Enhanced magneto-optical response with a 1D resonant grating for sensing applications

Graphene represents a new generation of materials which exhibit unique physicochemical properties such as high electron mobility, tunable optics, a large surface to volume ratio, and robust mechanical strength. These properties make graphene an ideal candidate for various optoelectronic, photonics, and sensing applications. In recent years, numerous efforts have been focused on azobenzene polymers (AZO-polymers) as photochromic molecular switches and thermal sensors because of their light-induced conformations and surface-relief structures. However, these polymers often exhibit drawbacks such as low photon storage lifetime and energy density. Additionally, AZO-polymers tend to aggregate even at moderate doping levels, which is detrimental to their optical response. These issues can be alleviated by incorporating graphene derivatives (GDs) into AZO-polymers to form orderly arranged molecules. GDs such as graphene oxide (GO), reduced graphene oxide (RGO), and graphene quantum dots (GQDs) can modulate the optical response, energy density, and photon storage capacity of these composites. Moreover, they have the potential to prevent aggregation and increase the mechanical strength of the azobenzene complexes. This review article summarizes and assesses literature on various strategies that may be used to incorporate GDs into azobenzene complexes. The review begins with a detailed analysis of structures and properties of GDs and azobenzene complexes. Then, important aspects of GD-azobenzene composites are discussed, including: (1) synthesis methods for GD-azobenzene composites, (2) structure and physicochemical properties of GD-azobenzene composites, (3) characterization techniques employed to analyze GD-azobenzene composites, and most importantly, (4) applications of these composites in various photonics and thermal devices. Finally, a conclusion and future scope are given to discuss remaining challenges facing GD-azobenzene composites in functional science engineering.

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Si1−xGex nanoantennas with a tailored Raman response and light-to-heat conversion for advanced sensing applications

Nanoscale ◽

10.1039/c9nr01837a ◽

2019 ◽

Vol 11 (24) ◽

pp. 11634-11641 ◽

Cited By ~ 8

Author(s):

E. Mitsai ◽

M. Naffouti ◽

T. David ◽

M. Abbarchi ◽

L. Hassayoun ◽

...

Keyword(s):

Optical Response ◽

Sensing Applications ◽

Raman Response

Incorporation of Ge into Si1−xGex nanoparticles allows modification of their light-to-heat conversion and optical response, which is crucial for biosensing applications.

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Porous silicon based resonant grating filters for biochemical sensing applications

10.1117/12.869703 ◽

2010 ◽

Author(s):

Xiaoyi Lv ◽

Jiaqing Mo ◽

Zhenhong Jia ◽

Mei Xiang ◽

Furu Zhong ◽

...

Keyword(s):

Porous Silicon ◽

Biochemical Sensing ◽

Sensing Applications ◽

Resonant Grating ◽

Silicon Based

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The geometric structure and optical response of gaseous endohedral magnesium-fullerenes

Journal of Modern Optics ◽

10.1080/0950034032000120731 ◽

2003 ◽

Vol 50 (15-17) ◽

pp. 2691-2704 ◽

Cited By ~ 1

Author(s):

M. Aichinger ◽

S. A. Chin ◽

E. Krotscheck ◽

H. A. Schuessler

Keyword(s):

Geometric Structure ◽

Optical Response

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Computer simulation study about the dependence of amorphous silicon photonic waveguides efficiency on the material quality

The European Physical Journal Applied Physics ◽

10.1051/epjap/2020190250 ◽

2020 ◽

Vol 90 (3) ◽

pp. 30502

Author(s):

Alessandro Fantoni ◽

João Costa ◽

Paulo Lourenço ◽

Manuela Vieira

Keyword(s):

Amorphous Silicon ◽

High Throughput Screening ◽

Simulation Analysis ◽

Low Cost ◽

Deposition Process ◽

Large Area ◽

Sidewall Roughness ◽

Sensing Applications ◽

Fabrication Defects ◽

The Impact

Amorphous silicon PECVD photonic integrated devices are promising candidates for low cost sensing applications. This manuscript reports a simulation analysis about the impact on the overall efficiency caused by the lithography imperfections in the deposition process. The tolerance to the fabrication defects of a photonic sensor based on surface plasmonic resonance is analysed. The simulations are performed with FDTD and BPM algorithms. The device is a plasmonic interferometer composed by an a-Si:H waveguide covered by a thin gold layer. The sensing analysis is performed by equally splitting the input light into two arms, allowing the sensor to be calibrated by its reference arm. Two different 1 × 2 power splitter configurations are presented: a directional coupler and a multimode interference splitter. The waveguide sidewall roughness is considered as the major negative effect caused by deposition imperfections. The simulation results show that plasmonic effects can be excited in the interferometric waveguide structure, allowing a sensing device with enough sensitivity to support the functioning of a bio sensor for high throughput screening. In addition, the good tolerance to the waveguide wall roughness, points out the PECVD deposition technique as reliable method for the overall sensor system to be produced in a low-cost system. The large area deposition of photonics structures, allowed by the PECVD method, can be explored to design a multiplexed system for analysis of multiple biomarkers to further increase the tolerance to fabrication defects.

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