Publications by authors named "Diego Perez-Morelo"
Thermal fluctuations often impose both fundamental and practical measurement limits on high-performance sensors, motivating the development of techniques that bypass the limitations imposed by thermal noise outside cryogenic environments. Here, we theoretically propose and experimentally demonstrate a measurement method that reduces the effective transducer temperature and improves the measurement precision of a dynamic impulse response signal. Thermal noise-limited, integrated cavity optomechanical atomic force microscopy probes are used in a photothermal-induced resonance measurement to demonstrate an effective temperature reduction by a factor of ≈25, i.
View Article and Find Full Text PDFThermal properties of materials are often determined by measuring thermalization processes; however, such measurements at the nanoscale are challenging because they require high sensitivity concurrently with high temporal and spatial resolutions. Here, we develop an optomechanical cantilever probe and customize an atomic force microscope with low detection noise ≈1 fm/Hz over a wide (>100 MHz) bandwidth that measures thermalization dynamics with ≈10 ns temporal resolution, ≈35 nm spatial resolution, and high sensitivity. This setup enables fast nanoimaging of thermal conductivity (η) and interfacial thermal conductance () with measurement throughputs ≈6000× faster than conventional macroscale-resolution time-domain thermoreflectance acquiring the full sample thermalization.
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- Many nonlinear systems exhibit eigenmodes with frequencies that depend on their amplitude, leading to strong interactions during internal resonances, which enable rapid energy exchange and complex dynamics in mechanical resonators.
- Recent experimental findings highlight the importance of persistent nonlinear phase-locked states at these internal resonances to understand the dynamic behavior of nonlinear systems with coupled eigenmodes.
- This research provides a comprehensive model that explains the dynamics, energy exchange, and relaxation pathways of resonators, suggesting implications for advancements across various fields like photonics and nanomechanics.
Advances in integrated photonics open up exciting opportunities for batch-fabricated optical sensors using high-quality-factor nanophotonic cavities to achieve ultrahigh sensitivities and bandwidths. The sensitivity improves with increasing optical power; however, localized absorption and heating within a micrometer-scale mode volume prominently distorts the cavity resonances and strongly couples the sensor response to thermal dynamics, limiting the sensitivity and hindering the measurement of broadband time-dependent signals. Here, we derive a frequency-dependent photonic sensor transfer function that accounts for thermo-optical dynamics and quantitatively describes the measured broadband optomechanical signal from an integrated photonic atomic force microscopy nanomechanical probe.
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- The study presents a new all-optical method for characterizing intrinsic losses in optical microresonators, specifically focusing on separating absorption and radiative losses.
- This technique relies solely on linear spectroscopy and an optically measured thermal time constant, demonstrating high accuracy.
- Results indicate that while total dissipation rates vary significantly, the small absorptive losses are effectively differentiated from dominant radiation losses, aligning with expected bulk material absorption values.
In this article, we present a nanoelectromechanical system (NEMS) designed to detect changes in the Casimir energy. The Casimir effect is a result of the appearance of quantum fluctuations in an electromagnetic vacuum. Previous experiments have used nano- or microscale parallel plate capacitors to detect the Casimir force by measuring the small attractive force these fluctuations exert between the two surfaces.
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