862 Works

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.007 mN (thirty-first nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.006 mN (nineteenth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.006 mN (twentieth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.006 mN (twenty-third nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.007 mN (forty-first nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.008 mN (nineteenth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.006 mN (thirty-seventh nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.008 mN (twentieth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.007 mN (fifty-fifth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.006 mN (forty-fifth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.008 mN (twenty-eighth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.005 mN (ninth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.007 mN (sixty-first nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe-9Cr) material at 23 °C and maximum indenter force of 10.006 mN (fiftieth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 20.015 mN

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 20.013 mN

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 8.009 mN

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 8.006 mN (third nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 8.007 mN (fourth nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 50.017 mN (first nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 20.01 mN (first nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 100.023 mN

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Nanoindentation (single cycle) test data for Model Alloy (Fe) material at 23 °C and maximum indenter force of 100.02 mN (first nominally repeat test)

AM Ruiz Moreno &
Data created at the European Commission JRC during the H2020 project on multiscale modeling for fusion and fission materials (M4F), funded from the Euratom research and training programme 2014-2018 under grant agreement No. 755039.

Uniaxial tensile test data for ALLOY 182 wm material at 288 °C (seventh nominally repeat test)

S. Ritter &
Data collection created at JRC and SCK CEN in the scope of the NUGENIA Data created at PSI, Switzerland in the scope of the NUGENIA MICRIN/MICRIN+ projects on the development of an accelerated test method for stress corrosion cracking initiation. The work was concerned with SSRT/SCCI screening tests on tapered tensile specimens (both flat and cylindrical) to determine the SCCI threshold stress. The material investigated was Ni-based weld Alloy 182 and A078 high-Si stainless steel.

Uniaxial tensile test data for ALLOY 182 wm material at 288 °C (eighth nominally repeat test)

S. Ritter &
Data collection created at JRC and SCK CEN in the scope of the NUGENIA Data created at PSI, Switzerland in the scope of the NUGENIA MICRIN/MICRIN+ projects on the development of an accelerated test method for stress corrosion cracking initiation. The work was concerned with SSRT/SCCI screening tests on tapered tensile specimens (both flat and cylindrical) to determine the SCCI threshold stress. The material investigated was Ni-based weld Alloy 182 and A078 high-Si stainless steel.

Registration Year

  • 2020
    862

Resource Types

  • Dataset
    862