Your search keyword '"J. Provine"' showing total 3 results

1. New avenues for residual stress analysis in ultrathin atomic layer deposited free-standing membranes through release of micro-cantilevers

Author

S. Burgmann, M.J. Lid, H.J.D. Johnsen, N.P. Vedvik, B. Haugen, J. Provine, A.T.J. van Helvoort, and J. Torgersen

Subjects

Ultrathin membranes, FIB, Residual stress, Strain analysis, ALD, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

The fabrication of thinnest, yet undeformed membrane structures with nanometer resolution is a prerequisite for a variety of Microelectromechanical systems (MEMS). However, functionally relevant thin films are susceptible to growth-generated stress. To tune the performance and reach large aspect ratios, knowledge of the intrinsic material properties is indispensable. Here, we present a new method for stress evaluation through releasing defined micro-cantilever segments by focused ion beam (FIB) milling from a predefined free-standing membrane structure. Thereby, the cantilever segment is allowed to equilibrate to a stress-released state through measurable strain in the form of a resulting radius of curvature. This radius can be back-calculated to the residual stress state. The method was tested on a 20 nm and 50 nm thick tunnel-like ALD Image 1 membrane structure, revealing a significant amount of residual stress with 866 MPa and 6104 MPa, respectively. Complementary finite element analysis to estimate the stress distribution in the structure showed a 97% and 90% agreement in out-of-plane deflection for the 20 nm and 50 nm membranes, respectively. This work reveals the possibilities of releasing entire membrane segments from thin film membranes with a significant amount of residual stress and to use the resulting bending behavior for evaluating stress and strain by measuring their deformation.

Published

2024

2. Intrinsic Stress Analysis on Free Standing Ultrathin Membrane Structures Through Release of Microcantilevers

Author

Stephanie Birgit Burgmann, Markus Joakim Lid, Håkon J. D. Johnsen, Nils Petter Vedvik, Bjørn Haugen, J Provine, Antonius T. J. van Helvoort, and Jan Torgensen

Published

2023

3. New avenues for residual stress analysis in ultrathin atomic layer deposited free-standing membranes through release of micro-cantilevers.

Author

Burgmann S, Lid MJ, Johnsen HJD, Vedvik NP, Haugen B, Provine J, van Helvoort ATJ, and Torgersen J

Abstract

The fabrication of thinnest, yet undeformed membrane structures with nanometer resolution is a prerequisite for a variety of Microelectromechanical systems (MEMS). However, functionally relevant thin films are susceptible to growth-generated stress. To tune the performance and reach large aspect ratios, knowledge of the intrinsic material properties is indispensable. Here, we present a new method for stress evaluation through releasing defined micro-cantilever segments by focused ion beam (FIB) milling from a predefined free-standing membrane structure. Thereby, the cantilever segment is allowed to equilibrate to a stress-released state through measurable strain in the form of a resulting radius of curvature. This radius can be back-calculated to the residual stress state. The method was tested on a 20 nm and 50 nm thick tunnel-like ALD Image 1 membrane structure, revealing a significant amount of residual stress with 866 MPa and 6104 MPa, respectively. Complementary finite element analysis to estimate the stress distribution in the structure showed a 97% and 90% agreement in out-of-plane deflection for the 20 nm and 50 nm membranes, respectively. This work reveals the possibilities of releasing entire membrane segments from thin film membranes with a significant amount of residual stress and to use the resulting bending behavior for evaluating stress and strain by measuring their deformation., Competing Interests: The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Jan Torgersen reports financial support was provided by The Research Council of Norway., (© 2024 The Author(s).)

Published

2024