TY - GEN
T1 - Novel Spin-decoupled Holographic Meta-displays
AU - Javed, Isma
AU - Naveed, Muhammad Ashar
AU - Zubair, Muhammad
AU - Goyal, Amit Kumar
AU - Mehmood, Muhammad Qasim
AU - Massoud, Yehia
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - Many modern applications like entertainment displays, data encryption, security, and virtual reality (VR) technology require asymmetric light manipulation. Symmetric spin-orbit interactions (SOI) apply a limit in achieving an asymmetrical metahologram. However, different reported asymmetric SOI's based on propagation and geometric phase mergence techniques effectively break this limit at the expense of design complexity and greater computation cost. This work proposes a novel helicity multiplexing technique that breaks all the aforementioned barriers in achieving on-axis dual side holograms. Benefiting from the geometric phase modulation of anisotropic nano-resonating antennas, we have employed a single unit cell to achieve helicity multiplexing. A low extinction coefficient material a-Si:H is used for device analysis. Due to the simple single unit cell-based designing technique, simulation and fabrication complexities were significantly reduced. As a result, based on the helicity and incidence direction of electromagnetic wave, we have achieved highly transmissive dual holographic images in the visible band. Our simulated efficiencies are 55%, 75%, and 80% for the blue boldsymbol(\lambda=488 nm), green boldsymbol(\lambda=532 nm), and red light boldsymbol(\lambda=633 nm).
AB - Many modern applications like entertainment displays, data encryption, security, and virtual reality (VR) technology require asymmetric light manipulation. Symmetric spin-orbit interactions (SOI) apply a limit in achieving an asymmetrical metahologram. However, different reported asymmetric SOI's based on propagation and geometric phase mergence techniques effectively break this limit at the expense of design complexity and greater computation cost. This work proposes a novel helicity multiplexing technique that breaks all the aforementioned barriers in achieving on-axis dual side holograms. Benefiting from the geometric phase modulation of anisotropic nano-resonating antennas, we have employed a single unit cell to achieve helicity multiplexing. A low extinction coefficient material a-Si:H is used for device analysis. Due to the simple single unit cell-based designing technique, simulation and fabrication complexities were significantly reduced. As a result, based on the helicity and incidence direction of electromagnetic wave, we have achieved highly transmissive dual holographic images in the visible band. Our simulated efficiencies are 55%, 75%, and 80% for the blue boldsymbol(\lambda=488 nm), green boldsymbol(\lambda=532 nm), and red light boldsymbol(\lambda=633 nm).
UR - https://www.scopus.com/pages/publications/85142928134
UR - https://www.scopus.com/pages/publications/85142928134#tab=citedBy
U2 - 10.1109/NANO54668.2022.9928775
DO - 10.1109/NANO54668.2022.9928775
M3 - Conference contribution
AN - SCOPUS:85142928134
T3 - Proceedings of the IEEE Conference on Nanotechnology
SP - 198
EP - 201
BT - 2022 IEEE 22nd International Conference on Nanotechnology, NANO 2022
PB - IEEE Computer Society
T2 - 22nd IEEE International Conference on Nanotechnology, NANO 2022
Y2 - 4 July 2022 through 8 July 2022
ER -