This letter reports the development of an integrated optoelectronic sensor for refractive index (RI) measurement, based on a zinc oxide metal–semiconductor–metal photodetector with electrohydrodynamic (EHD)-printed interdigitated electrodes and a polydimethylsiloxane (PDMS) waveguide placed on the sensor surface. The sensor detects variations in photocurrent caused by changes in the evanescent field of the PDMS waveguide when an analyte is deposited on it. A higher analyte RI results in decreased photocurrent. This work reports a promising application of conventional ultraviolet photodetectors for RI sensing. The use of scalable techniques, such as EHD printing and sputtering, together with direct integration of the PDMS waveguide, highlights the potential of the device as a compact and versatile sensing platform.

Acoustofluidics enables contact-free manipulation of particles in fluids using acoustic forces, making it ideal for handling biological samples without labeling or surface modification. While bulk acoustic wave (BAW) devices typically rely on transducer thickness modes, this work demonstrates high-performance particle manipulation using lateral width modes. Our silicon-glass-based microfluidic device, coupled to a piezoelectric transducer in an antisymmetric lateral mode, achieves acoustic energy densities up to 3000 J/m3—comparable to leading thickness-mode systems. This work demonstrates the two key applications, first, direct hematocrit determination by focusing red blood cells in whole blood, enabling optical analysis without centrifugation, and second, flow-through separation of particles and cells at rates up to 9 mL/min. The efficient particle focusing and separation performance confirm that lateral transducer modes are a powerful alternative in acoustofluidics. This approach broadens the design space for lab-on-chip systems targeting label-free diagnostics and sample preparation.

Capacitive resonator performance, including sensitivity, is determined by its capacitive change and resonant frequency shift in response to an external perturbation, such as added mass. Conventional designs are inherently defined by fully clamped boundaries around the deflectable plate. However, recent advances suggest that bilateral and quadrilateral concentric boundary resonators can offer improved performance through enhanced deflection compared to conventional fully clamped resonators. This letter analyzes how the spatial distribution of clamped boundaries under identical total clamped angles affects key resonator metrics, including sensitivity, which is manifested through a change in capacitance and frequency shift in electrical characterization. Resonators with bilateral and quadrilateral clamped boundary configurations are the focus of this letter to demonstrate the idea. In order to do this, resonators with total clamped angles of 120°, 180°, and 240° are fabricated and characterized using electrical impedance analysis, with results in agreement with the conducted finite element analysis. The quadrilateral configurations outperformed bilateral ones in both frequency shift and capacitance change, indicating that the clamped boundary distribution serves as a critical design parameter. These findings offer new insight into structural optimization strategies for capacitive resonators beyond conventional clamping schemes.

This letter proposes a fiber-optic-based method for monitoring the temperature of stator windings and housing regions in electric submersible pump (ESP) motors using Raman distributed temperature sensing (RDTS). The experimental setup replicates conditions of downhole installations or subsea skids by enclosing the ESP within an unplasticized polyvinyl chloride pipe, with annular flow established between the motor housing and the inner wall of the pipe. Flow rate and electric parameters are continuously monitored to evaluate their relationship with motor temperature. The results indicate that RDTS can be an intrinsically safe solution for temperature monitoring in ESP-lifted wells for oil and gas production, where conventional electric-based sensors are often unsuitable due to limited installation space, harsh environment, high electromagnetic interference, and long distance between the ESP motor and platform.

The detection of hazardous volatile organic compounds, particularly benzene, toluene, ethylbenzene, and xylene (BTEX), is crucial due to their carcinogenic nature and contribution to environmental pollution. Conventional gas sensors often suffer from high operating temperatures, poor sensitivity and selectivity, and slow response times. To address these limitations, composition-tunable MoSe2–WSe2 heterostructures were synthesized via a facile liquid-phase exfoliation (LPE) technique for room-temperature BTEX sensing applications. A comparative investigation was conducted between two distinct compositional ratios: MoSe2:WSe2 = 3:1 (n-type dominant) and 1:3 (p-type dominant), to elucidate the role of composition on electrical and sensing behavior. The structural, morphological, and optical properties of the synthesized composites were comprehensively characterized using Raman spectroscopy, FESEM, EDX, XRD, and UV–Vis spectroscopy. The 3:1 sample exhibited dominant MoSe2 Raman features with an estimated bandgap of 1.78 eV, whereas the 1:3 sample showed dominant WSe2 features with a bandgap of 1.47 eV. Elemental analysis further validated the targeted Mo:W atomic ratios, closely matching the intended 3:1 and 1:3 compositions. Electrical measurements demonstrated a maximum sensor response of 25.74% toward benzene, with a rapid response time of 30 s at a gas concentration of 50 ppm for MoSe2–WSe2 composite (1:3). This study provides the first detailed report on composition-dependent BTEX sensing performance of MoSe2–WSe2 heterostructures synthesized via LPE. The findings highlight the critical influence of n-/p-type dominance tuning for achieving gas-specific selectivity, offering promising pathways for the development of next-generation, room-temperature, 2D-material-based gas sensors with tailored sensitivity profiles.