Gold cone metasurface MIC sensor with monolayer of graphene and multilayer of graphite

This report makes a comparison between the spectrum features of plasmonic metamaterial metal-insulator-conductor (MIC) sensor with a monolayer of graphene and another MIC sensor with a multilayer of graphite as the back reflector. In both structures, the silicon substrate as an insulator layer was sandwiched between sub wave length periodic nanogold cones as the first layer and graphene and graphite as the third layer, respectively. Nanolayer of chromium nano rods was also considered in the structure of MIC sensors as an interface layer between silicon and nanogold cone metasurface. The performance of the sensor was evaluated under different incident polarized light angles and different thickness of the metasurface when the metasurface infiltrated with seawater and air. The transmission spectrum of monolayer graphene-based MIC sensor, respecting to s-polarized waves, reveals prominent feature to detect the air rather than seawater in invisible regime. Meanwhile, the reflection spectrum of graphite-based MIC sensor provides ∼0 % reflection under resonance condition regarding s- and p-polarized waves for detecting air in visible spectrum

Atomic force microscope base nanolithography for reproducible micro and nanofabrication

Atomic force microscopy nanolithography (AFM) is a strong fabrication method for micro and nano structure due to its high spatial resolution and positioning abilities. Mixing AFM nanolithography with advantage of silicon-on-insulator (SOI) technology provides the opportunity to achieve more reliable Si nanostructures. In this letter, we try to investigate the reproducibility of AFM base nanolithography for fabrication of the micro/nano structures. In this matter local anodic oxidation (LAO) procedure applied to pattern a silicon nanostructure on p-type (1015 cm-3) SOI using AFM base nanolithography. Then chemical etching is applied, as potassium hydroxide (saturated with isopropyl alcohol) and hydrofluoric etching for removing of Si and oxide layer, respectively. All parameters contributed in fabrication process were optimized and the final results revealed a good potential for using AFM base nanolithography in order to get a reproducible method of fabrication

Smart sensor controller for HVAC system

Nowadays, heat, ventilation and air conditioning system are an essential part in a building. In order to achieve energy saving, the heating, ventilation, and air conditioning (HVAC) system have to enhance the designs of their various types of integrated electrical and mechanical components so that to control and operate plant optimally. This paper presented the development of smart sensor controller for heat, ventilation and air conditioning system by using Arduino. Smart sensor controller can be regarded a device that can control the speed of the motor based on the number of person detected by the infrared sensor. The motor used in this project will represent the fan motor of the normal air conditioner. The objective of the smart sensor controller is to prove the energy saving concept and to reduce the electrical consumption for the HVAC system. The experiment conducted show that the implementation of the smart sensor controller provides an average energy saving efficiency of 45.13 % compare to HVAC system without smart sensor controller