Add to ORKGThe recent interest in size-dependent deformation of micro- and nanoscale materials has paralleled both technological miniaturization and advancements in imaging and small-scale mechanical testing methods. Here we describe a quantitative in situ nanomechanical testing approach adapted to a dualbeam focused ion beam and scanning electron microscope. A transducer based on a three-plate capacitor system is used for high-fidelity force and displacement measurements. Specimen manipulation, transfer, and alignment are performed using a manipulator, independently controlled positioners, and the focused ion beam. Gripping of specimens is achieved using electron-beam assisted Pt-organic deposition. Local strain measurements are obtained using digita...
In nanomechanics the measurement of ultrafine forces becomes increasingly important for unravelling ...
ABSTRACT It has been demonstrated that the mechanical properties of materials change significantly w...
The need to characterize nanometer-scale materials and structures has grown tremendously in the past...
The recent interest in size-dependent deformation of micro- and nanoscale materials has paralleled b...
Uniaxial quasi-static tensile testing on individual nanocrystalline Co nanowires (NWs), synthesized ...
The great effort is being placed in the design of new characterization techniques and the constructi...
The mechanical testing of micro-electro-mechanical systems (MEMS) and nano-electro-mechanical system...
In this work, we designed a micro-electromechanical systems (MEMS) device that allows simultaneous d...
This dissertation presents the development of the novel mechanical testing technique of in situ nan...
A unique method for quantitative in situ nanotensile testing in a transmission electron microscope e...
Probing mechanical properties in the micrometer regime is of current interest in materials science. ...
We have developed and tested the world’s smallest material testing system for the in situ mechanical...
This article reviews in situ mechanical testing of crystalline nanowires in scanning and transmissio...
Recently, the increasing importance and scope of nanotechnology has extended the need for high resol...
Three-point bending tests were performed on double-anchored, < 110 > silicon nanowire samples ...
In nanomechanics the measurement of ultrafine forces becomes increasingly important for unravelling ...
ABSTRACT It has been demonstrated that the mechanical properties of materials change significantly w...
The need to characterize nanometer-scale materials and structures has grown tremendously in the past...
The recent interest in size-dependent deformation of micro- and nanoscale materials has paralleled b...
Uniaxial quasi-static tensile testing on individual nanocrystalline Co nanowires (NWs), synthesized ...
The great effort is being placed in the design of new characterization techniques and the constructi...
The mechanical testing of micro-electro-mechanical systems (MEMS) and nano-electro-mechanical system...
In this work, we designed a micro-electromechanical systems (MEMS) device that allows simultaneous d...
This dissertation presents the development of the novel mechanical testing technique of in situ nan...
A unique method for quantitative in situ nanotensile testing in a transmission electron microscope e...
Probing mechanical properties in the micrometer regime is of current interest in materials science. ...
We have developed and tested the world’s smallest material testing system for the in situ mechanical...
This article reviews in situ mechanical testing of crystalline nanowires in scanning and transmissio...
Recently, the increasing importance and scope of nanotechnology has extended the need for high resol...
Three-point bending tests were performed on double-anchored, < 110 > silicon nanowire samples ...
In nanomechanics the measurement of ultrafine forces becomes increasingly important for unravelling ...
ABSTRACT It has been demonstrated that the mechanical properties of materials change significantly w...
The need to characterize nanometer-scale materials and structures has grown tremendously in the past...