15 research outputs found
Moonlight shifts the endogenous clock of Drosophila melanogaster
The ability to be synchronized by light–dark cycles is a fundamental property of circadian clocks. Although there are indications that circadian clocks are extremely light-sensitive and that they can be set by the low irradiances that occur at dawn and dusk, this has not been shown on the cellular level. Here, we demonstrate that a subset of Drosophila's pacemaker neurons responds to nocturnal dim light. At a nighttime illumination comparable to quarter-moonlight intensity, the flies increase activity levels and shift their typical morning and evening activity peaks into the night. In parallel, clock protein levels are reduced, and clock protein rhythms shift in opposed direction in subsets of the previously identified morning and evening pacemaker cells. No effect was observed on the peripheral clock in the eye. Our results demonstrate that the neurons driving rhythmic behavior are extremely light-sensitive and capable of shifting activity in response to the very low light intensities that regularly occur in nature. This sensitivity may be instrumental in adaptation to different photoperiods, as was proposed by the morning and evening oscillator model of Pittendrigh and Daan. We also show that this adaptation depends on retinal input but is independent of cryptochrome
Confined Chemical Fluid Deposition of Ferromagnetic Metalattices
A magnetic, metallic
inverse opal fabricated by infiltration into
a silica nanosphere template assembled from spheres with diameters
less than 100 nm is an archetypal example of a “metalattice”.
In traditional quantum confined structures such as dots, wires, and
thin films, the physical dynamics in the free dimensions is typically
largely decoupled from the behavior in the confining directions. In
a metalattice, the confined and extended degrees of freedom cannot
be separated. Modeling predicts that magnetic metalattices should
exhibit multiple topologically distinct magnetic phases separated
by sharp transitions in their hysteresis curves as their spatial dimensions
become comparable to and smaller than the magnetic exchange length,
potentially enabling an interesting class of “spin-engineered”
magnetic materials. The challenge to synthesizing magnetic inverse
opal metalattices from templates assembled from sub-100 nm spheres
is in infiltrating the nanoscale, tortuous voids between the nanospheres
void-free with a suitable magnetic material. Chemical fluid deposition
from supercritical carbon dioxide could be a viable approach to void-free
infiltration of magnetic metals in view of the ability of supercritical
fluids to penetrate small void spaces. However, we find that conventional
chemical fluid deposition of the magnetic late transition metal nickel
into sub-100 nm silica sphere templates in conventional macroscale
reactors produces a film on top of the template that appears to largely
block infiltration. Other deposition approaches also face difficulties
in void-free infiltration into such small nanoscale templates or require
conducting substrates that may interfere with properties measurements.
Here we report that introduction of “spatial confinement”
into the chemical fluid reactor allows for fabrication of nearly void-free
nickel metalattices by infiltration into templates with sphere sizes
from 14 to 100 nm. Magnetic measurements suggest that these nickel
metalattices behave as interconnected systems rather than as isolated
superparamagnetic systems coupled solely by dipolar interactions