Elevated temperature, nano-mechanical testing in situ in the scanning electron microscope

A general nano-mechanical test platform capable of performing variable temperature and variable strain rate testing in situ in the scanning electron microscope is described. A variety of test geometries are possible in combination with focused ion beam machining or other fabrication techniques: inde...

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Veröffentlicht in:	Review of scientific instruments 2013-04, Vol.84 (4), p.045103-045103
Hauptverfasser:	Wheeler, J. M., Michler, J.
Format:	Artikel
Sprache:	eng
Schlagworte:	BRITTLE-DUCTILE TRANSITIONS INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY ION BEAMS MATERIALS SCIENCE PLASTICITY SCANNING ELECTRON MICROSCOPY TEMPERATURE DEPENDENCE TEMPERATURE MONITORING THERMAL CONDUCTIVITY
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container_title	Review of scientific instruments
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creator	Wheeler, J. M. Michler, J.
description	A general nano-mechanical test platform capable of performing variable temperature and variable strain rate testing in situ in the scanning electron microscope is described. A variety of test geometries are possible in combination with focused ion beam machining or other fabrication techniques: indentation, micro-compression, cantilever bending, and scratch testing. The system is intrinsically displacement-controlled, which allows it to function directly as a micro-scale thermomechanical test frame. Stable, elevated temperature indentation/micro-compression requires the indenter tip and the sample to be in thermal equilibrium to prevent thermal displacement drift due to thermal expansion. This is achieved through independent heating and temperature monitoring of both the indenter tip and sample. Furthermore, the apex temperature of the indenter tip is calibrated, which allows it to act as a referenced surface temperature probe during contact. A full description of the system is provided, and the effects of indenter geometry and of radiation on imaging conditions are discussed. The stabilization time and temperature distribution throughout the system as a function of temperature is characterized. The advantages of temperature monitoring and thermal calibration of the indenter tip are illustrated, which include the possibility of local thermal conductivity measurement. Finally, validation results using nanoindentation on fused silica and micro-compression of ⟨100⟩ silicon micro-pillars as a function of temperature up to 500 °C are presented, and procedures and considerations taken for these measurements are discussed. A brittle to ductile transition from fracture to splitting then plastic deformation is directly observed in the SEM for silicon as a function of temperature.
doi_str_mv	10.1063/1.4795829
format	Article
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M. ; Michler, J.</creator><creatorcontrib>Wheeler, J. M. ; Michler, J.</creatorcontrib><description>A general nano-mechanical test platform capable of performing variable temperature and variable strain rate testing in situ in the scanning electron microscope is described. A variety of test geometries are possible in combination with focused ion beam machining or other fabrication techniques: indentation, micro-compression, cantilever bending, and scratch testing. The system is intrinsically displacement-controlled, which allows it to function directly as a micro-scale thermomechanical test frame. Stable, elevated temperature indentation/micro-compression requires the indenter tip and the sample to be in thermal equilibrium to prevent thermal displacement drift due to thermal expansion. This is achieved through independent heating and temperature monitoring of both the indenter tip and sample. 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M.</creatorcontrib><creatorcontrib>Michler, J.</creatorcontrib><title>Elevated temperature, nano-mechanical testing in situ in the scanning electron microscope</title><title>Review of scientific instruments</title><addtitle>Rev Sci Instrum</addtitle><description>A general nano-mechanical test platform capable of performing variable temperature and variable strain rate testing in situ in the scanning electron microscope is described. A variety of test geometries are possible in combination with focused ion beam machining or other fabrication techniques: indentation, micro-compression, cantilever bending, and scratch testing. The system is intrinsically displacement-controlled, which allows it to function directly as a micro-scale thermomechanical test frame. Stable, elevated temperature indentation/micro-compression requires the indenter tip and the sample to be in thermal equilibrium to prevent thermal displacement drift due to thermal expansion. This is achieved through independent heating and temperature monitoring of both the indenter tip and sample. Furthermore, the apex temperature of the indenter tip is calibrated, which allows it to act as a referenced surface temperature probe during contact. A full description of the system is provided, and the effects of indenter geometry and of radiation on imaging conditions are discussed. The stabilization time and temperature distribution throughout the system as a function of temperature is characterized. The advantages of temperature monitoring and thermal calibration of the indenter tip are illustrated, which include the possibility of local thermal conductivity measurement. Finally, validation results using nanoindentation on fused silica and micro-compression of ⟨100⟩ silicon micro-pillars as a function of temperature up to 500 °C are presented, and procedures and considerations taken for these measurements are discussed. A brittle to ductile transition from fracture to splitting then plastic deformation is directly observed in the SEM for silicon as a function of temperature.</description><subject>BRITTLE-DUCTILE TRANSITIONS</subject><subject>INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY</subject><subject>ION BEAMS</subject><subject>MATERIALS SCIENCE</subject><subject>PLASTICITY</subject><subject>SCANNING ELECTRON MICROSCOPY</subject><subject>TEMPERATURE DEPENDENCE</subject><subject>TEMPERATURE MONITORING</subject><subject>THERMAL CONDUCTIVITY</subject><issn>0034-6748</issn><issn>1089-7623</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><recordid>eNp9kM1LHTEUxYO06NN24T8gA25q6djcfMzHsoi2BaEbXXQV8pI7mjKTTJOM0P_eDO_VruzdXLj3x-GcQ8gp0EugDf8Ml6LtZcf6A7IB2vV12zD-hmwo5aJuWtEdkeOUftEyEuCQHDHecMlYtyE_r0d80hltlXGaMeq8RPxUee1DPaF51N4ZPZZnys4_VM5XyeVl3fkRq2S09-sdRzQ5Bl9NzsSQTJjxHXk76DHh-_0-Ifc313dX3-rbH1-_X325rY3oRK5N32u5tT3axrbaDDgYYSzrBejtVjNpDbQwSNHIoWFMaOglZWAGzYGjtMhPyPlONxSLKhmXi20TvC-OFGNApQRWqA87ao7h91LSqMklg-OoPYYlKeCikxRY0xX0YoeuSVLEQc3RTTr-UUDV2rcCte-7sGd72WU7oX0h_xZcgI87YDWmswv-v2qvwk8h_gPVbAf-DHOvl1g</recordid><startdate>20130401</startdate><enddate>20130401</enddate><creator>Wheeler, J. 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M. ; Michler, J.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c484t-c99a5bd9ed6d7acfefc4cd2941abba25dc171f5465f6224a195021cfa313e5de3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2013</creationdate><topic>BRITTLE-DUCTILE TRANSITIONS</topic><topic>INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY</topic><topic>ION BEAMS</topic><topic>MATERIALS SCIENCE</topic><topic>PLASTICITY</topic><topic>SCANNING ELECTRON MICROSCOPY</topic><topic>TEMPERATURE DEPENDENCE</topic><topic>TEMPERATURE MONITORING</topic><topic>THERMAL CONDUCTIVITY</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Wheeler, J. M.</creatorcontrib><creatorcontrib>Michler, J.</creatorcontrib><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><collection>OSTI.GOV</collection><jtitle>Review of scientific instruments</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Wheeler, J. M.</au><au>Michler, J.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Elevated temperature, nano-mechanical testing in situ in the scanning electron microscope</atitle><jtitle>Review of scientific instruments</jtitle><addtitle>Rev Sci Instrum</addtitle><date>2013-04-01</date><risdate>2013</risdate><volume>84</volume><issue>4</issue><spage>045103</spage><epage>045103</epage><pages>045103-045103</pages><issn>0034-6748</issn><eissn>1089-7623</eissn><coden>RSINAK</coden><abstract>A general nano-mechanical test platform capable of performing variable temperature and variable strain rate testing in situ in the scanning electron microscope is described. A variety of test geometries are possible in combination with focused ion beam machining or other fabrication techniques: indentation, micro-compression, cantilever bending, and scratch testing. The system is intrinsically displacement-controlled, which allows it to function directly as a micro-scale thermomechanical test frame. Stable, elevated temperature indentation/micro-compression requires the indenter tip and the sample to be in thermal equilibrium to prevent thermal displacement drift due to thermal expansion. This is achieved through independent heating and temperature monitoring of both the indenter tip and sample. Furthermore, the apex temperature of the indenter tip is calibrated, which allows it to act as a referenced surface temperature probe during contact. A full description of the system is provided, and the effects of indenter geometry and of radiation on imaging conditions are discussed. The stabilization time and temperature distribution throughout the system as a function of temperature is characterized. The advantages of temperature monitoring and thermal calibration of the indenter tip are illustrated, which include the possibility of local thermal conductivity measurement. Finally, validation results using nanoindentation on fused silica and micro-compression of ⟨100⟩ silicon micro-pillars as a function of temperature up to 500 °C are presented, and procedures and considerations taken for these measurements are discussed. A brittle to ductile transition from fracture to splitting then plastic deformation is directly observed in the SEM for silicon as a function of temperature.</abstract><cop>United States</cop><pmid>23635228</pmid><doi>10.1063/1.4795829</doi><tpages>15</tpages><oa>free_for_read</oa></addata></record>
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subjects	BRITTLE-DUCTILE TRANSITIONS INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY ION BEAMS MATERIALS SCIENCE PLASTICITY SCANNING ELECTRON MICROSCOPY TEMPERATURE DEPENDENCE TEMPERATURE MONITORING THERMAL CONDUCTIVITY
title	Elevated temperature, nano-mechanical testing in situ in the scanning electron microscope
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