UV electromagnetic irradiation sensing by GQDs sensitized ZnO/GaN heterostructure for wearable dosimetry

Lalit Goswami, Pukhraj Prajapat, Pargam Vashishtha, Govind Gupta
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Abstract

Sensing of Ultraviolet (UV) Electromagnetic Irradiations (EIs) for wearable dosimetry is promulgated universally by reserving their place in precise calibration for the controlled exposure of UV-EIs for the betterment of humankind. In other words, the controlled exposure of incident optical power density (OPD) of UV-EIs found advantageous and numerous noble healthcare applications such as beta-endorphin molecule (provide feel-good factor to the brain) level augmentation, adequate vitamin D (physical strength) level formation, in skin treatment like eczema and dermatitis, sensing important biomolecules like Uric Acid (responsible for critical disease related with kidney and heart). Moreover, the controlled exposure of OPDs also significantly impacts UV disinfection technologies, which provide a defensive shield against critical respiratory syndrome coronavirus 2 (SARS-CoV-2), which belongs to the COVID-19 pandemic. Therefore, by understanding the importance of limited exposure to these vital UV-EIs, the present study showcased the GQDs-sensitized ZnO/GaN heterostructured UV sensor utilized to explore the impact of UV-EIs OPDs on their performance. This study helps to develop and utilize the UV sensor-based wearable dosimetry for in-house diagnostics of critical healthcare parameters. This report also divulged an interesting core mechanism (band bending, tunneling through narrowed hole injection under increased negative bias) involved in affecting the performance of the UV-EIs sensor by a function of growing OPDs with the help of a suitable band diagram. The impact of increasing OPDs on fabricated UV-EIs sensors can be well understood by the fact that, by varying the OPDs up to ∼550%, the Gain (G), responsivity (R), external quantum efficiency (EQE) and noise equivalent power (NEP) significantly increases up to (156.7 to 332.4) ∼300%, (118 A W−1 to 3200 A W−1) 2700%, (∼870% to 12 × 103%) 1400% and (1.3 pWHz−1/2 to 50 fWHz−1/2) 10,000% respectively at an applied bias of −6 V. Furthermore, the time-correlated transient photoresponse is also dramatically improved with increasing OPDs, wherein the increment in rise and decay time is estimated as (159 ms to 7.86 ms) ∼2000% and (68.7 ms to 12.4 ms) ∼500%, respectively.
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利用 GQDs 敏化 ZnO/GaN 异质结构传感紫外线电磁辐照,用于可穿戴式剂量测定
用于可穿戴式剂量测定的紫外线(UV)电磁辐照(EIs)传感技术已被广泛应用于精确校准紫外线(UV)电磁辐照的受控照射,以造福人类。换句话说,紫外线-可见光入射光功率密度(OPD)的可控照射具有众多高尚的医疗保健应用优势,如增加 beta-内啡肽分子(为大脑提供良好感觉的因子)水平、形成充足的维生素 D(体力)水平、治疗湿疹和皮炎等皮肤疾病、感知重要的生物大分子,如尿酸(导致肾脏和心脏相关的严重疾病)。此外,OPDs 的受控暴露也会对紫外线消毒技术产生重大影响,而紫外线消毒技术则是抵御属于 COVID-19 大流行病的严重呼吸综合征冠状病毒 2(SARS-CoV-2)的防御屏障。因此,通过了解有限暴露于这些重要的紫外-可见光的重要性,本研究展示了 GQDs 敏化 ZnO/GaN 异质结构紫外传感器,用于探索紫外-可见光 OPDs 对其性能的影响。这项研究有助于开发和利用基于紫外传感器的可穿戴剂量计,用于关键医疗参数的内部诊断。该报告还揭示了一个有趣的核心机制(带弯曲、在负偏压增加的情况下通过狭窄的空穴注入隧道),该机制在适当带图的帮助下,通过 OPDs 的增长函数影响紫外线-EIs 传感器的性能。增加 OPD 对所制造的紫外-可见光传感器的影响可以通过以下事实很好地理解:当 OPD 变化达 ∼550% 时,增益 (G)、响应率 (R)、外部量子效率 (EQE) 和噪声等效功率 (NEP) 显著增加,最高可达(156.在外加偏压为 -6 V 时,增益(G)、响应率(R)、外部量子效率(EQE)和噪声等效功率(NEP)分别大幅增加到(156.7 至 332.4)∼300%、(118 A W-1 至 3200 A W-1)2700%、(∼870% 至 12 × 103%)1400% 和(1.3 pWHz-1/2 至 50 fWHz-1/2)10,000%。此外,随着 OPD 的增加,与时间相关的瞬态光响应也得到显著改善,上升和衰减时间分别增加了(159 毫秒至 7.86 毫秒)∼2000% 和(68.7 毫秒至 12.4 毫秒)∼500%。
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