schottky contact. Both the efficiency
and response time can be further significantly improved by realizing
2D MoS2 heaters with Ohmic contacts. Our work shows clear
advantages of employing 2D semiconductors for heater applications
and paves the way for developing novel energy-efficient loss-less
2D heaters for on-chip photonic-integrated circuits.
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