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Ultrafast Electro-thermal Transport Through Nanoscale Electronic Materials and Interfaces

2023
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Release : 2023
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Book Synopsis Ultrafast Electro-thermal Transport Through Nanoscale Electronic Materials and Interfaces by : Christopher Perez

Download or read book Ultrafast Electro-thermal Transport Through Nanoscale Electronic Materials and Interfaces written by Christopher Perez. This book was released on 2023. Available in PDF, EPUB and Kindle. Book excerpt: Although silicon-based nanofabrication technology has satisfied computational demands for decades, the aggressive scaling of complementary metal oxide semiconductor (CMOS) technology to sub-5 nm geometries poses challenges that must be addressed at the materials level. One example is tuning electro-thermal transport in metal nanostructures to enhance the transfer of information and the dissipation of heat in integrated circuits. The manipulation of these pathways can be further optimized by integrating low-temperature passivation materials with varying thermal conductivities. Furthermore, the emergence of photonic interconnects presents an opportunity for the integration of electro-optic components that rely heavily on the movement, transfer, and recombination of charge carriers within photosensitive materials. All the above are governed by the fundamental limits of physical transfer mechanisms in semiconductors, bringing electron and phonon engineering --the control of heat and charge carriers in materials-- to the forefront of CMOS hardware design. This work explores the fundamental mechanisms and limits of electron-phonon transport in four individual material systems which can comprise different parts of a broader, electro-thermally optimized electronic system using primarily time-domain thermoreflectance (TDTR) and scanning ultrafast electron microscopy (SUEM) as probes. First, we discuss the electro-thermal characterization of iridium (Ir) as an emerging metal for high aspect ratio nanostructures on account of its favorable resistivity scaling with thickness. The exceptionally defect-free metal films offer minimal confounding microstructural effects and allow the probing of thermal anisotropy and cross-plane quasi-ballistic thermal transport in epitaxial Ir(001) interposed between Al and MgO(001). Such effects reveal a transition between three dominant cross-plane thermal transport mechanisms which include electron dominant, phonon dominant, and electron-phonon energy conversion dominant regimes at different thicknesses. Finally, we develop a phenomenological model that correctly describes the dominant transport regimes, providing insight into the thickness-dependent interplay between carriers in metals as well as enabling quick evaluation and potential scalability to broader material systems. Next, we describe defect-modulated thermal transport in sputtered aluminum nitride (AlN) thin films for enabling wide-bandgap (WBG), high-temperature, and high-power electronic devices deposited at back-end of the line (BEOL) compatible temperatures (

Ultrafast Thermal Transport at Interfaces

2014
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Release : 2014
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Book Synopsis Ultrafast Thermal Transport at Interfaces by :

Download or read book Ultrafast Thermal Transport at Interfaces written by . This book was released on 2014. Available in PDF, EPUB and Kindle. Book excerpt: Our research program on Ultrafast Thermal Transport at Interfaces advanced understanding of the mesoscale science of heat conduction. At the length and time scales of atoms and atomic motions, energy is transported by interactions between single-particle and collective excitations. At macroscopic scales, entropy, temperature, and heat are the governing concepts. Key gaps in fundamental knowledge appear at the transitions between these two regimes. The transport of thermal energy at interfaces plays a pivotal role in these scientific issues. Measurements of heat transport with ultrafast time resolution are needed because picoseconds are the fundamental scales where the lack of equilibrium between various thermal excitations becomes a important factor in the transport physics. A critical aspect of our work has been the development of experimental methods and model systems that enabled more precise and sensitive investigations of nanoscale thermal transport.

Ultrafast Optical Characterization of Nanoscale Thermal Properties

2012
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Release : 2012
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Book Synopsis Ultrafast Optical Characterization of Nanoscale Thermal Properties by : Mr. Elah Bozorg-Grayeli

Download or read book Ultrafast Optical Characterization of Nanoscale Thermal Properties written by Mr. Elah Bozorg-Grayeli. This book was released on 2012. Available in PDF, EPUB and Kindle. Book excerpt: Ultrafast thermoreflectance is a powerful technique designed to measure thermal properties in films less than a micrometer thick. Careful sample design and control over the measurement timescale allow spatial and temporal confinement of the measurement to a region of interest. This work explores the capability of nanosecond and picosecond thermoreflectance in capturing the thermal properties of a host of exotic materials used in next generation electronic devices. These include the phase change material Ge2Sb2Te5 (GST), diamond substrates for high electron mobility transistors (HEMT), and multilayer Mo/Si mirrors for extreme ultraviolet wavelengths (EUV). Nanosecond and picosecond thermoreflectance were used to determine the thermal properties of the phase change material, GST, along with several candidate electrode films (C, Ti, TiN, W, and WNx) and novel electrode multilayers (C-TiN and W-WNx). These results offer a material selection roadmap for device designers seeking to tune the thermal properties of their PCM cell. This work also reports picosecond thermoreflectance measurements of GST films sandwiched between TiN electrode layers and annealed at multiple temperatures. Thermal conductivity of the hexagonal close-packed (HCP) phase exceeds that of the face centered cubic (FCC) phase due to the addition of electron thermal conduction. Electron interface transport is shown to be negligible, implying that the addition of electrons as energy carriers does not significantly affect thermal boundary resistance (TBR). Thermal spreading analysis of a representative HEMT structure on diamond and SiC substrates shows that a device-substrate thermal interface resistance in excess of 20 m2 K GW-1 negates the benefits of diamond as a substrate material. Picosecond thermoreflectance measurements on multiple diamond samples were performed to determine the thermal conductivity, thermal anisotropy, and boundary resistance of diamond on AlN substrates. Further measurements on the top and bottom surfaces of a suspended diamond films demonstrated the thermal conductivity of the coalescence region (80 W m-1 K-1) and high quality layer (1350 W m-1 K-1) of a single diamond film. Using a two-layer model of the diamond film, we predict the thickness of the coalescence region and show it to be less than 1 [micrometer]. The operating temperatures of Mo/Si multilayers used in EUV lithography affect their lifetimes. Predicting the mirror/mask damage threshold fluence requires accurate knowledge of the mirror thermal properties. This study reports high temperature thermal properties of the TaN masking film, the MoSi2 intermetallic, and the room temperature properties of the Mo/Si multilayer. The thickness dependent electrical conductivity of TaN estimates the mean free path of electrons in the film unhindered by the material interfaces (~ 30 nm). Measurements on MoSi2 demonstrate the change in thermal conductivity due to crystallization, from 1.7 W m-1 K-1 in the amorphous phase to 2.8 W m-1 K-1 in the crystalline phase. Mo/Si results demonstrate thermal conductivity (1.1 W m-1 K-1) significantly lower than previous literature assumptions (4-5 W m-1 K-1). A finite element thermal model uses these results to predict the maximum EUV fluence allowed on a Mo/Si mirror for a single shot and for a one billion pulse lifetime before causing a reflectance loss of 1%.

Nanoscale Photonics and Optoelectronics

2010-11-16 Technology & Engineering
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Release : 2010-11-16
Genre : Technology & Engineering
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Book Synopsis Nanoscale Photonics and Optoelectronics by : Zhiming M Wang

Download or read book Nanoscale Photonics and Optoelectronics written by Zhiming M Wang. This book was released on 2010-11-16. Available in PDF, EPUB and Kindle. Book excerpt: The intersection of nanostructured materials with photonics and electronics shows great potential for clinical diagnostics, sensors, ultrafast telecommunication devices, and a new generation of compact and fast computers. Nanophotonics draws upon cross-disciplinary expertise from physics, materials science, chemistry, electrical engineering, biology, and medicine to create novel technologies to meet a variety of challenges. This is the first book to focus on novel materials and techniques relevant to the burgeoning area of nanoscale photonics and optoelectronics, including novel-hybrid materials with multifunctional capabilities and recent advancements in the understanding of optical interactions in nanoscale materials and quantum-confined objects. Leading experts provide a fundamental understanding of photonics and the related science and technology of plasmonics, polaritons, quantum dots for nanophotonics, nanoscale field emitters, near-field optics, nanophotonic architecture, and nanobiophotonic materials.

Understanding Heat Transport at Interfaces for Thermal Management of Electronics

2022
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Release : 2022
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Book Synopsis Understanding Heat Transport at Interfaces for Thermal Management of Electronics by : Lenan Zhang

Download or read book Understanding Heat Transport at Interfaces for Thermal Management of Electronics written by Lenan Zhang. This book was released on 2022. Available in PDF, EPUB and Kindle. Book excerpt: The discovery and development of two-dimensional (2D) materials offer new opportunities for high-performance nanoscale electronics. However, new material systems involve new device architectures, which leads to new challenges on both the electronic and thermal design. While significant progress has been made to understand and engineer the electrical properties of 2D devices, the thermal problems remain relatively poorly understood. Since many 2D electronics can reach very high-power density (>104 W/cm2 ), the dense vertical integration of multilayers within a few nanometers leads to a significant temperature rise (>150 °C), which becomes the bottleneck of device performance. These thermal challenges are associated with two critical thermophysical properties of 2D materials, i.e., the thermal expansion and the interfacial thermal transport. In addition, to address the thermal management of 2D electronics, novel cooling approaches with insights gained from 2D thermal interfaces are in high demands. This thesis performed a systematic study on the thermal expansion and thermal transport of the van der Waals (vdW) bonded 2D interfaces, and developed highly efficient thermal management solutions based on two-phase cooling. First, we developed for the first time a pure experimental approach to accurately measure the thermal expansion coefficients(TECs) of various 2D materials. Our measurements confirmed the correct physical range of 2D monolayer TECs and hence addressed the more than two orders of magnitude discrepancies in literature. Second, we investigated the thermal transport across various 2D interfaces. In particular, we elucidated the role of vdW interaction in the anisotropic thermal transport of substrate-supported 2D monolayers and identified an optimal vdW interaction toward the maximum total heat transfer. On the other hand, we explored the twist-angle dependence of 2D interfacial thermal transport. We observed that depending on different material systems, the thermal transport of 2D materials can exhibit both strong and weak twist-angle dependences, which creates a new degree of freedom to manipulate heat at the atomic level. Lastly, with fundamental understanding of 2D thermal interfaces, we designed and optimized a liquid-vapor thin film evaporator based on microstructured surfaces, enabling high-performance thermal management of 2D electronics. This thesis provides a holistic understanding for the fundamental thermal properties of 2D materials and interfaces, which are critical to address the thermal crisis of 2D electronics. We believe the simulation, experimental, and design approaches developed in this thesis can serve as a guideline for the next-generation 2D electronics with unprecedented reliability and performance.

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