Use of effective medium theory for characterization of optical and dielectric properties of explosive composites in terahertz spectral range

IF 3.4 3区物理与天体物理 Q2 INSTRUMENTS & INSTRUMENTATION

Infrared Physics & Technology Pub Date : 2025-09-01 DOI:10.1016/j.infrared.2025.106129

Rajesh Koalla, Anil Kumar Chaudhary

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Abstract

This paper reports the optical and dielectric characterization of highly sensitive explosives composites using an Effective Medium Theory approach in Terahertz Time-domain Spectroscopy. For the spectroscopic studies, samples need to be in pellet form. However, making pellets of some of the primary shock-sensitive high-energy materials is risky due to their sensitivity to grinding. Therefore, these sensitive samples must be mixed with an external host medium (Teflon) to form a pellet. We have approached Effective Medium Theory (EMT) analytic relations, such as Maxwell Garnett, Bruggeman, and LLL approaches, to extract the optical and dielectric properties from Teflon/ sensitive explosive composite. The approach was validated by preparing a mixture of three premium explosives, RDX, HMX, and TNT, in a Teflon matrix and extracting their optical and dielectric properties using the Effective Medium Theory method. The obtained properties of the explosives were then compared with those of the pure explosives (without the Teflon matrix). The extracted values show good agreement with those of the pure samples for the explosive mixture in the Teflon matrix (1:5).

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利用有效介质理论在太赫兹光谱范围内表征爆炸复合材料的光学和介电性能

利用有效介质理论方法在太赫兹时域光谱中研究了高敏感炸药复合材料的光学和介电特性。对于光谱研究，样品需要呈颗粒状。然而，由于一些主要的冲击敏感高能材料对研磨的敏感性，制造颗粒是有风险的。因此，这些敏感样品必须与外部宿主介质（聚四氟乙烯）混合以形成颗粒。我们利用有效介质理论（EMT）分析关系，如Maxwell Garnett、Bruggeman和LLL方法，从特氟龙/敏感炸药复合材料中提取光学和介电性质。通过将RDX、HMX和TNT三种优质炸药混合在聚四氟乙烯基体中，并使用有效介质理论方法提取其光学和介电性质，验证了该方法的有效性。然后将所得炸药的性能与纯炸药（不含特氟龙基体）的性能进行比较。在聚四氟乙烯基质（1:5）中，炸药混合物的提取值与纯样品的提取值吻合良好。

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来源期刊

Infrared Physics & Technology 物理-光学

CiteScore

5.70

自引率

12.10%

发文量

400

审稿时长

67 days

期刊介绍： The Journal covers the entire field of infrared physics and technology: theory, experiment, application, devices and instrumentation. Infrared'' is defined as covering the near, mid and far infrared (terahertz) regions from 0.75um (750nm) to 1mm (300GHz.) Submissions in the 300GHz to 100GHz region may be accepted at the editors discretion if their content is relevant to shorter wavelengths. Submissions must be primarily concerned with and directly relevant to this spectral region. Its core topics can be summarized as the generation, propagation and detection, of infrared radiation; the associated optics, materials and devices; and its use in all fields of science, industry, engineering and medicine. Infrared techniques occur in many different fields, notably spectroscopy and interferometry; material characterization and processing; atmospheric physics, astronomy and space research. Scientific aspects include lasers, quantum optics, quantum electronics, image processing and semiconductor physics. Some important applications are medical diagnostics and treatment, industrial inspection and environmental monitoring.