Nitrogen-doped carbon quantum dots enable efficient photothermal conversion for direct absorption solar collectors

IF 6.3 2区 材料科学 Q2 ENERGY & FUELS
Yuxin Liu , Chuanshuai Dong , Chaohua Peng , Tao Zhang , Lizhi Zhang
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Abstract

Direct absorption solar collector (DASC) using nanofluids is an efficient way to utilize solar energy. The heat collection efficiency in DASC is constrained by the stability and optical absorption capacity of nanofluids. Carbon quantum dots (CQDs) nanofluids are used in DASC due to the excellent dispersion stability. However, the optical absorption range of current CQDs is primarily confined to the ultraviolet region, resulting in the visible and near-infrared regions of sunlight being underutilized. To solve this problem, this study synthesized novel N-doped carbon quantum dots (FPNCQDs) using ammonium bifluoride (NH4F) and perylene derivatives. The addition of NH4F and perylene derivatives during synthesis increased the sp2 conjugated structure and the content of graphite N in FPNCQDs. The doping of N, especially graphite N, significantly reduces the band gap by injecting excess electrons into the unoccupied π∗ orbitals. The temperature of FPNCQDs/EG nanofluids increased from 24 °C to 65.7 °C within 60 min, demonstrating excellent photothermal conversion performance. What's more, the FPNCQDs/EG nanofluids achieved high stability with nearly consistent transmittance over a 14-day storage test. Finally, a theoretical model for the photothermal conversion process of the nanofluids was developed to investigate the effect to carbon quantum dots on the solar collection performance. The simulation results indicated that the FPNCQDs/EG nanofluids at 10 ppm demonstrated the highest solar collection efficiency considering both photothermal conversion and heat loss from the surface. The novel FPNCQDs/EG nanofluid will be a promising photothermal fluids in direct absorption solar collector.
掺氮碳量子点实现直接吸收太阳能集热器的高效光热转换
使用纳米流体的直接吸收太阳能集热器(DASC)是一种高效利用太阳能的方法。DASC的集热效率受到纳米流体稳定性和光吸收能力的制约。碳量子点(CQDs)纳米流体具有出色的分散稳定性,因此被用于 DASC。然而,目前 CQDs 的光吸收范围主要局限于紫外线区域,导致太阳光的可见光和近红外区域未得到充分利用。为解决这一问题,本研究利用氟化氢铵(NH4F)和过烯衍生物合成了新型 N 掺杂碳量子点(FPNCQDs)。在合成过程中加入 NH4F 和过二甲苯衍生物增加了 FPNCQDs 的 sp2 共轭结构和石墨 N 的含量。N 的掺杂,尤其是石墨 N 的掺杂,通过向未被占用的 π∗ 轨道注入过量电子而显著降低了带隙。在 60 分钟内,FPNCQDs/EG 纳米流体的温度从 24 ℃ 升至 65.7 ℃,显示出卓越的光热转换性能。此外,FPNCQDs/EG 纳米流体还具有很高的稳定性,在 14 天的储存测试中透射率几乎保持一致。最后,建立了纳米流体光热转换过程的理论模型,以研究碳量子点对太阳能收集性能的影响。模拟结果表明,考虑到光热转换和表面热损失,10 ppm 的 FPNCQDs/EG 纳米流体的太阳能收集效率最高。新型 FPNCQDs/EG 纳米流体将成为直接吸收太阳能集热器中一种前景广阔的光热流体。
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来源期刊
Solar Energy Materials and Solar Cells
Solar Energy Materials and Solar Cells 工程技术-材料科学:综合
CiteScore
12.60
自引率
11.60%
发文量
513
审稿时长
47 days
期刊介绍: Solar Energy Materials & Solar Cells is intended as a vehicle for the dissemination of research results on materials science and technology related to photovoltaic, photothermal and photoelectrochemical solar energy conversion. Materials science is taken in the broadest possible sense and encompasses physics, chemistry, optics, materials fabrication and analysis for all types of materials.
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