Additive Manufacturing of Thermoelectrics: Emerging Trends and Outlook

Zhang, Danwei; Lim, Wei Yang; Duran, Solco Samantha Faye; Loh, Xian Jun; Suwardi, Ady

doi:10.1021/acsenergylett.1c02553

Cited by 49 publications

(38 citation statements)

References 144 publications

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“…However, the effectiveness of these strategies is limited according to the defect type and the wavelengths of phonons [18,[38][39][40][41][42]. Alternatively, other strategies, such as band structure modulation, entropy engineering, and preferential scattering of minority carriers, can be explored, which aim to improve other components of thermal conductivity as well [43][44][45][46][47][48][49][50][51][52][53]. More recently, a fresh perspective on engineering next-generation high-performance thermoelectrics has been reported, which includes low doping, in contrast to the "golden range of carrier concentration" [54,55].…”

Section: Thermoelectric Devicesmentioning

confidence: 99%

Potential of Recycled Silicon and Silicon-Based Thermoelectrics for Power Generation

et al. 2022

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Thermoelectrics can convert waste heat to electricity and vice versa. The energy conversion efficiency depends on materials figure of merit, zT, and Carnot efficiency. Due to the higher Carnot efficiency at a higher temperature gradient, high-temperature thermoelectrics are attractive for waste heat recycling. Among high-temperature thermoelectrics, silicon-based compounds are attractive due to the confluence of light weight, high abundance, and low cost. Adding to their attractiveness is the generally defect-tolerant nature of thermoelectrics. This makes them a suitable target application for recycled silicon waste from electronic (e-waste) and solar cell waste. In this review, we summarize the usage of high-temperature thermoelectric generators (TEGs) in applications such as commercial aviation and space voyages. Special emphasis is placed on silicon-based compounds, which include some recent works on recycled silicon and their thermoelectric properties. Besides materials design, device designing considerations to further maximize the energy conversion efficiencies are also discussed. The insights derived from this review can be used to guide sustainable recycling of e-waste into thermoelectrics for power harvesting.

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Section: Thermoelectric Devicesmentioning

confidence: 99%

Potential of Recycled Silicon and Silicon-Based Thermoelectrics for Power Generation

et al. 2022

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“…Through decades of work on thermoelectrics, the physical understanding and chemical intuition in engineering their high performance are well established. [ 21–25 ] Strategies such as band‐engineering, carrier scattering modulation, nanostructuring, resonant doping, and energy filtering have been well reported to enhance various aspects of thermoelectrics. [ 17,26–31 ]…”

Section: Introductionmentioning

confidence: 99%

“…[18][19][20] Through decades of work on thermoelectrics, the physical understanding and chemical intuition in engineering their high performance are well established. [21][22][23][24][25] Strategies such as band-engineering, carrier scattering modulation, nanostructuring, resonant doping, and energy filtering have been well reported to enhance various aspects of thermoelectrics. [17,[26][27][28][29][30][31] In this work, we turn waste silicon PV into thermoelectrics by pulverizing polycrystalline silicon into powder, followed by pelletization into ingot.…”

Section: Introductionmentioning

confidence: 99%

Upcycling Silicon Photovoltaic Waste into Thermoelectrics

et al. 2022

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Two decades after the rapid expansion of photovoltaics, the number of solar panels reaching end‐of‐life is increasing. While precious metals such as silver and copper are usually recycled, silicon, which makes up the bulk of a solar cells, goes to landfills. This is due to the defect‐ and impurity‐sensitive nature in most silicon‐based technologies, rendering it uneconomical to purify waste silicon. Thermoelectrics represents a rare class of material in which defects and impurities can be engineered to enhance the performance. This is because of the majority‐carrier nature, making it defect‐ and impurity‐tolerant. Here, the upcycling of silicon from photovoltaic (PV) waste into thermoelectrics is enabled. This is done by doping 1% Ge and 4% P, which results in a figure of merit (zT) of 0.45 at 873 K, the highest among silicon‐based thermoelectrics. The work represents an important piece of the puzzle in realizing a circular economy for photovoltaics and electronic waste.

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“…For example, in traditional methods, there is a disadvantage to produce flow channels, such as electrodes and bipolar plates for energy applications by machining methods, in terms of both cost and their geometrical structures. Therefore, the AM method has recently become the lead production system in terms of design freedom, material savings, and easy production of complex structures. , It was the first application of the photopolymerization method for the 3D printing method. This method was introduced in the 1980s by Hideo Kodama.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, the AM method has recently become the lead production system in terms of design freedom, material savings, and easy production of complex structures. 32 , 33 It was the first application of the photopolymerization method for the 3D printing method. This method was introduced in the 1980s by Hideo Kodama.…”

Section: Introductionmentioning

confidence: 99%

An Overview of Various Additive Manufacturing Technologies and Materials for Electrochemical Energy Conversion Applications

et al. 2022

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Additive manufacturing (AM) technologies have many advantages, such as design flexibility, minimal waste, manufacturing of very complex structures, cheaper production, and rapid prototyping. This technology is widely used in many fields, including health, energy, art, design, aircraft, and automotive sectors. In the manufacturing process of 3D printed products, it is possible to produce different objects with distinctive filament and powder materials using various production technologies. AM covers several 3D printing techniques such as fused deposition modeling (FDM), inkjet printing, selective laser melting (SLM), and stereolithography (SLA). The present review provides an extensive overview of the recent progress in 3D printing methods for electrochemical fields. A detailed review of polymeric and metallic 3D printing materials and their corresponding printing methods for electrodes is also presented. Finally, this paper comprehensively discusses the main benefits and the drawbacks of electrode production from AM methods for energy conversion systems.

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Additive Manufacturing of Thermoelectrics: Emerging Trends and Outlook

Cited by 49 publications

References 144 publications

Potential of Recycled Silicon and Silicon-Based Thermoelectrics for Power Generation

Potential of Recycled Silicon and Silicon-Based Thermoelectrics for Power Generation

Upcycling Silicon Photovoltaic Waste into Thermoelectrics

An Overview of Various Additive Manufacturing Technologies and Materials for Electrochemical Energy Conversion Applications

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