Additive manufacturing of highly conductive carbon nanotube architectures towards carbon-based flexible thermoelectric generators

IF 3.2 Q2 CHEMISTRY, PHYSICAL
Energy advances Pub Date : 2024-05-29 DOI:10.1039/D4YA00182F
Christos K. Mytafides, William J. Wright, Raden Gustinvil, Lazaros Tzounis, George Karalis, Alkiviadis S. Paipetis and Emrah Celik
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Abstract

Moving the fabrication of electronics from the conventional 2D orientation to 3D space, necessitates the use of sophisticated additive manufacturing processes which are capable to deliver multifunctional materials and devices with exceptional spatial resolution. In this study, it is reported the nozzle-guided 3D-printing of highly conductive, epoxy-dispersed, single-walled carbon nanotube (SWCNT) architectures with embedded thermoelectric (TE) properties, capable to exploit significant waste thermal energy from the environment. In order to achieve high-resolution and continuous printing with the SWCNT-based paste through a confined nozzle geometry, i.e. without agglomeration and nozzle clogging, a homogeneous epoxy resin-dispersed SWCNT paste was produced. As a result, various 3D-printed structures with high SWCNT concentration (10 wt%) were obtained via shear-mixing processes. The 3D printed p- and n-type epoxy-dispersed SWCNT-based thermoelements exhibit high power factors of 102 and 75 μW mK−2, respectively. The manufactured 3D carbon-based thermoelectric generator (3D-CTEG) has the ability to stably operate at temperatures up to 180 °C in ambient conditions (1 atm, relative humidity: 50 ± 5% RH), obtaining TE values of an open-circuit voltage VOC = 13.6 mV, short-circuit current ISC = 1204 μA, internal resistance RTEG = 11.3 Ohm, and a generated power output Pmax = 4.1 μW at ΔT = 100 K (with TCold = 70 °C). The approach and methodology described in this study aims to increase the flexibility of integration and additive manufacturing processes for advanced 3D-printed conceptual devices and the development of multifunctional materials.

Abstract Image

增材制造高导电性碳纳米管结构,实现碳基柔性热电发电机
要将电子器件的制造从传统的二维方向转移到三维空间,就必须使用复杂的增材制造工艺,这种工艺能够提供具有特殊空间分辨率的多功能材料和器件。本研究报告了喷嘴引导的高导电性、环氧树脂分散的石墨烯纳米管(GNT)结构的三维打印,这种结构具有嵌入式热电(TE)特性,能够利用环境中的大量废弃热能。为了通过限定的喷嘴几何形状实现基于石墨烯纳米管的浆料的高分辨率和连续打印,即不产生团聚和喷嘴堵塞,生产出了均匀的环氧树脂分散石墨烯纳米管浆料。因此,通过剪切混合工艺获得了各种具有高 GNT 浓度(10 wt %)的 3D 打印结构。三维打印的 p 型和 n 型环氧树脂分散 GNT 热电元件的功率因数分别高达 102 和 75 μW/mK2。制造出的三维碳基热电发生器(3D-CTEG)能够在温度高达 180 °C的环境条件(1 atm,相对湿度:50 ± 5% RH)下稳定工作,在 ΔΤ = 100 K(TCold=70°C)下获得开路电压 VOC = 13.6 mV、短路电流 ISC = 1204 μA、内阻 RTEG = 11.3 Ohm 和发电功率输出 PMAX = 4.1 μW 的 TE 值。本研究中描述的方法和方法论旨在提高先进 3D 打印概念设备的集成和增材制造工艺的灵活性,并开发多功能材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
1.80
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