14 Dicembre 2020 admin

Projects for Master Degree

MASTER THESIS PROJECTS AVAILABLE AT LABORATORY POLYSENSE IN 2025

PolySense Labs offer several Master Thesis Projects within the research topics:

  • Quartz-Enhanced Photoacoustic Spectroscopy

  • Multi-pass Absorption Spectroscopy

  • Tunable Diode Laser Spectroscopy

  • Optical Gas Sensing

  • Infrared Detection with Quartz Tuning Fork

  • Photonic Integrated Devices

  • Mid-Infrared Spectroscopy for Biological Samples Analysis

The projects are classified in three types:

  • The Experimental Master’s thesis option requires that the student complete an original research project in the laboratory. This includes the realization of an experimental setup, measurements and data analysis. The students will work with sophisticated laboratory instruments and facilities.
  • A Theoretical Master’s thesis option comes with a focus on a theoretical subject. The empirical study is taken as the topic for the master’s program. The student is required to discuss unresolved aspects with numerical simulations as well to develop novel models.
  • The hybrid Theoretical/Experimental Master’s thesis proposes a good overlap between theory and experiment. It includes numerical simulations supported by an experimental investigation. The experimental part is expected to validate the theoretical model and to gather data for modifying them.

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MASTER THESIS PROJECT 1

Title: Study of impact of high temperature on resonance properties of a quartz tuning fork

Type of Thesis: Theoretical/Experimental

Description: Quartz Tuning Fork (QTF) is largely used in Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS) as sound detector of weak pressure waves generated by gas molecules when they absorb resonant, intensity-modulated light. The performance of a QEPAS sensor are stricly related to the resonance properties of the QTF, requiring a precise control of the temperature and pressure of the gas flowing in the cell where the QTF is immersed. For some applications,  the temperature of the gas mixture can be significantly above the room temperature and its impact on the QTF properties can alter the detection sensitivity. The project aims at studying the temperature dependence of the resonance frequency, the resonance width and the electrical resistance of a QTF when it is immersed directly in a slow gas flow rate – less than 100 sccm – from room temperature up to 200 °C. A theoretical/phenomenological modeling as well as a systematic experimental characterization of the mechanical and electrical properties of the QTF will be conducted.

Referents: Marilena Giglio/Arianna Elefante

Status: AVAILABLE

MASTER THESIS PROJECT 2

Title: Realization of a Quartz-Enhanced Photoacoustic Sensor for detection of carbon monoxide impurities in hydrogen

Type of Thesis: Experimental

Description: Hydrogen energy, as a pollution-free and efficient energy source, is gradually receiving widespread attention. In this context, fuel cells, as a type of hydrogen energy cell, have significant prospects for development. Currently, most hydrogen energy for fuel cells mainly comes from hydrocarbons reforming, which uses catalytic reactions to convert hydrocarbons into hydrogen. In the process of reforming hydrogen, there are inevitably the production of impurities, such as CO, NH3, H2S, etc. and any impurities present in hydrogen gas itself may result in substantial degradation of fuel cells. Indeed, the presence of these impurities can cause damage even when they are present at concentration levels of part-per-billion (ppb). This project aims at the realization of a trace gas sensor based on Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS) for ultrasensitive and selective detection of carbon monoxide impurities in a hydrogen matrix. The QEPAS sensor will be calibrated with certified mixtures in laboratory environment, in order to assess the sensitivity, the ultimate detection limit and the long-term mechanical stabililty.

Referents: Andrea Zifarelli/Pietro Patimisco

Status: ASSIGNED to Enrico SALLUSTIO

MASTER THESIS PROJECT 3

Title: Quartz-Enhanced Photoacoustic Spectroscopy for Sulfur Dioxide Monitoring for volcanoes surveillance

Type of Thesis: Experimental

Description: Volcanic gas analysis provides crucial insights into subsurface magmatic and hydrothermal processes, supporting hazard assessment during unrest phases. Besides the predominant emissions of H₂O and CO₂, sulfur compounds—particularly hydrogen sulfide (H₂S) and sulfur dioxide (SO₂)—are key indicators due to their atmospheric and climatic relevance. To achieve reliable and continuous monitoring under the challenging conditions typical of volcanic environments, compact and robust sensors are required, capable to guarantee high selectivity and sensitivity with detection limits below part-per-million (ppm) range in the complex and variable volcanic plume.
This project aims at the realization of a Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS) sensor for ultrasensitive and selective detection of SO2. The QEPAS sensor will be calibrated with certified mixtures in laboratory environment, in order to assess the sensitivity, the ultimate detection limit and the long-term mechanical stability. The sensor will be fully configured for field deployment, enabling continuous, real-time measurements at the Pisciarelli fumarolic field (Campi Flegrei caldera, southern Italy), in conjunction with an H₂S QEPAS sensor previously tested in a measurement campaign. This combined approach aims to enhance multi-gas monitoring capabilities for improved understanding and surveillance of volcanic emissions.

Referents: Arianna Elefante/Pietro Patimisco

Status: ASSIGNED to Aurora SISTO

MASTER THESIS PROJECT 4

Title: Quartz-enhanced photoacoustic sensor with wide dynamic range operation from percent to part-per-billion

Type of Thesis: Experimental

Description: Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS) is indirect absorption technique where the photo-induced acoustic wave generated in an absorbing medium is detected by a spectrophone, composed by a quartz tuning fork (QTF) and a pair of millimeter-size resonator tubes located on both sides of QTF. The two tubes act as acoustic resonator and amplify the sound wave nearby the QTF. It can be shown that the acoustic wave intensity is proportional to the gas concentration and thus a wide dynamic linear range can be supposed. In practice, the optimization of QEPAS spectrophone for low concentrations detection makes it inevitably unusable for high concentrations, primarily for non-linearity and signal saturation effects. This project aims to design and realize an innovative QEPAS module composed by a bare QTF, for high concentration measurements, and a spectrophone, for low concentrations. Both two QTFs and tubes must be aligned along the same optical axis in order to allow laser beam to pass through without touching any of them.  The QEPAS module will be tested with an absorbing gas varying its concentration from percent to part-per-billion range.

Referents: Angelo Sampaolo/Pietro Patimisco

Status: AVAILABLE

MASTER THESIS PROJECT 5

Title: Broadband spectroscopy with supercontinuum laser source and an optical spectrum analyzer: a comparison with a Fourier transform spectrometer

Type of Thesis: Experimental

Description: Infrared spectroscopy for gas sensing has developed strongly during the last two decades, driven by new infrared sources and new measurement concepts. In this context, ultra-broadband spectroscopy in the mid-infrared wavelength range, where most molecular species have strong, distinct absorption features, has a great potential for gas sensing applications. Nevertheless, limitations remain for fast broadband spectroscopy, especially in multispecies detection in the gas phase. This project aims at comparing two distinct approaches for broadband operation required for multi-species detection. The first exploits a scanning Fourier transform spectrometer, where interferograms are collected by measurements of the coherence of the light in the time-domain, and translated into frequency domain through Fourier transform. The other one combines a broadband, spatially coherent supercontinuum mid-infrared source with an optical spectrum analyzer. For both approaches, the sensitivity will be enhanced by using a Herriott-type multipass cell with 31.2 m optical path.

Referents: Andrea Zifarelli/Pietro Patimisco

Status: AVAILABLE

MASTER THESIS PROJECT 6

Title: Beat-frequency Quartz-Enhanced Photoacoustic Spectroscopy for fast multi-gas detection

Type of Thesis: Experimental

Description: The potentiality to acquire data in wide and harsh environments and to guarantee the safety of the operator promotes Unmanned Aerial Vehicle (UAV)-assisted monitoring as one of the most suitable solutions for multi-gas detection in urban and industrial areas. Moreover, a sensing system to be mounted on UAVs should be reliable and fast at the same time. Among different optical sensing techniques, Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS) demonstrated to be suitable and reliable to monitor multiple gas species. In QEPAS, the signal of the gas under investigation is acquired during a slow spectral scan of the laser tuning range across the gas absorption feature. This process requires several minutes, preventing the real-time monitoring of the QTF resonance parameters, necessary to validate measurements. This project aims at investigating a novel approach, named Beat-Frequency QEPAS (BF-QEPAS), to simultaneously speed up and validate data acquisitions. In BF-QEPAS, the laser modulation frequency (f) will be detuned of Δf with respect to the QTF resonance frequency, and a fast ramp will be applied to scan the laser tuning range so that the QTF results excited by a fast acoustic pulse.

Referent: Giansergio Menduni

Status: AVAILABLE

MASTER THESIS PROJECT 7

Title: Study and design of photonic integrated structures for optical gas sensors

Type of Thesis: Theoretical

Description: Mid-infrared (mid-IR) absorption spectroscopy based on Photonic Integrated Circuits (PICs) has shown great promise in trace-gas sensing applications where the mid-IR radiation directly interacts with the targeted analyte. Furthermore, the possibility to integrate laser sources, waveguides and optical detectors on the same platform could allow the realization of a fully integrated spectroscopic setup for gas sensing. Waveguide represents one of the core elements on a photonic integrated circuit: the propagation losses and the overlap factors are the main parameters affecting the performance of integrated sensors. This project aims at simulating and designing different waveguide structures for integrated gas sensors (e.g., slot waveguides, subwavelength waveguides, pedestal waveguides) and studying the influence of critical parameters on the ultimate performance of the PIC.

Referent: Angelo Sampaolo/ Giansergio Menduni

Status: AVAILABLE

MASTER THESIS PROJECT 8

Title: Trace gas detector based on Lithium niobate resonators

Type of Thesis: Theoretical/Experimental

Description: In the last couple of decades, lithium niobate (LiN) has arisen as a promising piezoelectric material in the integrated photonics field for the realization of transducers. Lithium niobate tuning forks (LiNTF) have been employed as viscosimeters or, very recently, as sound wave detector for gas sensing in Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS). The same type of resonator could be implemented as infrared photodetector in Light-Induced Thermoelastic Spectroscopy (LITES). This project aims at studying the performance and the resonance properties of LiNTFs, when employed as sound detector and photodetector in QEPAS and LITES technique, respectively, and in the realization of a gas chamber where the LiNTF can be employed for trace gas sensing.

Referent: Angelo Sampaolo/ Giansergio Menduni

Status: AVAILABLE

MASTER THESIS PROJECT 9

Title: Study of the Signal-to-Noise Ratio trend in Quartz Tuning Fork-based gas sensors at different working conditions

Type of Thesis: Theoretical/Experimental

Description: Quartz Tuning Forks (QTF) have been widely employed in the last years as sound wave detector in Quartz-Enhanced Photoacoustic Spectroscopy (QEPAS), and as photodetector in Light-Induced Thermoelastic Spectroscopy (LITES). In both techniques, the signal depends on the pressure of the gas chamber. Furthermore, the ultimate noise level is determined by the QTF thermal noise, depending on the quality factor of the resonator, and in turn on the working pressure. This project aims at modeling different noise contributions affecting both techniques and at defining the working pressure that optimizes the Signal-to-Noise ratio (SNR), both in QEPAS and LITES technique. A QEPAS and LITES sensor will be realize to assess and validate the theoretical model.

Referent: Pietro Patimisco/ Giansergio Menduni

Status: AVAILABLE

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THESIS PROJECTS COMPLETED AT LABORATORY POLYSENSE

Campus Universitario "Ernesto Quagliariello" Via G. Amendola 173 - 70126 Bari
polysense@poliba.it vincenzoluigi.spagnolo@poliba.it
080/5442373
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