Extraordinary coupled spin and chirality of electromagnetic guided waves

Optical spin and chirality play key roles in the interaction between light and chiral materials. The propagating guided modes by optical waveguides hardly produce optical chirality because of the broken symmetry between electric and magnetic components. Here for the first time we discover that the directional coupling of spatially guided modes can create polarization helicity, and thus generate optical spin and chirality. They are originated from the intrinsic phase retardation of {\pi}/2 between two directionally coupled spatial modes.We show that these near-field coupled spin and chirality manifests as odd-symmetric density distribution in the cross-section of symmetric waveguides, and especially this odd-symmetric distribution is intrinsically locked to coupling paths regardless of the propagation direction of light. Furthermore, such odd-symmetric chirality could produce a considerable chiral gradient force that can be used to separate chiral nanoparticles. These extraordinary electromagnetic properties may further prosper spin photonics and chiral light-matter interaction on nanophotonic platforms.Comment: 8 figure

Based on Cross-layer Adaptive Contention Window MAC Protocol for Middle and High Rate Sensor Networks

AbstractIn middle and high rate sensor network (MHWSN) usually contains a large quantity of self-organizing distributed nodes. It can be widely applied in emergency searching, disaster salvation and military applications etc. As middle and high rate sensor network node energy is limited, so energy efficient is the primary issue for Sensor network Medium Access Control (MAC) protocol design. BEB back-off algorithm cause more collision when node is in middle or high rate. A new back-off algorithm named ACW (Adaptive Contention Window) is proposed in this paper, which adjusts the CW based on the number of historical collision. In ACW, the adjustment of CW can properly reflect the state of medium contention, which results in improvements of throughput and reducement delay in MHWSN