Phonons, the quasi-particles of sound waves represent an indispensable resource in modern communication technologies because of their universal coupling to literally any other system. Moreover, phonons propagate with moderate velocities which are approximately 100000-times slower than the speed of light. This enables miniaturization of gigahertz frequency devices to the size of a chip. Magnetic systems exhibit spin-wave excitations in exactly the same frequency domain and, thus, are ideally suited to couple to sound waves via magnetostriction.In this project, we develop highly integrated programmable and scalable circuits, in which the propagation of phonons can be manipulated and even programmed by precisely engineered magnetic thin films and patterns. To this end, we bundle our complementary theoretical and experimental expertise and develop a complete toolbox of circuit elements for the design of integrated magneto-phononic circuits. This project addresses three major objective and research questions which are crucial for the fundamental understanding and for applications:(1) Development of theoretical and experimental methods to model, design and fabricate magneto-phononic integrated circuits. To this end, we will (i) unify modelling methods for magnetic and phononic systems on a common platform, (ii) combine nanofabrication techniques of phononic circuits and magnetic thin films, and (iii) validate the designed and fabricated magneto-phononic circuits by radio frequency spectroscopy.(2) Investigation of the magneto-phononic coupling between magnetic thin film systems and dispersion-engineered phononic waveguides.(3) Realization of integrated and programmable prototype devices employing magnetic arrays, e.g. for isolators and circulators radio frequency applications.At each stage of the project, new theoretical approaches and experimental techniques will be developed, which not only address important fundamental questions. Moreover, it lays the foundation for novel magneto-phononic circuits and their vast potential promise even more far-reaching applications in combination with for instance optically addressable spin systems or quantum emitters.

DFG Programme Research Grants

International Connection Austria

Partner Organisation Fonds zur Förderung der wissenschaftlichen Forschung (FWF)

Cooperation Partner Privatdozent Dr. Claas Abert