Random Metamaterials with Double Negative Electromagnetic Parameters in Dense CuCr2Se4-CoCr2Se4 Binary Spinels

IF 3.3 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Dalton Transactions Pub Date : 2025-09-15 DOI:10.1039/d5dt01531f

Jun Cao, Chengsheng Wang, Zechao Xu, Kelan Yan, Liming Shen, Zhen Huang, Lingjie Zhang, Runhua Fan, Ningzhong Bao

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引用次数: 0

Abstract

Metamaterials exhibiting simultaneous negative permittivity (ε<0) and negative permeability (µ<0) offer exceptional electromagnetic properties, enabling advanced applications such as subwavelength imaging, wireless power transfer, and advanced antenna systems. Chromium-based selenium spinel composites have emerged as promising candidates for random double-negative metamaterials (DNMs), although achieving tunable and desired double-negative characteristics remains challenging. Here, CoCr2Se4, distinguished by high magnetic spin resonance in high-frequency fields and low conductivity, was selected to modulate the electromagnetic properties of CuCr₂Se₄-based composites. A series of (1-x)CuCr2Se4·xCoCr2Se4 samples were synthesized via a solid-state reaction. Double-negative properties (ε′ᵣ < 0, μ′ᵣ < 0) were achieved in the MHz frequency ranges, specifically within 841–1000 MHz for x = 0.2, 638–1000 MHz for x = 0.4, and 484–1000 MHz for x = 0.6. The negative permittivity arises from the plasma oscillations of delocalized carriers, well described by the Drude model. Meanwhile, negative permeability is explained through the suppression of eddy currents–due to the low conductivity of CoCr2Se4–which mitigates skin-depth limitations and enhances magnetic resonance. This composite design not only reduces electromagnetic attenuation but also improves magnetic responsiveness under alternating fields. By clarifying the selection rationale for metallic ferromagnetic spinel composites, this work enhances the theoretical understanding and tuning mechanisms of negative ε and µ. It thereby broadens the scope of metamaterial research and facilitates the development of single-phase double-negative materials, especially for low-frequency near-field applications

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CuCr2Se4-CoCr2Se4二元尖晶石中具有双负电磁参数的随机超材料

同时具有负介电常数（ε<0）和负磁导率（µ<0）的超材料具有卓越的电磁特性，可实现亚波长成像、无线电力传输和先进天线系统等先进应用。铬基硒尖晶石复合材料已成为随机双负超材料（dnm）的有希望的候选材料，尽管实现可调和理想的双负特性仍然具有挑战性。本研究选用高频自旋共振高、电导率低的CoCr2Se4来调制CuCr₂Se₄基复合材料的电磁性能。通过固相反应合成了一系列（1-x）CuCr2Se4·xCoCr2Se4样品。在MHz频率范围内实现双负特性（ε′ᵣ< 0, μ′ᵣ< 0），特别是当x = 0.2时841-1000 MHz，当x = 0.4时638-1000 MHz，当x = 0.6时484-1000 MHz。负介电常数是由离域载流子的等离子体振荡引起的，德鲁德模型很好地描述了这一点。同时，负磁导率是通过抑制涡流来解释的——由于cocr2se4的低电导率，这减轻了皮肤深度的限制，增强了磁共振。这种复合设计不仅减少了电磁衰减，而且提高了交变磁场下的磁响应性。通过澄清金属铁磁尖晶石复合材料的选择原理，本工作增强了对负ε和µ调谐机理的理论认识。从而拓宽了超材料研究的范围，促进了单相双负材料的发展，特别是低频近场应用

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来源期刊

Dalton Transactions 化学-无机化学与核化学

CiteScore

6.60

自引率

7.50%

发文量

1832

审稿时长

1.5 months

期刊介绍： Dalton Transactions is a journal for all areas of inorganic chemistry, which encompasses the organometallic, bioinorganic and materials chemistry of the elements, with applications including synthesis, catalysis, energy conversion/storage, electrical devices and medicine. Dalton Transactions welcomes high-quality, original submissions in all of these areas and more, where the advancement of knowledge in inorganic chemistry is significant.