Turning Waste Heat into Power with Nanoribbon Tech - Enhancing Performance of Thermoelectrics

In advanced materials science, precise structural engineering at the nanoscale is very important to optimize the performance of ceramic composites in various applications, including electronics, thermal management, and especially thermoelectric materials. A fundamental challenge in this field is creating controlled asymmetric structures that optimize directional properties and functional efficiency.

A recent collaborative study, "Asymmetric structuring of ceramic composite via co-electrospun sodium cobaltite and calcium cobaltite nanoribbons," published in the Journal of the American Ceramic Society, represents a significant advancement toward overcoming this challenge. Researchers from the Institute of Physical Chemistry and Electrochemistry at Leibniz University Hannover (Germany) and the Wolfson Department of Chemical Engineering at the Technion–Israel Institute of Technology (Haifa, Israel) employed an innovative fabrication method called co-electrospinning. This advanced variation of electrospinning allowed for the precise preparation of composite nanoribbons consisting of sodium cobaltite (NaCo₂O₄) and calcium cobaltite (Ca₃Co₄O₉). The approach provided accurate control over ceramic microstructure and texturing, creating materials specifically tailored for improved thermoelectric performance.

Advanced Characterization with NETZSCH DSC and LFA: Key to Thermoelectric Performance

Our laboratory at NETZSCH Analyzing & Testing contributed specialized thermal analysis essential to this research. Specifically the in-plane and out-of-plane thermal conductivity (λ) was accurately determined based on the thermal diffusivity, measured using the NETZSCH LFA 467 HT HyperFlash, and the specific heat capacity values, obtained with the NETZSCH DSC 404 F1 Pegasus^®.

These measurements contributed to a comprehensive evaluation of the composite's thermal behavior.

The study demonstrated enhanced thermoelectric performance, with a power factor of 9.9 μW/cm²K² and a ZT value of 0.49 at 1073 K, surpassing previously reported values for similar cobaltite-based materials. These improvements were linked to increased electrical conductivity enabled by optimized charge carrier properties within the nanostructured composite.

This research exemplifies how effective collaboration between academic institutions and specialized analytical laboratories can accelerate advancements in ceramic materials technology.

Read the full paper

Acknowledgments

We gratefully acknowledge the collaborative research contributions from the Institute of Physical Chemistry and Electrochemistry at Leibniz University Hannover (Germany) and the Wolfson Department of Chemical Engineering and the Nancy & Stephan Grand Technion Energy Program (GTEP) at Technion–Israel Institute of Technology (Haifa, Israel). We are proud to have supported this study by contributing our expertise and advanced instrumentation in the field of thermal analysis.

Learn more about NETZSCH DSC and LFA Instruments for High-Temperature Applications

DSC 500 Pegasus^®
Das Hochtemperatur-Differential-Scanning-Kalorimeter
- Temperaturbereich: von -150 °C bis 2000 °C
- Integrierte Massenflussregelung (MFC) für drei verschiedene Gase
- Optional mit Temperaturmodulation (TM-DSC)
LFA 717 High Temperature HyperFlash^®
Schnelle und berührungslose Bestimmung der TemperaturleitfähigkeitDie Temperaturleitfähigkeit (a mit der Einheit mm2/s) ist eine materialabhängige Stoffeigenschaft zur Charakterisierung des instationären Wärmetransports. Sie gibt an, wie schnell ein Material auf eine Temperaturänderung reagiert.Temperaturleitfähigkeit bis 1250 °C
- Langlebige Xenon-Lampe für den kostengünstigen Betrieb von Messungen bis zu 1250 °C
- Vakuumdichter Platinofen für Heizraten bis zu 50 K/min
- Mini-Röhrenöfen für unübertroffene Prüfgeschwindigkeit.

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