Sílvia F V Silva, Gonçalo Figueiredo, Rui F P Pereira, Verónica de Zea Bermudez, Lianshe Fu, Paulo S André, Albano N Carneiro Neto, Rute A S Ferreira
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引用次数: 0
摘要
发光测温仪具有精确的远程温度测量能力,但在实际应用中却面临着巨大的挑战,主要是由于校准容易受到环境因素的影响。外部因素会影响精度,因此必须采用弹性测量协议,以确保在各种环境下都能获得可靠的温度 (T) 读数。我们探索了一种基于时间门控(t)发光测温参数Δ(T,t)的新型三维(3D)方法,该方法采用了基于二苯甲酰甲烷和罗丹明 B 的表面工程碳点(CD)物理混合物。这些碳点显示出持久、温度响应和可定制的磷光,易于被低功率 LED 激活,并因热激活延迟磷光而延长了发射时间。通过传统的光谱仪分析或在手电筒照明下使用智能手机摄像头拍摄照片,可对热发射依赖性进行量化,每个样品可获得多达 30 个时间门控比率测温参数。值得注意的是,在 23-45 °C 的温度范围内,7.9% °C-1 的最大相对灵敏度超过了目前最先进的基于 CD 的温度计,并确保了低分辨率便携式设备(如未改装的智能手机)的温度读数。
Time-gated multi-dimensional luminescence thermometry via carbon dots for precise temperature mobile sensing.
Luminescence thermometry presents precise remote temperature measurement capabilities but faces significant challenges in real-world applications, primarily stemming from the calibration's susceptibility to environmental factors. External factors can compromise accuracy, necessitating resilient measurement protocols to ensure dependable temperature (T) readings across various settings. We explore a novel three-dimensional (3D) approach based on time-gated (t) luminescence thermometric parameters, Δ(T,t), employing physical mixtures of surface-engineered carbon dots (CDs) based on dibenzoylmethane and rhodamine B. These CDs showcase enduring, temperature-responsive, and customizable phosphorescence, easily activated by low-power LEDs and distinguished by their prolonged emission time due to thermally activated delayed phosphorescence. Quantifying the thermal emission dependency is achievable through conventional spectrometer analyses or by capturing photographs with a smartphone's camera under flashlight illumination, yielding up to 30 time-gated ratiometric thermometric parameters per sample. Notably, within the temperature range of 23-45 °C, the maximum relative sensitivity of 7.9% °C-1 surpasses current state-of-the-art CD-based thermometers and ensures temperature readout with low-resolution portable devices as non-modified smartphones.
期刊介绍:
Nanoscale is a high-impact international journal, publishing high-quality research across nanoscience and nanotechnology. Nanoscale publishes a full mix of research articles on experimental and theoretical work, including reviews, communications, and full papers.Highly interdisciplinary, this journal appeals to scientists, researchers and professionals interested in nanoscience and nanotechnology, quantum materials and quantum technology, including the areas of physics, chemistry, biology, medicine, materials, energy/environment, information technology, detection science, healthcare and drug discovery, and electronics.
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