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1. An NDN-Enabled Fog Radio Access Network Architecture With Distributed In-Network Caching

   Taki, Sifat Ut; Mastorakis, Spyridon (January 2023, International Conference on Communications)

   To meet the increasing demands of next-generation cellular networks (e.g., 6G), advanced networking technologies must be incorporated. On one hand, the Fog Radio Access Network (F-RAN), has been proposed as an enhancement to the Cloud Radio Access Network (C-RAN). On the other hand, efficient network architectures, such as Named Data Networking (NDN), have been recognized as prominent Future Internet candidates. Nevertheless, the interplay between F-RAN and NDN warrants further investigation. In this paper, we propose an NDN-enabled F-RAN architecture featuring a strategy for distributed in-network caching. Through a simulation study, we demonstrate the superiority of the proposed in-network caching strategy in comparison with baseline caching strategies in terms of network resource utilization, cache hits, and front haul channel usage. 

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2. Comparative Principles for Next-Generation Neuroscience

   https://doi.org/https://doi.org/10.3389/fnbeh.2019.00012  

   Miller, Cory T; Hale, Melina E; Okano, H; Okabe, S; Mitra, P (February 2019, Frontiers in behavioral neuroscience)

   Neuroscience is enjoying a renaissance of discovery due in large part to the implementation of next-generation molecular technologies. The advent of genetically encoded tools has complemented existing methods and provided researchers the opportunity to examine the nervous system with unprecedented precision and to reveal facets of neural function at multiple scales. The weight of these discoveries, however, has been technique-driven from a small number of species amenable to the most advanced gene-editing technologies. To deepen interpretation and build on these breakthroughs, an understanding of nervous system evolution and diversity are critical. Evolutionary change integrates advantageous variants of features into lineages, but is also constrained by pre-existing organization and function. Ultimately, each species’ neural architecture comprises both properties that are species–specific and those that are retained and shared. Understanding the evolutionary history of a nervous system provides interpretive power when examining relationships between brain structure and function. The exceptional diversity of nervous systems and their unique or unusual features can also be leveraged to advance research by providing opportunities to ask new questions and interpret findings that are not accessible in individual species. As new genetic and molecular technologies are added to the experimental toolkits utilized in diverse taxa, the field is at a key juncture to revisit the significance of evolutionary and comparative approaches for next-generation neuroscience as a foundational framework for understanding fundamental principles of neural function. 

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3. Post-Quantum Cryptography for Integrated Space-Aerial-Terrestrial Networks: Current State, Challenges and Trends

   Gur, G; Yavuz, A A (June 2026, Springer Cham)

   Lenders, V; Blezinger, E; Jang-Jaccard; J; Mulder, V; Mermoud, A (Ed.)

   Emerging satellite networks integrated with terrestrial and aerial systems form a key part of next-generation infrastructures supporting the Internet of Everything (IoE). This chapter outlines the current status of PQC-based authentication in integrated Space-Aerial-Terrestrial Networks (SATIN), highlighting the technical challenges in achieving quantum-resilient security within constrained and complex environments. While quantum computing necessitates migration to post-quantum cryptography (PQC), existing standards often demand resources that are unsuited for SATIN’s limited hardware and fragile links. We analyze leading NIST PQC signature and key encapsulation schemes in the SATIN context, evaluating trade-offs in computational cost, signature size, and protocol compatibility. Emerging directions, including broader algorithm evaluations, advanced protocol integrations (e.g., EMSS and NIST-PQC with terrestrial backbone, PQ group key management), and some alternative PQ technologies are discussed. Addressing these challenges requires advanced simulation and experimental frameworks to enable scalable, practical, and quantum-resilient secure communications in future integrated networks. 

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4. Nanopackaging for FutureG Solutions

   https://doi.org/10.1109/MNANO.2024.3358691  

   Ghaleb_Al-Duhni, Ghaleb Saleh; Hasan, Muhammad Mahmudul; Pala, Nezih; Pulugurtha, Markondeya Raj (April 2024, IEEE Nanotechnology Magazine)

   Foundations for advancing wireless networks rely on the exploration of high-frequency bands ranging from 30 GHz to 300 GHz. FutureG technologies enable access to these bands with improved spectral efficiency and bandwidth. However, these trends also present significant challenges for future electronic systems. These are associated with design for higher gain and bandwidth to address higher pathlosses, interconnect losses between the transceiver and the antenna array, higher power consumption because of hardware complexity, electromagnetic interference (EMI), thermal management for higher power dissipation, limited manufacturability because of the new set of required materials, high functional density in multilayered substrates, and high production costs. Nanopackaging enables key solutions to many of these challenges by bringing advanced packaging and device materials, interfaces and package architectures to manage the complex system requirements for FutureG communications. These include nanoscale low-loss conductors, shielding structures, thermal interfaces and heat-spreaders, reconfigurable systems with tunable components, THz arrays and detectors, metasurfaces and seamless heterogeneous integration. This article reviews the key nanopackaging advances that are making FutureG communications a reality. 

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5. 2025 roadmap on 3D nanomagnetism

   https://doi.org/10.1088/1361-648X/ad9655  

   Gubbiotti, Gianluca; Barman, Anjan; Ladak, Sam; Bran, Cristina; Grundler, Dirk; Huth, Michael; Plank, Harald; Schmidt, Georg; van_Dijken, Sebastiaan; Streubel, Robert; et al (February 2025, Journal of Physics: Condensed Matter)

   Abstract The transition from planar to three-dimensional (3D) magnetic nanostructures represents a significant advancement in both fundamental research and practical applications, offering vast potential for next-generation technologies like ultrahigh-density storage, memory, logic, and neuromorphic computing. Despite being a relatively new field, the emergence of 3D nanomagnetism presents numerous opportunities for innovation, prompting the creation of a comprehensive roadmap by leading international researchers. This roadmap aims to facilitate collaboration and interdisciplinary dialogue to address challenges in materials science, physics, engineering, and computing. The roadmap comprises eighteen sections, roughly divided into three blocks. The first block explores the fundamentals of 3D nanomagnetism, focusing on recent trends in fabrication techniques and imaging methods crucial for understanding complex spin textures, curved surfaces, and small-scale interactions. Techniques such as two-photon lithography and focused electron beam-induced deposition enable the creation of intricate 3D architectures, while advanced imaging methods like electron holography and synchrotron x-ray tomography provide nanoscale spatial resolution for studying magnetization dynamics in three dimensions. Various 3D magnetic systems, including coupled multilayer systems, artificial spin-ice, magneto-plasmonic systems, topological spin textures, and molecular magnets are discussed. The second block introduces analytical and numerical methods for investigating 3D nanomagnetic structures and curvilinear systems, highlighting geometrically curved architectures, interconnected nanowire systems, and other complex geometries. Finite element methods are emphasized for capturing complex geometries, along with direct frequency domain solutions for addressing magnonic problems. The final block focuses on 3D magnonic crystals and networks, exploring their fundamental properties and potential applications in magnonic circuits, memory, and spintronics. Computational approaches using 3D nanomagnetic systems and complex topological textures in 3D spintronics are highlighted for their potential to enable faster and more energy-efficient computing. 

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