Identification of four detrimental chemicals using square-core photonic crystal fiber in the regime of THz

Numerous techniques and technologies have been proposed for the detection and identification of hazardous chemicals that can harm the lungs and respiratory system as well as the central nervous system and kidneys when inhaled. Most practical techniques can be carried out by extraordinary professionals in well-equipped facilities. A reliable, simple, highly sensitive, and feasible sensing technique is still required. A potential sensor for these harmful chemicals is the photonic crystal fiber (PCF), which achieves several unique properties. A square-core PCF sensor is proposed in this work for the detection of detrimental gases (tetra-chloro silane, tetra-chloro methane, turpentine, and tin terra-chloride) in the THz region. The cladding region is divided into three rings, and each ring has rectangular and square air holes. Within the operating region, we have found a relatively high sensitivity of 96.185% along with 95.407% core power fraction, 0.2211 numerical aperture, and a low effective area of 154 470 mu m(2) at 1.9 THz frequency. Ignorable confinement loss of 3.071 x 10(-14) cm(-1) and effective material loss of 0.007 72 cm(-1) have been also found. Additionally, the current manufacturing techniques guarantee the viability of the proposed PCF sensor's manufacture. These obtained results demonstrate that the proposed sensor can be effectively employed for applications involving hazardous chemical compounds, gases, and biosensing. Published under an exclusive license by AIP Publishing.

Automated summary

A photonic crystal fiber sensor is proposed for the detection of hazardous chemicals in the THz region, achieving high sensitivity and other unique properties. The results demonstrate the effectiveness of the sensor for applications involving hazardous chemical compounds, gases, and biosensing.