Significant tuning of internal mode coupling in doubly clamped MEMS beam resonators by thermal effect

Intermodal coupling has been demonstrated to be a promising mechanism for the development of advanced micro/nanoelectromechanical devices. However, strong mode coupling remains a key challenge limiting the practical application of intermodal coupling. Furthermore, the insight into physical mechanisms underlying mode coupling and the capability to quantitatively tune the mode coupling is also limited. Here, we experimentally and theoretically demonstrate the significant tunability of mode coupling by using the thermal tuning effect, yet in an asymmetric doubly-clamped MEMS beam resonator, enabling various coupling strength to be implemented for practical applications. In this system, two out-of-plane vibrational modes are mechanically coupled through displacement-induced tension, and their mode coupling strength arises from both hardening and softening nonlinearities of the two modes, thus allowing for the tuning of mode coupling strength by thermally enhancing the softening nonlinearity of the MEMS beam. Our results demonstrate a feasible approach to tune the mode coupling and offer insights into fundamental mechanism of mode coupling in MEMS beam resonators, paving the way for the development of MEMS resonators with enhanced performance and application-specific tunability.