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Your search keyword '"Kazazis, Dimitrios"' showing total 29 results
Start Over Author "Kazazis, Dimitrios" Publication Type Magazines
29 results on '"Kazazis, Dimitrios"'

1. Approaching Angstrom-Scale Resolution in Lithography Using Low-Molecular-Mass Resists (<500 Da)

Author

Saifullah, Mohammad S.M., Rajak, Anil Kumar, Hofhuis, Kevin A., Tiwale, Nikhil, Mahfoud, Zackaria, Testino, Andrea, Karadan, Prajith, Vockenhuber, Michaela, Kazazis, Dimitrios, Valiyaveettil, Suresh, and Ekinci, Yasin

Abstract

Resists that enable high-throughput and high-resolution patterning are essential in driving the semiconductor technology forward. The ultimate patterning performance of a resist in lithography is limited because of the trade-off between resolution, line-width roughness, and sensitivity; improving one or two of these parameters typically leads to a loss in the third. As the patterned feature sizes approach angstrom scale, the trade-off between these three metrics becomes increasingly hard to resolve and calls for a fundamental rethinking of the resist chemistry. Low-molecular-mass monodispersed metal-containing resists of high atom economy can provide not only very high resolution but also very low line-width roughness without sacrificing sensitivity. Here we describe a modular metal-containing resist platform (molecular mass <500 Da) where a molecular resist consists of just two components: a metal and a radical initiator bonded to it. This simple system not only is amenable to high-resolution electron beam lithography (EBL) and extreme ultraviolet lithography (EUVL) but also unites them mechanistically, giving a consolidated perspective of molecular and chemical processes happening during exposure. Irradiation of the resist leads to the production of secondary electrons that generate radicals in the initiator bonded to metal. This brings about an intramolecular rearrangement and causes solubility switch in the exposed resist. We demonstrate record 1.9–2.0 nm isolated patterns and 7 nm half-pitch dense line-space features over a large area using EBL. With EUVL, 12 nm half-pitch line-space features are shown at a dose of 68 mJ/cm2. In both of these patterning techniques, the line-width roughness was found to be ≤2 nm, a record low value for any resist platform, also leading to a low-performance trade-off metric, Zfactor, of 0.6 × 10–8mJ·nm3. With the ultimate resolution limited by instrumental factors, potential patterning at the level of a unit cell can be envisaged, making low-molecular-mass resists best poised for angstrom-scale lithography.

Published
2024
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23. The Extent of Platinum-Induced Hydrogen Spillover on Cerium Dioxide

Author

Beck, Arik, Kazazis, Dimitrios, Ekinci, Yasin, Li, Xiansheng, Müller Gubler, Elisabeth Agnes, Kleibert, Armin, Willinger, Marc-Georg, Artiglia, Luca, and van Bokhoven, Jeroen A.

Abstract

Hydrogen spillover from metal nanoparticles to oxides is an essential process in hydrogenation catalysis and other applications such as hydrogen storage. It is important to understand how far this process is reaching over the surface of the oxide. Here, we present a combination of advanced sample fabrication of a model system and in situ X-ray photoelectron spectroscopy to disentangle local and far-reaching effects of hydrogen spillover in a platinum–ceria catalyst. At low temperatures (25–100 °C and 1 mbar H2) surface O–H formed by hydrogen spillover on the whole ceria surface extending microns away from the platinum, leading to a reduction of Ce4+to Ce3+. This process and structures were strongly temperature dependent. At temperatures above 150 °C (at 1 mbar H2), O–H partially disappeared from the surface due to its decreasing thermodynamic stability. This resulted in a ceria reoxidation. Higher hydrogen pressures are likely to shift these transition temperatures upward due to the increasing chemical potential. The findings reveal that on a catalyst containing a structure capable to promote spillover, hydrogen can affect the whole catalyst surface and be involved in catalysis and restructuring.

Published
2022
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24. Charge Configuration Memory Devices: Energy Efficiency and Switching Speed

Author

Mraz, Anze, Venturini, Rok, Svetin, Damjan, Sever, Vitomir, Mihailovic, Ian Aleksander, Vaskivskyi, Igor, Ambrozic, Bojan, Dražić, Goran, D’Antuono, Maria, Stornaiuolo, Daniela, Tafuri, Francesco, Kazazis, Dimitrios, Ravnik, Jan, Ekinci, Yasin, and Mihailovic, Dragan

Abstract

Current trends in data processing have given impetus for an intense search of new concepts of memory devices with emphasis on efficiency, speed, and scalability. A promising new approach to memory storage is based on resistance switching between charge-ordered domain states in the layered dichalcogenide 1T-TaS2. Here we investigate the energy efficiency scaling of such charge configuration memory (CCM) devices as a function of device size and data write time τWas well as other parameters that have bearing on efficient device operation. We find that switching energy efficiency scales approximately linearly with both quantities over multiple decades, departing from linearity only when τWapproaches the ∼0.5 ps intrinsic switching limit. Compared to current state of the art memory devices, CCM devices are found to be much faster and significantly more energy efficient, demonstrated here with two-terminal switching using 2.2 fJ, 16 ps electrical pulses.

Published
2022
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