Publications by authors named "M A Asgar"

Micro/nano-precision glass molding (MNPGM) is an efficient approach for manufacturing micro/nanostructured glass components with intricate geometry and a high-quality optical finish. In MNPGM, the mold, which directly imprints the desired pattern on the glass substrate, is a key component. To date, a wide variety of mold inserts have been utilized in MNPGM.

View Article and Find Full Text PDF

A simple and cost-effective method is proposed herein for a plasmonic nanoantenna array (PNAA) for the fabrication of metal-enhanced fluorescence (MEF) substrates in which fluorophores interact with the enhanced electromagnetic field generated by a localized surface plasmon to provide a higher fluorescence signal. The PNAA is fabricated by the deposition of a silver (Ag) layer on an ultraviolet (UV) nanoimprinted nanodot array with a pitch of 400 nm, diameter of 200 nm, and height of 100 nm. During deposition, raised Ag nanodisks and a lower Ag layer are, respectively, formed on the top and bottom of the imprinted nanodot array, and the gap between these Ag layers acts as a plasmonic nanoantenna.

View Article and Find Full Text PDF
Article Synopsis
  • The study presents the first observation of two wobbling bands in ^{183}Au, both identified as transverse wobbling bands with distinct energy behaviors.
  • One band's wobbling energy increases with spin in the positive parity configuration, while the other decreases in the negative parity configuration.
  • Evidence for this wobbling nature was gathered through measurements of gamma-ray direction and polarization, with models accurately depicting the observed behavior, marking ^{183}Au as the only nucleus to show both increasing and decreasing wobbling energy.
View Article and Find Full Text PDF

Although polymer nanoimprinting on glass substrates has been widely employed for the fabrication of functional anti-reflective (AR) nanostructures, several drawbacks exist with respect to durability and delamination. The direct patterning of glass material is a potential solution for outdoor applications that require AR functional nanostructured glass plates. In this study, a glass imprinting technique was employed for the fabrication of an AR nanostructure on a soda-lime glass substrate using a vitreous carbon (VC) stamp.

View Article and Find Full Text PDF