Schlicke, HendrikHendrikSchlickeKunze, SvenjaSvenjaKunzeRebber, MatthiasMatthiasRebberSchulz, NorbertNorbertSchulzRiekeberg, SvenjaSvenjaRiekebergTrieu, Hoc KhiemHoc KhiemTrieuVossmeyer, TobiasTobiasVossmeyer2021-02-222021-02-222020-10-01Advanced Functional Materials 30 (40): 2003381 (2020-10-01)http://hdl.handle.net/11420/8895In this article, highly sensitive differential pressure sensors based on free-standing membranes of cross-linked gold nanoparticles are demonstrated. The nanoparticle membranes are employed as both diaphragms and resistive transducers. The elasticity and the pronounced resistive strain sensitivity of these nanometer-thin composites enable the fabrication of sensors achieving high sensitivities exceeding 10−3 mbar−1 while maintaining an overall small membrane area. Furthermore, by combining micro-bulge tests with atomic force microscopy and in situ resistance measurements the membranes’ electromechanical responses are studied through precise observation of the concomitant changes of the membranes’ topography. The study demonstrates the high potential of free-standing nanoparticle composites for the fabrication of highly sensitive force and pressure sensors and introduces a unique and powerful method for the electromechanical investigation of these materials.en1616-301XAdvanced functional materials2020402003381gold nanoparticlesMEMSnanoparticle compositesNEMSsensorsCross-Linked Gold Nanoparticle Composite Membranes as Highly Sensitive Pressure SensorsJournal Article10.1002/adfm.202003381Other