Your search keyword '"Dal Zilio, Simone"' showing total 6 results

1. Experimental Characterization of Separate Absorption–Multiplication GaAs Staircase Avalanche Photodiodes under Continuous Laser Light Reveals Periodic Oscillations at High Gains.

Author

Colja, Matija, Cautero, Marco, Arfelli, Fulvia, Bertolo, Michele, Biasiol, Giorgio, Dal Zilio, Simone, Driussi, Francesco, Menk, Ralf Hendrik, Modesti, Silvio, Palestri, Pierpaolo, Pilotto, Alessandro, and Cautero, Giuseppe

Subjects

AVALANCHE photodiodes, AUDITING standards, IMPACT ionization, OSCILLATIONS, GALLIUM arsenide

Abstract

In this work, we experimentally analyze the periodic oscillations that take place in staircase APDs with separate absorption and multiplication regions when operating under continuous laser light. These oscillations increase in frequency when the APD gain increases. We have verified that they are not affected by the parameters (gain and bandwidth) of the transimpedance amplifier, and thus originate inside the APD. The phenomenon is analyzed systematically by considering devices with different thicknesses of the absorption region. Possible physical interpretations related to the flux of holes generated by impact ionization are provided. [ABSTRACT FROM AUTHOR]

Published

2023

2. Water–Air Interface to Mimic In Vitro Tumoral Cell Migration in Complex Micro-Environments.

Author

Conti, Martina, Bolzan, Ilaria, Dal Zilio, Simone, Parisse, Pietro, Andolfi, Laura, and Lazzarino, Marco

Subjects

EXTRACELLULAR matrix, CELL migration, ENGINEERING mathematics, CANCER cells, CELL lines, BREAST cancer

Abstract

The long-known role of cell migration in physiological and pathological contexts still requires extensive research to be fully understood, mainly because of the intricate interaction between moving cells and their surroundings. While conventional assays fail to capture this complexity, recently developed 3D platforms better reproduce the cellular micro-environment, although often requiring expensive and time-consuming imaging approaches. To overcome these limitations, we developed a novel approach based on 2D micro-patterned substrates, compatible with conventional microscopy analysis and engineered to create micro-gaps with a length of 150 µm and a lateral size increasing from 2 to 8 µm, where a curved water–air interface is created on which cells can adhere, grow, and migrate. The resulting hydrophilic/hydrophobic interfaces, variable surface curvatures, spatial confinements, and size values mimic the complex micro-environment typical of the extracellular matrix in which aggressive cancer cells proliferate and migrate. The new approach was tested with two breast cancer cell lines with different invasive properties. We observed that invasive cells (MDA-MB-231) can align along the pattern and modify both their morphology and their migration rate according to the size of the water meniscus, while non-invasive cells (MCF-7) are only slightly respondent to the surrounding micro-environment. Moreover, the selected pattern highlighted a significative matrix deposition process connected to cell migration. Although requiring further optimizations, this approach represents a promising tool to investigate cell migration in complex environments. [ABSTRACT FROM AUTHOR]

Published

2022

3. Synchrotron Radiation Study of Gain, Noise, and Collection Efficiency of GaAs SAM-APDs with Staircase Structure.

Author

Colja, Matija, Cautero, Marco, Menk, Ralf Hendrik, Palestri, Pierpaolo, Gianoncelli, Alessandra, Antonelli, Matias, Biasiol, Giorgio, Dal Zilio, Simone, Steinhartova, Tereza, Nichetti, Camilla, Arfelli, Fulvia, De Angelis, Dario, Driussi, Francesco, Bonanni, Valentina, Pilotto, Alessandro, Gariani, Gianluca, Carrato, Sergio, and Cautero, Giuseppe

Subjects

AUDITING standards, MOLECULAR beam epitaxy, GALLIUM arsenide, SYNCHROTRON radiation, TIME-resolved spectroscopy, AVALANCHE photodiodes

Abstract

In hard X-ray applications that require high detection efficiency and short response times, such as synchrotron radiation-based Mössbauer absorption spectroscopy and time-resolved fluorescence or photon beam position monitoring, III–V-compound semiconductors, and dedicated alloys offer some advantages over the Si-based technologies traditionally used in solid-state photodetectors. Amongst them, gallium arsenide (GaAs) is one of the most valuable materials thanks to its unique characteristics. At the same time, implementing charge-multiplication mechanisms within the sensor may become of critical importance in cases where the photogenerated signal needs an intrinsic amplification before being acquired by the front-end electronics, such as in the case of a very weak photon flux or when single-photon detection is required. Some GaAs-based avalanche photodiodes (APDs) were grown by a molecular beam epitaxy to fulfill these needs; by means of band gap engineering, we realised devices with separate absorption and multiplication region(s) (SAM), the latter featuring a so-called staircase structure to reduce the multiplication noise. This work reports on the experimental characterisations of gain, noise, and charge collection efficiencies of three series of GaAs APDs featuring different thicknesses of the absorption regions. These devices have been developed to investigate the role of such thicknesses and the presence of traps or defects at the metal–semiconductor interfaces responsible for charge loss, in order to lay the groundwork for the future development of very thick GaAs devices (thicker than 100 μ m) for hard X-rays. Several measurements were carried out on such devices with both lasers and synchrotron light sources, inducing photon absorption with X-ray microbeams at variable and controlled depths. In this way, we verified both the role of the thickness of the absorption region in the collection efficiency and the possibility of using the APDs without reaching the punch-through voltage, thus preventing the noise induced by charge multiplication in the absorption region. These devices, with thicknesses suitable for soft X-ray detection, have also shown good characteristics in terms of internal amplification and reduction of multiplication noise, in line with numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2022

4. ZnO Thin Films Growth Optimization for Piezoelectric Application.

Author

Polewczyk, Vincent, Magrin Maffei, Riccardo, Vinai, Giovanni, Lo Cicero, Matteo, Prato, Stefano, Capaldo, Pietro, Dal Zilio, Simone, di Bona, Alessandro, Paolicelli, Guido, Mescola, Andrea, D'Addato, Sergio, Torelli, Piero, and Benedetti, Stefania

Subjects

THIN films, ZINC oxide, ZINC oxide films, LEAD zirconate titanate, THIN film devices, SURFACE roughness, ATOMIC force microscopy, SPUTTER deposition

Abstract

The piezoelectric response of ZnO thin films in heterostructure-based devices is strictly related to their structure and morphology. We optimize the fabrication of piezoelectric ZnO to reduce its surface roughness, improving the crystalline quality, taking into consideration the role of the metal electrode underneath. The role of thermal treatments, as well as sputtering gas composition, is investigated by means of atomic force microscopy and x-ray diffraction. The results show an optimal reduction in surface roughness and at the same time a good crystalline quality when 75% O2 is introduced in the sputtering gas and deposition is performed between room temperature and 573 K. Subsequent annealing at 773 K further improves the film quality. The introduction of Ti or Pt as bottom electrode maintains a good surface and crystalline quality. By means of piezoelectric force microscope, we prove a piezoelectric response of the film in accordance with the literature, in spite of the low ZnO thickness and the reduced grain size, with a unipolar orientation and homogenous displacement when deposited on Ti electrode. [ABSTRACT FROM AUTHOR]

Published

2021

5. Perspectives of Microscopy Methods for Morphology Characterisation of Extracellular Vesicles from Human Biofluids.

Author

Malenica, Mladenka, Vukomanović, Marija, Kurtjak, Mario, Masciotti, Valentina, dal Zilio, Simone, Greco, Silvio, Lazzarino, Marco, Krušić, Vedrana, Perčić, Marko, Jelovica Badovinac, Ivana, Wechtersbach, Karmen, Vidović, Ivona, Baričević, Vanja, Valić, Srećko, Lučin, Pero, Kojc, Nika, and Grabušić, Kristina

Subjects

EXTRACELLULAR vesicles, ATOMIC force microscopy, MICROSCOPY, ELECTRON microscopy

Abstract

Extracellular vesicles (EVs) are nanometric membranous structures secreted from almost every cell and present in biofluids. Because EV composition reflects the state of its parental tissue, EVs possess an enormous diagnostic/prognostic potential to reveal pathophysiological conditions. However, a prerequisite for such usage of EVs is their detailed characterisation, including visualisation which is mainly achieved by atomic force microscopy (AFM) and electron microscopy (EM). Here we summarise the EV preparation protocols for AFM and EM bringing out the main challenges in the imaging of EVs, both in their natural environment as biofluid constituents and in a saline solution after EV isolation. In addition, we discuss approaches for EV imaging and identify the potential benefits and disadvantages when different AFM and EM methods are applied, including numerous factors that influence the morphological characterisation, standardisation, or formation of artefacts. We also demonstrate the effects of some of these factors by using cerebrospinal fluid as an example of human biofluid with a simpler composition. Here presented comparison of approaches to EV imaging should help to estimate the current state in morphology research of EVs from human biofluids and to identify the most efficient pathways towards the standardisation of sample preparation and microscopy modes. [ABSTRACT FROM AUTHOR]

Published

2021

6. Nanostructured P3HT as a Promising Sensing Element for Real-Time, Dynamic Detection of Gaseous Acetone.

Author

Bertoni, Cristina, Naclerio, Pasquale, Viviani, Emanuele, Dal Zilio, Simone, Carrato, Sergio, and Fraleoni-Morgera, Alessandro

Subjects

ACETONE, NANOCOMPOSITE materials, GAS detectors, GAS flow, ENERGY consumption

Abstract

The dynamic response of gas sensors based on poly(3-hexylthiophene) (P3HT) nanofibers (NFs) to gaseous acetone was assessed using a setup based on flow-injection analysis, aimed at emulating actual breath exhalation. The setup was validated by using a commercially available sensor. The P3HT NFs sensors tested in dynamic flow conditions showed satisfactory reproducibility down to about 3.5 ppm acetone concentration, a linear response over a clinically relevant concentration range (3.5-35 ppm), excellent baseline recovery and reversibility upon repeated exposures to the analyte, short pulse rise and fall times (less than 1 s and about 2 s, respectively) and low power consumption (few nW), with no relevant response to water. Comparable responses' decay times under either nitrogen or dry air suggest that the mechanisms at work is mainly attributable to specific analyte-semiconducting polymer interactions. These results open the way to the use of P3HT NFs-based sensing elements for the realization of portable, real-time electronic noses for on-the-fly exhaled breath analysis. [ABSTRACT FROM AUTHOR]

Published

2019