«Our approach makes it possible to draw nanoscale electrically - conductive features in atomically - thin insulating sheets with
the highest spatial control reported so far,» said Mativetsky.
Not exact matches
Researchers at Tohoku University's Advanced Institute for Materials Research (AIMR) have carried out a collaborative study aimed at precisely
controlling phase transformations with
high spatial precision, which represents a significant step forward in realizing new functionalities in confined dimensions.
In particular, Brillouin optical correlation - domain reflectometry (BOCDR), which operates based on the correlation
control of continuous lightwaves, is known to be an intrinsically one - end - access distributed sensing technique with
high spatial resolution (< 1 cm).
Integration of MEMS devices with metalenses combine the strength of
high - speed dynamic
control with precise
spatial manipulation of wave - fronts.
However, relatively few studies have investigated whether there are differences in brain structure between these subgroups.We acquired diffusion tensor imaging data and used tract - based
spatial statistics (TBSS) to compare adolescents with CD and
high levels of CU traits (CD / CU +; n = 18, CD and low levels of CU traits (CD / CU -; n = 17) and healthy
controls (HC; n = 32) on measures of fractional anisotropy (FA), axial (AD), radial (RD) and mean (MD) diffusivity.