Hydrothermal Synthesis Au-Bi2Te3 Nanocomposite Thermoelectric Film with a Hierarchical Sub-Micron Antireflection Quasi-Periodic Structure

Tian, Junlong; Zhang, Wang; Yuan, Zhe; Xue, Rongjian; Wang, Yuhua; Zhang, Zhijian; Zhang, Di

doi:10.3390/ijms160612547

Cited by 5 publications

(2 citation statements)

References 46 publications

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“…Then, the carriers are transferred to the other side (the cold side) of TEG and get accumulated there, thereby generating a potential difference between the hot and cold sides. At present, two kinds of solar TEGs are classified based on materials, including flexible organic thermoelectric materials and rigid inorganic thermoelectric materials. − The first type of solar TEG is a thin film device based on organic thermoelectric materials, and its hot side and cold side are located at the two horizontal ends of TEG. ,− This solar TEG usually has strong absorption in the solar spectrum, specifically the NIR-MIR region. Its principle is that the hot side absorbs infrared light through photothermal materials so that there is a temperature difference between the hot side and the cold side, and then, there is a potential difference.…”

Section: Introductionmentioning

confidence: 99%

High-Efficiency Photo-Thermo-Electric System with Waste Heat Utilization and Energy Storage

Liu

Long

et al. 2022

ACS Appl. Mater. Interfaces

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In a photo-thermo-electric system, solar energy is first converted into heat and then into electrical energy, which has attracted much attention. However, the heat of the cold side of a thermoelectric generator (TEG) is generally removed by an aircooling or water-cooling technology without being fully utilized, resulting in a low solar energy utilization efficiency. Here, we designed an integrated system composed of a photo-thermoelectric conversion part and a waste energy collection part. In this system, one carbon foam (CF) doped with PPy and PEG is used as a layer for photothermal conversion and energy storage, and the other CFwhere one side was hydrophobically modifiedis used for the storage of cooling water and the recovery of waste heat. The two CF layers contact the hot and cold sides of TEG, respectively. With the system, solar energy can be converted into heat and then electricity for TEG. On the other hand, waste heat can be utilized for seawater desalination by the process of water evaporation. In addition, the integrated system can work sustainably under intermittent light conditions. With the recovery of waste heat, the solar energy utilization efficiency in this system is greatly increased to as much as 86%.

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Section: Introductionmentioning

confidence: 99%

High-Efficiency Photo-Thermo-Electric System with Waste Heat Utilization and Energy Storage

Liu

Long

et al. 2022

ACS Appl. Mater. Interfaces

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“…Zhang and co‐workers further developed Au‐Bi 2 Te 3 composite thermoelectric film based on the same black scales. The nonhomogeneity of heat source density distribution was beneficial to efficiently generate electricity . The results pave a new pathway for the utilization of infrared light with natural evolved architectures and for photothermal and photoelectric conversion applications.…”

Section: Solar Energy Utilizationmentioning

confidence: 90%

Bio‐Inspired Photonic Materials: Prototypes and Structural Effect Designs for Applications in Solar Energy Manipulation

Zhou

Liu

et al. 2017

Adv Funct Materials

Self Cite

128

109

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Natural creatures have evolved elaborate photonic nanostructures on multiple scales and dimensions in a hierarchical, organized way to realize controllable absorption, reflection, or transmitting the desired wavelength of the solar spectrum. A bio-inspired strategy is a powerful and promising way for solar energy manipulation. This feature article presents the state-of-theart progress on bio-inspired photonic materials on this particular application. The article first briefly recalls the physical origins of natural photonic effects and catalogues the typical natural photonic prototypes including light harvesting, broadband reflection, selective reflection, and UV/IR response. Next, typical applications are categorized into two primary areas: solar energy utilization and reflection. Recent advances including solar-to-electricity, solar-to-fuels, solar-thermal (e.g., photothermal converters, infrared detectors, thermoelectric materials, smart windows, and solar steam generation) are highlighted in the first part. Meanwhile, solar energy reflection involving infrared stealth, radiative cooling, and micromirrors are also addressed. In particular, this article focuses on bioinspired design principles, structural effects on functions, and future trends. Finally, the main challenges and prospects for the next generation of bioinspired photonic materials are discussed, including new design concepts, emerging ideas, and possible strategies.

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Preparation of Cobalt doped Bi2Se3 nano-topological insulators

Ashoush

El-Okr

El-Fattah

2016

J Mater Sci: Mater Electron

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Hydrothermal Synthesis Au-Bi2Te3 Nanocomposite Thermoelectric Film with a Hierarchical Sub-Micron Antireflection Quasi-Periodic Structure

Cited by 5 publications

References 46 publications

High-Efficiency Photo-Thermo-Electric System with Waste Heat Utilization and Energy Storage

High-Efficiency Photo-Thermo-Electric System with Waste Heat Utilization and Energy Storage

Bio‐Inspired Photonic Materials: Prototypes and Structural Effect Designs for Applications in Solar Energy Manipulation

Preparation of Cobalt doped Bi2Se3 nano-topological insulators

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