Vincent Linseis scite author profile

The characterization of nanostructured samples with at least one restricted dimension like thin films or nanowires is challenging, but important to understand their structure and transport mechanism, and to improve current industrial products and production processes. We report on the 2nd generation of a measurement chip, which allows for a simplified sample preparation process, and the measurement of samples deposited from the liquid phase using techniques like spin coating and drop casting. The new design enables us to apply much higher temperature gradients for the Seebeck coefficient measurement in a shorter time, without influencing the sample holder's temperature distribution. Furthermore, a two membrane correction method for the 3ω thermal conductivity measurement will be presented, which takes the heat loss due to radiation into account and increases the accuracy of the measurement results significantly. Errors caused by different sample compositions, varying sample geometries, and different heat profiles are avoided with the presented measurement method. As a showcase study displaying the validity and accuracy of our platform, we present temperature-dependent measurements of the thermoelectric properties of an 84 nm BiSb thin film and a 15 μm PEDOT:PSS thin film.

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High Thermoelectric Performance in n‐Type Perylene Bisimide Induced by the Soret Effect

Jiang

Sun

Zhao

et al. 2020

Advanced Materials

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Low‐cost, non‐toxic, abundant organic thermoelectric materials are currently under investigation for use as potential alternatives for the production of electricity from waste heat. While organic conductors reach electrical conductivities as high as their inorganic counterparts, they suffer from an overall low thermoelectric figure of merit (ZT) due to their small Seebeck coefficient. Moreover, the lack of efficient n‐type organic materials still represents a major challenge when trying to fabricate efficient organic thermoelectric modules. Here, a novel strategy is proposed both to increase the Seebeck coefficient and achieve the highest thermoelectric efficiency for n‐type organic thermoelectrics to date. An organic mixed ion–electron n‐type conductor based on highly crystalline and reduced perylene bisimide is developed. Quasi‐frozen ionic carriers yield a large ionic Seebeck coefficient of −3021 μV K−1, while the electronic carriers dominate the electrical conductivity which is as high as 0.18 S cm−1 at 60% relative humidity. The overall power factor is remarkably high (165 μW m−1 K−2), with a ZT = 0.23 at room temperature. The resulting single leg thermoelectric generators display a high quasi‐constant power output. This work paves the way for the design and development of efficient organic thermoelectrics by the rational control of the mobility of the electronic and ionic carriers.

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High-quality textured SnSe thin films for self-powered, rapid-response photothermoelectric application

Zhong

Zhang

Linseis³

et al. 2020

Nano Energy

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Platform for in-planeZTmeasurement and Hall coefficient determination of thin films in a temperature range from 120 K up to 450 K

et al. 2016

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Thickness and temperature dependent thermoelectric properties of Bi₈₇Sb₁₃ nanofilms measured with a novel measurement platform

Linseis

Völklein

Reith

et al. 2018

Semicond. Sci. Technol.

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The temperature and thickness dependent thermoelectric properties of Bi 87 Sb 13 nano-films with a thickness from 84 nm to 282 nm have been studied in a temperature range from 110 K up to 450 K. The films have been prepared by thermal evaporation of the raw material from an Al 2 O 3 coated tungsten boat under vacuum conditions of at least 10 −6 mbar. The measurements have been performed using a novel measurement platform, which allows the nearly simultaneous characterization of the thermal conductivity, electrical conductivity, the Seebeck coefficient and the Hall coefficient. All properties are measured in the in-plane direction at the same sample within one measurement run, avoiding many sources of uncertainties and allowing the calculation of the direction dependent, in-plane thermoelectric figure of Merit ZT with high precision. The maximum ZT value of 0.28 has been obtained for the thickest sample at a temperature of 265 K. All comparative measurements have been performed after an initial thermal annealing step, as the heat treatment shows a strong impact on the thermoelectric performance of the films.

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Vincent Linseis

Advanced platform for the in-plane ZT measurement of thin films

High Thermoelectric Performance in n‐Type Perylene Bisimide Induced by the Soret Effect

High-quality textured SnSe thin films for self-powered, rapid-response photothermoelectric application

Platform for in-planeZTmeasurement and Hall coefficient determination of thin films in a temperature range from 120 K up to 450 K

Thickness and temperature dependent thermoelectric properties of Bi₈₇Sb₁₃ nanofilms measured with a novel measurement platform

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Resources

About

Vincent Linseis

Advanced platform for the in-plane ZT measurement of thin films

High Thermoelectric Performance in n‐Type Perylene Bisimide Induced by the Soret Effect

High-quality textured SnSe thin films for self-powered, rapid-response photothermoelectric application

Platform for in-planeZTmeasurement and Hall coefficient determination of thin films in a temperature range from 120 K up to 450 K

Thickness and temperature dependent thermoelectric properties of Bi87Sb13 nanofilms measured with a novel measurement platform

Contact Info

Product

Resources

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Thickness and temperature dependent thermoelectric properties of Bi₈₇Sb₁₃ nanofilms measured with a novel measurement platform