A groundbreaking advancement in thermoelectric technology promises to revolutionize energy harvesting by converting waste heat directly into electricity with unprecedented efficiency. Researchers from Shanghai Jiao Tong University, the Shanghai Institute of Space Power Sources, and The University of Tokyo have engineered a segmented thermoelectric (TE) module that achieves a record peak energy conversion efficiency of 12.7%, heralding a new era for solid-state power generation.
Traditional thermoelectric modules struggle with performance across broad temperature gradients, as most single materials lose efficiency outside their optimal temperature ranges. Addressing this limitation, the team devised a segmented approach, combining materials tailored for specific temperature regimes within the same module. The module features p-type legs segmented with mid-to-high temperature optimized germanium telluride (GeTe) and low-temperature optimized bismuth-antimony telluride (BST), paired with n-type legs made of structurally refined skutterudite (Yb₀.₃Co₄Sb₁₂, SKD).
Through multiphysics finite element modeling, the researchers optimized the module’s architecture, determining three critical shape factors to maximize performance. The segmentation ratio, height-to-area ratio, and p- to n-leg area ratio were finely tuned to 0.35, 0.67 mm⁻¹, and 1.85 respectively. This strategic geometrical refinement ensures balanced thermal and electrical transport properties, enabling the module to operate optimally under a substantial temperature difference of 500 K.
A significant breakthrough came from integrating an ultrathin nickel foil at the interface between GeTe and BST segments. Remarkably, this nickel layer serves as a diffusion barrier, preventing elemental intermixing and ensuring structural integrity under high temperatures. Concurrently, it acts as a metallization layer that minimizes internal contact resistance, a common bottleneck in thermoelectric device performance.
Experimental validation demonstrated the module achieving a power output of approximately 0.43 watts at 500 K temperature differential. This equates to a power density of 0.35 W/cm² per module surface area and 143 W/kg per module weight. Notably, considering only the active TE material area, the effective power density soared to an impressive 1.51 W/cm², showcasing the module’s remarkable energy harvesting capability.
Compared to baseline unsegmented modules, the segmented design boosts power density and conversion efficiency by 35% and 21%, respectively. These enhancements underscore the transformative potential of broad-temperature leg segmentation combined with precise structural optimization.
This research opens avenues for more efficient industrial waste heat recovery systems and deep-space power sources, where reliability and performance across variable temperature spans are critical. The solid-state nature of thermoelectric modules also offers advantages in durability and absence of moving parts, positioning them as promising candidates for next-generation sustainable energy solutions.
The study appears in the journal ENGINEERING Energy, highlighting a pivotal step forward in thermoelectric materials science and device engineering.
Subject of Research: Thermoelectric energy conversion, solid-state energy harvesting, thermoelectric module design
Article Title: Achieving 12.7% energy conversion efficiency in segmented GeTe/BST-SKD thermoelectric modules via broad-temperature and structural optimizations
News Publication Date: 30-Jun-2026
Web References: DOI 10.1007/s11708-026-1081-1
Image Credits: Ge Fu, Shangchao Lin, Yang Liu, Yiling Duan, Yixuan Liu & Qilin Zhang
Keywords
Thermoelectric modules, waste heat recovery, segmented thermoelectrics, GeTe, Bi₂₋ₓSbₓTe₃, skutterudite, energy efficiency, power density, solid-state power generation



