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New ultra-high temperature nanoindentation system for operating at up to 1100 °C

Minnert, Christian ; Oliver, Warren C. ; Durst, Karsten (2020)
New ultra-high temperature nanoindentation system for operating at up to 1100 °C.
In: Materials & Design, 2020, 192
doi: 10.25534/tuprints-00013342
Article, Secondary publication, Publisher's Version

Copyright Information: CC BY-NC-ND 4.0 International - Creative Commons, Attribution NonCommercial, NoDerivs.

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Item Type: Article
Type of entry: Secondary publication
Title: New ultra-high temperature nanoindentation system for operating at up to 1100 °C
Language: English
Date: 2020
Year of primary publication: 2020
Publisher: Elsevier
Journal or Publication Title: Materials & Design
Volume of the journal: 192
DOI: 10.25534/tuprints-00013342
URL / URN: https://doi.org/10.1016/j.matdes.2020.108727
Origin: Secondary publication via sponsored Golden Open Access

In this work a new ultra-high temperature (UHT) nanoindentation system for testing at up to 1100 °C is presented. The system is capable to perform indents fromsmall scale up to large indentation depths due to the combination of a 1 N actuator and a frame stiffness of N1 � 106 N� m even at 1100 °C. Dynamic testing allows a continuous determination of the contact stiffness (CSM) and thus also the depth-dependent hardness and indentation modulus. Low drift rates can be achieved by an independent tip and sample heating. Operating the nanoindenter inside a scanning electron microscope (SEM) equipped with a high temperature backscattered electron (BSE) detector opens the possibility of in-situ observations, as high vacuumminimizes oxidation effects. The HT capability of the systemis demonstrated on three reference materials: fused silica,molybdenumassessing the change in modulus with increasing temperature using constant strain rate tests (CSR). The creep response of single crystalline Ni has been assessed by strain rate jump (SRJ) as well as a step-load and hold creep (SLH) method. The resulting modulus, hardness as well as the strain rate sensitivity from RT up to 1100 °C are in good accordance with literature data, highlighting the applicability of the system.

Status: Publisher's Version
URN: urn:nbn:de:tuda-tuprints-133422
Classification DDC: 600 Technology, medicine, applied sciences > 620 Engineering and machine engineering
Divisions: 11 Department of Materials and Earth Sciences > Material Science > Physical Metallurgy
Zentrale Einrichtungen > University and State Library Darmstadt (ULB)
Date Deposited: 21 Aug 2020 09:06
Last Modified: 21 Aug 2020 09:07
URI: https://tuprints.ulb.tu-darmstadt.de/id/eprint/13342
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