M. ZOUACHE Tarek

MCA

Directory of teachers

Department

Departement of ELECTRONICS

Research Interests

Sensors, Opto-Mechanical Sensor, , Optoelectronic, Semiconductors Physics.

Contact Info

University of M'Sila, Algeria

Email : tarek.zouache@univ-msila.dz

On the Web:

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Recent Publications

2023-05-15

Indium Arsenide-Based High-Sensitivity Pressure Sensor with a 2D Photonic Crystal Waveguide Coupled to Two Microcavities

In this work, a hydrostatic pressure sensor based on two microcavities coupled to a photonic crystals
waveguide is presented. The pressure sensing part is formed by a double asymmetrical microcavities
made in the slab of the sensor, with the aim of creating a sharp resonant output spectral response.
These defects introduce a pressure detection mechanism based on the change of the Indium arsenide
semiconductor (InAs) slab refractive index when an applied pressure on his active surface changes and
this refractive index change leads a shift of the response resonant wavelength. The proposed structure
provides very distinguishing resonance peaks with good quality factor of 2103
for the considered
pressure range, and a pressure sensitivity reaching 26.1 nm/GPa. In addition, our proposed design
ensures an impeccable linear relationship between the resonance wavelength and the corresponding
applied pressure, which offer a highly selective pressure detection
Citation

M. ZOUACHE Tarek, (2023-05-15), "Indium Arsenide-Based High-Sensitivity Pressure Sensor with a 2D Photonic Crystal Waveguide Coupled to Two Microcavities", [international] First International Conference on Advances in Electrical and Computer Engineering 2023” (ICAECE'2023) , TEBESSA, ALGERIA

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2023-03-01

A 2D photonic crystal indium arsenide based with dual micro-cavities coupled to a waveguide as a platform for a high sensitivity pressure sensor

In the present work, we give a hydrostatic pressure sensor based on two micro-cavities coupled to a photonic crystals waveguide. A dual asymmetric H1 incorporing each one a point defect is introduced to create a sharp resonance output spectrum response of the structure. These defects make it able to detect the change of the Indium arsenide (InAs) substrate refractive index with the applied pressure changes. By applying a hydrostatic pressure on the active surface of the sensor, the refractive index of the InAs changes consequently. Therefore, this change induces a shift of the output resonant wavelength, which constitute the basis of the detection mechanism used by the photonic crystals pressure sensor. This proposed structure gives a high refractive index and pressure sensitivity reaching respectively 421 nm/RIU and 26.1 nm/GPa for a wide pressure range. Therefore, it provides very distinctive resonance peaks with good quality factors for all considered refractive index and a perfect linear relationship between the cutoff wavelength and the pressure, which offer a possibility of highly selective pressure detection.
Citation

M. ZOUACHE Tarek, (2023-03-01), "A 2D photonic crystal indium arsenide based with dual micro-cavities coupled to a waveguide as a platform for a high sensitivity pressure sensor", [international] Optical and Quantum Electronics , Springer

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2022-07-03

Capteur de micro-déplacement pour la mesure de très faibles déplacements avec une très haute précision.

Le capteur sujet de la présente invention se rapporte au domaine de mesure électronique de précision. Il entre dans le cadre des capteurs de mesure des pressions hydrostatiques appliquées à une surface donnée. Ce capteur miniature - facilement intégrable lui et son circuit électronique associé sur une même puce- trouve son intérêt dans différents domaine tel que, le contrôle des pression des gazes naturels, et synthétiques, le contrôle de pression de sang, etc.
Citation

M. ZOUACHE Tarek, (2022-07-03), "Capteur de micro-déplacement pour la mesure de très faibles déplacements avec une très haute précision.", [national] university of M'sila

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Micro-capteur optique de pression hydrostatique à haute sensibilité

Le capteur sujet de la présente invention se rapporte au domaine de mesure électronique de précision. Il entre dans le cadre des capteurs de mesure des pressions hydrostatiques appliquées à une surface donnée. Ce capteur miniature - facilement intégrable lui et son circuit électronique associé sur une même puce- trouve son intérêt dans différents domaine tel que, le contrôle des pression des gazes naturels, et synthétiques, le contrôle de pression de sang, etc.
Citation

M. ZOUACHE Tarek, (2022-07-03), "Micro-capteur optique de pression hydrostatique à haute sensibilité", [national] university of M'sila

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Un nouveau biocapteur plasmonique à base d’un guide d’onde MIM couplé à un résonateur de Fano pour la détection du cancer

La présente invention a pour objet de la proposition d’un nouveau biocapteur plasmonique miniature, non couteux et hautement sensible, à base d’un guide d’onde MIM couplé à un résonateur de Fano. Ce biocapteur permet de détecter les cellules cancéreuses (Besal, Hela , Jurkat, PC12, MDA-MB-231 et MCF-7) dans une solution biologique déposé sur surface du résonateur. Le mécanisme de détection repose sur la détection sans marquage, qui utilise l’indice de réfraction comme un élément de détection.
Citation

M. ZOUACHE Tarek, (2022-07-03), "Un nouveau biocapteur plasmonique à base d’un guide d’onde MIM couplé à un résonateur de Fano pour la détection du cancer", [national] university of M'sila

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2020-08-29

Mid-Infrared Micro-Displacement Measurement with a Bidimensional Silicon Photonic Crystal

In this work, a micro displacement sensor based on a dual micro cavity coupled to a photonic crystal waveguide is proposed. The defects are introduced to create a sharp resonance in the structure which makes it useful for detecting micro displacement changes. The sensing principle is based on the change of the output signal transmission with the change of the displacement of a moving part compared to a fixed part of sensor structure. The proposed structure reached a good sensitivity of 6,13a-1 and also exhibit a good linearity against wide range of displacement.
Citation

M. ZOUACHE Tarek, (2020-08-29), "Mid-Infrared Micro-Displacement Measurement with a Bidimensional Silicon Photonic Crystal", [national] Progress In Electromagnetics Research Letters , PIER Letters

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2020-05-17

Micro displacement measurement using dual micro cavity two dimensional silicon photonic crystal

In this work, a micro displacement sensor based on a dual micro cavity coupled to a photonic crystal waveguide is proposed. The defects are introduced to create a sharp resonance in the structure which makes it useful for detecting micro displacement changes. The sensing principle is based on the change of the output signal transmission with the change of the displacement of a moving part compared to a fixed part of sensor structure. The proposed structure reached a good sensitivity of 6,13a-1 and also exhibit a good linearity against wide range of displacement.
Citation

M. ZOUACHE Tarek, (2020-05-17), "Micro displacement measurement using dual micro cavity two dimensional silicon photonic crystal", [international] 2020 1st International Conference on Communications, Control Systems and Signal Processing (CCSSP) , El Oued, Algeria

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2018-06-27

Cavity-coupled photonic crystal waveguide as highly sensitive platform for pressure sensing

In this paper, a pressure sensing platform based on cavity-coupled photonic crystal waveguide is
proposed for hydrostatic pressure sensing. A label-free waveguide-cavity coupled with high-Q, is
designed and analyzed to exhibit high sensitivity against wide range of pressures. The introduction
of a cavity in the structure leads to a sharp resonance which makes it useful for
detection of pressure change. It is observed through 2-D Finite Difference Time Domain (FDTD)
method that the resonant wavelength of sensor is shifted by increasing the refractive index (RI)
that is imposed by the hydrostatic pressure presence. The reported sensitivity and quality factor
of the proposed platform are acceptable for wide range of pressures. The proposed design also
demonstrates separated resonant peaks for different index (RI) and a good linear relation between
the cutoff wavelength and the pressure, which allow high selective label-free pressure
detection.
Citation

M. ZOUACHE Tarek, (2018-06-27), "Cavity-coupled photonic crystal waveguide as highly sensitive platform for pressure sensing", [national] Optik - International Journal for Light and Electron Optics , ELSEVIER

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2018-06-07

A High Sensitivity Pressure Sensor using Two Dimensional Photonic Crystal Cavity

In this work, ahydrostatic pressure sensor based on a cavity coupled to a photonic crystal waveguide is proposed. A defect is introducedto createa sharp resonance in the structure which makes it useful for detecting pressure changes. The sensing principle is based on the shift of the resonant wavelength with the change refractive index which arises due to the hydrostatic pressure effect. The proposed structure gives a high sensitivity against wide range of pressures and a good quality factor near 3GPa is achieved. Conclusion: The proposed design also shows separated resonant peaks for different indicesand a perfect linear relation between the cutoff wavelength and the pressure which offer a possibility of highly selective pressure detection.
Citation

M. ZOUACHE Tarek, (2018-06-07), "A High Sensitivity Pressure Sensor using Two Dimensional Photonic Crystal Cavity", [national] International Journal of Sensors Wireless Communications and Control , Bentham Science Publishers

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2017

Design of pressure sensor based on two-dimensional photonic crystal

In this work, we design a new pressure sensor based on two-dimensional photonic crystal waveguide coupled
to a point-defect resonant microcavity. The mechanism of sensing is based on the change of the germanium
refractive index as function of the hydrostatic pressure P. The resonant wavelength will shift when pressure
variation induces change in the refractive indexes of the structure. The pressure variation causes the shifting of
defect modes. The properties of the refractive index sensor are simulated using the finite-difference time-domain
algorithm and the plane wave expansion method. These kinds of sensors have many advantages in compactness,
high sensitivity, and various choices of materials.
Citation

M. ZOUACHE Tarek, riad Mokhtari, , (2017), "Design of pressure sensor based on two-dimensional photonic crystal", [national] Acta Physica Polonica A , Institute of Physics, Polish Academy of Science

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