Accelerated testing of gold based materials during hot switching cycles in a MEMS test platform
Accelerated testing of gold based materials during hot switching cycles in a MEMS test platform
This paper explores the endurance of electrical contacts cycled under hot switching conditions (4 Vdc, 10 - 300 mA) in a test platform designed to model a Micro-Electromechanical System (MEMS) switch. The test platform allows the control of critical parameters applicable to a MEMS device, including DC switching power, contact force and the displacement profile of the opening and closing actuator. The paper investigates the ability to use the system to predict the failure of the contact surfaces from a low number of hot-switching cycles (e.g. 1 million). The surfaces investigated include conventional metallic surfaces and a metallic surface supported by a soft underlayer that allows one of the metallic surfaces to deform under the application of an applied contact force. The paper reviews several endurance data sources to predict the limits of switching as a function of the switched power. These limits are then tested and are shown to be proven. This will allow the full investigation of switching materials for the application, with a low number of switching cycles used to predict the surface failure by increased contact resistance.
Bull, Thomas
f3f00de4-1bfa-42c4-b957-dbd95a1a9aa2
McBride, John
d9429c29-9361-4747-9ba3-376297cb8770
12 December 2025
Bull, Thomas
f3f00de4-1bfa-42c4-b957-dbd95a1a9aa2
McBride, John
d9429c29-9361-4747-9ba3-376297cb8770
Bull, Thomas and McBride, John
(2025)
Accelerated testing of gold based materials during hot switching cycles in a MEMS test platform.
In,
2025 IEEE 70th Holm Conference on Electrical Contacts (HLM).
(doi:10.1109/HLM51652.2025.11278374).
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Abstract
This paper explores the endurance of electrical contacts cycled under hot switching conditions (4 Vdc, 10 - 300 mA) in a test platform designed to model a Micro-Electromechanical System (MEMS) switch. The test platform allows the control of critical parameters applicable to a MEMS device, including DC switching power, contact force and the displacement profile of the opening and closing actuator. The paper investigates the ability to use the system to predict the failure of the contact surfaces from a low number of hot-switching cycles (e.g. 1 million). The surfaces investigated include conventional metallic surfaces and a metallic surface supported by a soft underlayer that allows one of the metallic surfaces to deform under the application of an applied contact force. The paper reviews several endurance data sources to predict the limits of switching as a function of the switched power. These limits are then tested and are shown to be proven. This will allow the full investigation of switching materials for the application, with a low number of switching cycles used to predict the surface failure by increased contact resistance.
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Published date: 12 December 2025
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Local EPrints ID: 510257
URI: http://eprints.soton.ac.uk/id/eprint/510257
PURE UUID: dfc70e68-b7e7-4e0f-b5f2-5f1fb362866f
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Date deposited: 24 Mar 2026 17:51
Last modified: 25 Mar 2026 03:06
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Author:
Thomas Bull
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