Your search keyword '"Kamil Ber"' showing total 7 results

1. The detector control unit of the fine guidance sensor instrument on-board the ARIEL mission: design status

Author

Vladimiro Noce, Mauro Focardi, Marina Vela Nunez, Luca Naponiello, Andrea Lorenzani, Raoul Grimoldi, Elio Mangraviti, Luca Carli, Kamil Ber, Miroslaw Rataj, Konrad Rutkowski, Konrad R. Skup, Przemyslaw Nita, Giuseppina Micela, Giuseppe Malaguti, Natalia Auricchio, Emanuele Pace, Giampaolo Preti, Enzo Pascale, Giovanna Tinetti, Paul Eccleston, Elisabetta Tommasi, Mario Salatti, Raffaele Piazzolla, Pietro Bolli, Renzo Nesti, Marcella Iuzzolino, Luca Carbonaro, Ciro Del Vecchio, Debora Ferruzzi, Federico Miceli, Anna Brucalassi, Gilberto Falcini, Andrea Tozzi, and Daniele Gottini

Published

2022

2. ARIEL fine guidance system: design, challenges, and opportunities

Author

Konrad R. Skup, Mirosław Rataj, Piotr Wawer, Mateusz Sobiecki, Kamil Ber, Konrad Rutkowski, Grzegorz Szymanski, Radoslaw Trzepalka, Roland Ottensamer, Gerald Mösenlechner, Armin Luntzer, Hyung Cho, Edmundo Guzman, Warren A. Holmes, Ronald C. Kruid, Renaud Goullioud, Jerry Mulder, Perry G. Ramsey, Albert J. Rieck, Allan J. Runkle, Mark R. Swain, Gautam Visisht, Carissa T. Weber, Roger Foltz, Tilak Hewagama, Mauro Focardi, and Raoul Grimoldi

Published

2022

3. Comprehensive Study of Kinetics of Processes Competing during PECVD Ultrathin Silicon Layer High-Temperature Annealing

Author

Romuald B. Beck and Kamil Ber

Subjects

010302 applied physics, Amorphous silicon, Fabrication, Materials science, Article Subject, Silicon, Annealing (metallurgy), Nanophotonics, Recrystallization (metallurgy), chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Engineering physics, Amorphous solid, chemistry.chemical_compound, chemistry, Plasma-enhanced chemical vapor deposition, lcsh:Technology (General), 0103 physical sciences, lcsh:T1-995, General Materials Science, 0210 nano-technology

Abstract

Application of low-temperature PECVD is a very tempting option for formation of ultrathin silicon layers for nanoelectronic and nanophotonic applications, as followed by annealing of this layer, regardless if executed as individual process performed in controlled ambient or during following high-temperature processes, allows for phase and content changes in the silicon layer. Understanding complex changes that can take place during such process, which depend on its temperature, conditions (e.g., oxygen availability), and timeframe, is a fundamental requirement for conscious application of such technology. It is worth realizing that nanodevices with their unprecedented variety of structures and devices require many different fabrication technologies. Hence, depending on the application in mind, different results of ultrathin silicon layer annealing may appear advantageous. During high-temperature processing (e.g., annealing) of PECVD ultrathin silicon layer, three competing effects have to be taken into account. These are amorphous silicon recrystallization and oxidation of amorphous and crystalline (as-deposited or just recrystallized from as-deposited amorphous phase) silicon (both of which by nature exhibit different kinetics). So far, most of attention has been paid to silicon recrystallization, which was justified by the fact that under experimental conditions studied (silicon multilayers) oxidation was certainly of less importance. In certain applications, the required device structure consists of single (and not multiple) ultrathin silicon layer, and thus, oxidation effects certainly have to be included into considerations. Understanding dynamics and very complex relations between these individual effects is thus mandatory for using consciously this technique and achieving needed properties of the layer. It has to be stated clearly that although the achieved results, presented in this study, refer to the silicon layers fabricated under certain conditions (particular type of PECVD reactor and process parameters), they can, however, be easily extrapolated for similar cases too. The presented below results are, to our knowledge, the first successful attempt to address these issues.

Published

2019

4. STIX IDPU: very efficient and reliable controller for a scientific instrument

Author

Oliver Grimm, Säm Krucker, Kamil Ber, Stefan Koegl, Waldemar Bujwan, Konrad Skup, Marek Winkler, Andrzej Cichocki, Marcin Darmetko, M. Michalska, and Grzegorz Juchnikowski

Subjects

Scientific instrument, Control theory, Computer science, Control engineering

Published

2019

5. Recrystallization and oxidation - competing processes during PECVD ultrathin silicon layer high temperature annealing

Author

Romuald B. Beck and Kamil Ber

Subjects

010302 applied physics, Thermal oxidation, Amorphous silicon, Materials science, Silicon, business.industry, Annealing (metallurgy), Metallurgy, Nanocrystalline silicon, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Monocrystalline silicon, chemistry.chemical_compound, chemistry, 0103 physical sciences, Optoelectronics, Crystalline silicon, LOCOS, 0210 nano-technology, business

Abstract

In this work we have studied relations between three competing effects that take place during high temperature annealing of PECVD ultrathin silicon layer, namely: amorphous silicon recrystallization, amorphous silicon oxidation and oxidation of just received crystalline silicon in the first few minutes of this process. Understanding very complex relations between these kinetics is essential to allow for conscious manipulating of annealing and/or oxidation parameters in order to achieve different results, depending on the application in mind. The presented below results are, to our knowledge, the first attempt to address these issues.

Published

2016

6. Deliberation and polarization: a multi-disciplinary review

Author

Didier Caluwaerts, Kamil Bernaerts, Rebekka Kesberg, Lien Smets, and Bram Spruyt

Subjects

deliberative democracy, polarization, affective polarization, democracy, systematic review, Political science

Abstract

In recent years, deliberative democracy has drawn attention as a potential way of fighting polarization. Allowing citizens to exchange arguments and viewpoints on political issues in group, can have strong conflict-mitigating effects: it can foster opinion changes (thereby overcoming idea-based polarization), and improve relations between diametrically opposed groups (thereby tackling affective forms of polarization, such as affective polarization). However, these results conflict with social psychological and communication studies which find that communicative encounters between groups can lead to further polarization and even group think. The question therefore arises under which conditions deliberative interactions between citizens can decrease polarization. Based on a multidisciplinary systematic review of the literature, which includes a wide diversity of communicative encounters ranging from short classroom discussions to multi-weekend citizen assemblies, this paper reports several findings. First, we argue that the effects of communicative encounters on polarization are conditional on how those types of communication were conceptualized across disciplines. More precisely, we find depolarizing effects when group discussions adhere to a deliberative democracy framework, and polarizing effects when they do not. Second we find that the depolarizing effects depend on several design factors that are often implemented in deliberative democracy studies. Finally, our analysis shows that that much more work needs to be done to unravel and test the exact causal mechanism(s) underlying the polarization-reducing effects of deliberation. Many potential causal mechanisms were identified, but few studies were able to adjudicate how deliberation affects polarization.

Published

2023

7. Formation of ultrathin silicon layers by PECVD and their modification for nanoelectronic and nanophotonic applications

Author

Kamil Ber and Romuald B. Beck

Subjects

Materials science, Silicon, chemistry, Annealing (metallurgy), Hybrid silicon laser, Plasma-enhanced chemical vapor deposition, Nanocrystalline silicon, chemistry.chemical_element, Nanotechnology, Strained silicon, Dielectric, Nanocrystalline material

Abstract

Nanoelectronic and nanophotonic applications have created a pressure on methods of fabrication double dielectric barriers stacks with ultrathin silicon layer located between dielectric layers. Among numerous possible methods, PECVD seems to be very promising. In order to increase possible number of applications, however, the ability to transform continuous silicon layer into nanocrystalline form in dielectric matrix is required. The work described below reports on experimental efforts to form such a structure by controlled high temperature recrystallization and oxidation of ultrathin PECVD silicon layer in the stack. The effects if high temperature annealing has been studied by spectroscopic ellipsometry. The applied model allowed for identification of composition and structural changes within the silicon PECVD layer due to different high temperature annealing processes applied. As a result of this study, it has been proved that it is feasible to fabricate complete two barrier stack consisting of ultrathin dielectric and silicon layers in one PECVD system without exposing samples to the ambient atmosphere. In order to reduce the PECVD silicon layer thickness to approximately 3 nm, we proposed using plasma oxidation in PECVD instead of PECVD oxide deposition. High temperature (especially in 1100°C) annealing in argon proved to allow formation of silicon nanocrystals in oxide matrix. Other effects resulting from high temperature annealing of fabricated stacks are also studied.

Published

2013