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128 results on '"Oprins, Herman"'

1. Selecting Alternative Metals for Advanced Interconnects

Author

Soulié, Jean-Philippe, Sankaran, Kiroubanand, Van Troeye, Benoit, Leśniewska, Alicja, Pedreira, Olalla Varela, Oprins, Herman, Delie, Gilles, Fleischmann, Claudia, Boakes, Lizzie, Rolin, Cédric, Ragnarsson, Lars-Åke, Croes, Kristof, Park, Seongho, Swerts, Johan, Pourtois, Geoffrey, Tőkei, Zsolt, and Adelmann, Christoph

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Interconnect resistance and reliability have emerged as critical factors limiting the performance of advanced CMOS circuits. With the slowdown of transistor scaling, interconnect scaling has become the primary driver of continued circuit miniaturization. The associated scaling challenges for interconnects are expected to further intensify in future CMOS technology nodes. As interconnect dimensions approach the 10 nm scale, the limitations of conventional Cu dual-damascene metallization are becoming increasingly difficult to overcome, spurring over a decade of focused research into alternative metallization schemes. The selection of alternative metals is a highly complex process, requiring consideration of multiple criteria, including resistivity at reduced dimensions, reliability, thermal performance, process technology readiness, and sustainability. This tutorial introduces the fundamental criteria for benchmarking and selecting alternative metals and reviews the current state of the art in this field. It covers materials nearing adoption in high-volume manufacturing, materials currently under active research, and potential future directions for fundamental study. While early alternatives to Cu metallization have recently been introduced in commercial CMOS devices, the search for the optimal interconnect metal remains ongoing., Comment: 74 pages, 27 figures, 5 Tables

Published
2024

4. Multidie 3-D Stacking of Memory Dominated Neuromorphic Architectures

Author

Giacomini Rocha, Leandro M., Bilgic, Refik, Naeim, Mohamed, Das, Sudipta, Oprins, Herman, Yousefzadeh, Amirreza, Konijnenburg, Mario, Milojevic, Dragomir, Myers, James, Ryckaert, Julien, and Biswas, Dwaipayan

Abstract

Event-driven neuromorphic processors for artificial intelligence (AI) inference on edge/IoT devices require largeon-chip memory capacity, for efficient execution of spiking neural networks (NNs). In this work, we evaluate 3-D stacking benefits on SENECA, a digital neuromorphic accelerator core, sweeping itson-chip memory capacity from 2 up to 32 Mb in both legacy planar and advanced nanosheet CMOS logic nodes. In a planar CMOS node (GF-22 nm), two-die memory-on-logic (MoL) partitioning enables $8\times $ moreon-chip memory, and it boosts operating frequency by 7% with 26% less power than the 2-D. Moving to an advanced nanosheet technology (imec A10), multidie (up to 7 dies) MoL stacking enables a performance increase of up to 29% and power savings up to 31%. Furthermore, a core folding (CF) partitioning in A10 shows up to 16% performance improvement with 12% total power savings with respect to the 2-D implementation on the same technology. We also demonstrate no thermal overhead for multidie stacking at advanced nodes for designs exhibiting low power density. These physical design explorations lay the foundation for system technology co-optimization studies for edge devices.

Published
2024
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5. A Critical Analysis of the Thermo-Optic Time Constant in Si Photonic Devices.

Author

Coenen, David, Kim, Minkyu, Oprins, Herman, Van Campenhout, Joris, and De Wolf, Ingrid

Subjects
TEMPERATURE control, CRITICAL analysis, HEATING, PHOTONICS, AMBIGUITY
Abstract

The use of integrated heaters is widespread in silicon photonics for waveguide temperature control. The dynamical behavior of the heaters is important for determining their usefulness for certain applications. There exists ambiguity in the literature when it comes to reporting the thermo-optic time constants of Si photonic devices. Many studies report devices with different heating and cooling times without providing an explanation to this phenomenon. In this paper, a comprehensive theoretical framework is developed for interpreting experimental results. This framework is developed for interferometric devices (Mach–Zehnder-based) and resonant devices (rings). With this framework, the impact of measurement conditions on the obtained thermo-optic time constant can be simulated, and we provide an explanation to the observed difference between heating and cooling time constants. We also provide guidelines on how to disentangle optical non-linearities from the pure thermal response, which should be useful in for future reporting of thermo-optic time constants. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Thermal Scaling Analysis of Large Hybrid Laser Arrays for Co-Packaged Optics

Author

Coenen, David, Sar, Huseyin, Marinins, Aleksandrs, Smyth, Stuart, McKee, Andrew, Ban, Yoojin, Van Campenhout, Joris, and Oprins, Herman

Abstract

Optical transceivers for data center applications require multi-wavelength light sources, which can either be integrated or external from the transceiver die. Scaling up the number of communication channels implies the need for large laser arrays. Since the energy efficiency of semiconductor lasers is very sensitive to temperature, it is imperative to employ a thermal-aware design and minimize self-heating and thermal crosstalk. In this paper, a thermal scaling analysis is performed on hybrid, flip-chip integrated InP-on-Si lasers. A finite element thermal model of a single gain section laser is validated with experimental measurement of the laser thermal resistance and extrapolated to accomodate multi-section operation. The impact of adding a top-side heat sink as well as increasing laser length and width are investigated. The detailed 3D simulation results are used to build a compact, coupled thermo-optic model of a large array of multiple lasers, considering thermal crosstalk. Finally, this model is applied to a test case with 8 WDM channels and 8 ports. Depending on the configuration (integrated vs. external) and ambient temperature, different optimal designs arise based on both energy efficiency and module footprint. The presented modelling framework is generic; it can be applied to different types of lasers and systems.

Published
2025
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9. Effects of Nozzle Pitch Adaptation in Micro-Scale Liquid Jet Impingement.

Author

Elsinger, Georg, Oprins, Herman, Cherman, Vladimir, Van der Plas, Geert, Beyne, Eric, and De Wolf, Ingrid

Subjects
JET impingement, COMPUTATIONAL fluid dynamics, HYDRAULIC jump, ELECTRONIC equipment, PRESSURE drop (Fluid dynamics), NOZZLES, LIQUIDS
Abstract

With ever increasing integration density of electronic components, the demand for cooling solutions capable of removing the heat generated by such systems grows along with it. It has been shown that a viable answer to this demand is the use of direct liquid jet impingement. While this method can generally be scaled to the cooling of large areas, this is restricted by the necessity of coolant flow rate scaling. In this study, the benefits and restrictions of using increased nozzle pitch to remedy the increasing demand for overall flow rate are investigated. To this end, a model is validated against experimental findings and then used for computational fluid dynamics simulations, exploring effects of the pitch change for micro-scale nozzle diameters and nozzle-to-target spacings. It is found that while this method is efficient in adjusting the tradeoff between total coolant flow rate and pressure drop up to a certain pint, the occurrence of a hydraulic jump in the cavity causes a deterioration of its effect for large nozzle pitches. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Modeling-Based Improvement of Microscale Liquid Jet Impingement Cooling

Author

Elsinger, Georg, Oprins, Herman, Cherman, Vladimir, Van der Plas, Geert, Beyne, Eric, and De Wolf, Ingrid

Abstract

As high-power electronics cooling for high heat fluxes above 100 W/cm $^{\mathbf {2}}$ continues to become a more and more pressing matter, work to provide an efficient and effective cooling solution in turn also continues. In the ecosystem of active liquid cooling solutions, it is the cooling performance that is provided within a given flow rate and pressure drop budget that determines efficiency. Liquid jet impingement on the bare die has been proven to provide good cooling performance that is not impeded by the thermal resistance of thermal interface materials. However, system optimizations are also necessary to provide the desired cooling performance within the restrictions of flow rate and pressure drop. A modeling study and experimental demonstrations were done in this work to showcase improvement options within restricted operating conditions. The modeling study shows that the adjustment of inlet- and outlet-nozzle diameter, nozzle-to-target spacing, and nozzle pitch allows for optimizing the achieved heat transfer coefficient at given operating conditions. Based on this modeling study, a reference cooler and different improved demonstrators were built, and within the same budget for coolant flow rate and driving pressure drop, an improvement of effective heat transfer coefficient by 122% from 4.9 to 10.4 W/cm $^{\mathbf {2}}\cdot $ K was achieved.

Published
2024
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24. 3ω correction method for eliminating resistance measurement error due to Joule heating

Author

Guralnik, Benny, primary, Hansen, Ole, additional, Henrichsen, Henrik H., additional, Beltrán-Pitarch, Braulio, additional, Østerberg, Frederik W., additional, Shiv, Lior, additional, Marangoni, Thomas A., additional, Stilling-Andersen, Andreas R., additional, Cagliani, Alberto, additional, Hansen, Mikkel F., additional, Nielsen, Peter F., additional, Oprins, Herman, additional, Vermeersch, Bjorn, additional, Adelmann, Christoph, additional, Dutta, Shibesh, additional, Borup, Kasper A., additional, Mihiretie, Besira M., additional, and Petersen, Dirch H., additional

Published
2021
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27. 3ω correction method for eliminating resistance measurement error due to Joule heating

Author

Guralnik, Benny, Hansen, Ole, Henrichsen, Henrik H., Beltrán-Pitarch, Braulio, Østerberg, Frederik W., Shiv, Lior, Marangoni, Thomas A., Stilling-Andersen, Andreas R., Cagliani, Alberto, Hansen, Mikkel F., Nielsen, Peter F., Oprins, Herman, Vermeersch, Bjorn, Adelmann, Christoph, Dutta, Shibesh, Borup, Kasper A., Mihiretie, Besira M., Petersen, Dirch H, Guralnik, Benny, Hansen, Ole, Henrichsen, Henrik H., Beltrán-Pitarch, Braulio, Østerberg, Frederik W., Shiv, Lior, Marangoni, Thomas A., Stilling-Andersen, Andreas R., Cagliani, Alberto, Hansen, Mikkel F., Nielsen, Peter F., Oprins, Herman, Vermeersch, Bjorn, Adelmann, Christoph, Dutta, Shibesh, Borup, Kasper A., Mihiretie, Besira M., and Petersen, Dirch H

Abstract

Electrical four-terminal sensing at (sub-)micrometer scales enables the characterization of key electromagnetic properties within the semiconductor industry, including materials' resistivity, Hall mobility/carrier density, and magnetoresistance. However, as devices' critical dimensions continue to shrink, significant over/underestimation of properties due to a by-product Joule heating of the probed volume becomes increasingly common. Here, we demonstrate how self-heating effects can be quantified and compensated for via 3ω signals to yield zero-current transfer resistance. Under further assumptions, these signals can be used to characterize selected thermal properties of the probed volume, such as the temperature coefficient of resistance and/or the Seebeck coefficient.

Published
2021

28. Thermal analysis of 3D functional partitioning for high-performance systems

Author

Oprins, Herman, Milojevic, Dragomir, Van Der Plas, Geert, Beyne, Eric, Oprins, Herman, Milojevic, Dragomir, Van Der Plas, Geert, and Beyne, Eric

Abstract

In this paper, we present a modeling study for the thermal analysis of a functionally partitioned high-performance 3D system-on-chip (SoC). The temperature distributions in a reference 2D-SoC and different stacking configurations of the 3D-SoC are evaluated using a Green ‘s function based semi-analytical thermal modeling method. The modeling study shows that there is only a limited thermal penalty for the 3D functional partitioning compared to the reference 2D-SoC. It is shown that the impact of the different 3D stacking configurations, with different order of the logic and memory layer, is much smaller than the thermal impact of the different cooling solutions that are considered for the 3D-SoC., SCOPUS: cp.p, info:eu-repo/semantics/published

Published
2021

31. Improved thermal performance of AlGaN/GaN HEMTs by an optimized flip-chip design

Author

Das, Jo, Oprins, Herman, Borghs, Gustaaf, Hangfeng Ji, Germain, Marianne, Sarua, Andrei, Kuball, Martin, Ruythooren, Wouter, and Derluyn, Joff

Subjects
High-electron-mobility transistors -- Design and construction, Gallium compounds -- Electric properties, Nitrides -- Electric properties, Aluminum compounds -- Electric properties, Business, Electronics, Electronics and electrical industries
Abstract

AlGaN/GaN high electron mobility transistors (HEMT) on sapphire substrates are studied for their potential application in RF power applications. Results reveal that a novel bump design, where bumps are placed directly onto both source and drain ohmic contacts, improves the thermal performance of the HEMT.

Published
2006

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