太赫兹在物理、工程和生命科学领域的无声革命：超越光谱

IF 6.3 3区综合性期刊 Q1 Multidisciplinary

Fundamental Research Pub Date : 2025-09-01 DOI:10.1016/j.fmre.2025.05.004

Yuankun Sun , Shaomeng Wang , Yubin Gong

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引用次数: 0

摘要

太赫兹技术通过将非电离辐射与分子灵敏度和材料穿透性相结合，正在彻底改变光子学、生物医学和通信。超材料、自适应天线和人工智能驱动系统的进步解决了发射效率和大气衰减方面的历史限制，实现了安全的高容量网络和精确的生物医学应用。可重构波束形成和混合信道模型增强了无线可靠性，而超灵敏生物传感器和神经调节技术则开创了神经退行性疾病和精神疾病的非侵入性诊断和治疗。太赫兹在分子传感和神经调节中的双重作用建立了闭环“检测-治疗”范式，连接了材料科学和神经科学。在优化临床应用和混合系统可扩展性方面仍然存在挑战，但其探测载体动力学、蛋白质相互作用和神经回路的能力使太赫兹成为6G网络、个性化医疗和脑机接口的通用平台。通过将物理感知工程与生物洞察力相结合，太赫兹技术超越了传统界限，为医疗保健、安全连接和工业创新提供了变革性解决方案。

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Terahertz's silent revolution in physics, engineering, and life science: Beyond the spectrum

Terahertz technology is revolutionizing photonics, biomedicine, and communications by merging non-ionizing radiation with molecular sensitivity and material penetration. Advances in metamaterials, adaptive antennas, and AI-driven systems address historical limitations in emission efficiency and atmospheric attenuation, enabling secure high-capacity networks and precision biomedical applications. Reconfigurable beamforming and hybrid channel models enhance wireless reliability, while ultra-sensitive biosensors and neuromodulation techniques pioneer non-invasive diagnostics and therapies for neurodegenerative and psychiatric disorders. Terahertz’s dual role in molecular sensing and neural modulation establishes closed-loop “detect-treat” paradigms, bridging material science and neuroscience. Challenges remain in optimizing clinical application and hybrid system scalability, yet its capacity to probe carrier dynamics, protein interactions, and neural circuits positions Terahertz as a universal platform for 6G networks, personalized medicine, and brain-machine interfaces. By unifying physics-aware engineering with biological insights, terahertz technology transcends traditional boundaries, offering transformative solutions for healthcare, secure connectivity, and industrial innovation.

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