Metal-based folded-thermopile for 2.5D micro-thermoelectric generators

We report on the simulation and fabrication of 2.5D micro-thermoelectric generators (µTEGs) with a thermopile topology periodically folded and distributed on a multi-membrane template, capable of harvesting lost heat directly into useful electrical energy. The originality of the folded thermopile is...

Full description

Saved in:
Bibliographic Details
Published in:Sensors and actuators. A. Physical. 2023-01, Vol.349, p.114090, Article 114090
Main Authors: Bel-Hadj, Ibrahim, Bougrioua, Zahia, Ziouche, Katir
Format: Article
Language:English
Subjects:
CMOS-compatible technology
Electric power
Engineering Sciences
Membranes
Metallic thermoelectrics
Micro and nanotechnologies
Micro-thermoelectric generators
Microelectronics
Planar thermopile
Thermal modeling
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We report on the simulation and fabrication of 2.5D micro-thermoelectric generators (µTEGs) with a thermopile topology periodically folded and distributed on a multi-membrane template, capable of harvesting lost heat directly into useful electrical energy. The originality of the folded thermopile is multiple: i/ it uses low-cost and eco-friendly alloy-based thermoelectrics (TEs) in the form of a series of Ni90Cr10/Cu55Ni45 thermocouples (TCs), ii/ in each TC both TE layers are stacked on top of each other allowing a better integration, iii/ the TCs are electrically associated in series and in parallel, reducing drastically the electrical resistance, iv/ the choice of membrane number permits to tune the module thermal resistance. All this results in an improvement of the conversion efficiency of the µTEG compared to our former all-Silicon planar modules. A finite element simulation allows defining the temperature distribution profiles in the module as a function of its dimensions. Several 2- and 3-membranes based µTEGs were fabricated using CMOS-compatible Silicon technology and characterized. In the best µTEG, the harvesting of 1 Watt of heat results in an output power density of 108.3 µW/cm2. This corresponds to an efficiency factor of 6.82 10−3 µW.cm-².K-² which is better than state-of-the-art metal-based modules. [Display omitted] •Multi-membrane-based 2.5D µTEGs integrating a new kind of metal-based thermopile are modeled, fabricated and characterized.•The novel thermopile topology is periodically folded and is based on Ni90Cr10 and Cu55Ni45 thermoelectric layers.•The thermopile integrates a high density of thermocouples with a combined series and parallel electrical association.•In the 3-membranes based µTEG, a maximum output power density of 108.3 µW/cm2 is generated from 1 W heat to harvest.•Those 2.5D µTEGs have higher efficiency and thermal resistance than in the state of the art of metal based modules.
ISSN:0924-4247
1873-3069
DOI:10.1016/j.sna.2022.114090