Attempts to model the current through Schottky barrier diodes using the two fundamental mechanisms of thermionic emission and tunnelling are adversely impacted by defects and second order effects. This has led to the publication of countless different models to account for these effects, including some with non-physical parameters. Recently, we have developed silicon carbide Schottky barrier diodes that do not suffer from second order effects, such as excessive leakage, carrier generation and recombination, and non-uniform barrier height. In this paper, we derive the foundational current equations to establish clear links between the fundamental current mechanisms and the governing parameters. Comparing these equations with measured current–voltage characteristics, we show that the fundamental equations for tunnelling and thermionic emission can accurately model 4H silicon carbide Schottky barrier diodes over a large temperature and voltage range. Based on the obtained results, we discuss implications and misconceptions regarding barrier inhomogeneity, barrier height measurement, and reverse-bias temperature dependencies.
Inertial microfluidics is a promising approach for particle separation due to the superior advantages of high throughput, simplicity, precise manipulation and low cost. However, the current obstacle of inertial microfluidics in biological applications is the broad size distribution of biological microparticles. Most devices only work well for a narrow range of particle sizes. For focusing and separating a new set of particles, troublesome and time-consuming design, fabrication, testing and optimization procedures are needed. As such, it is of particular interest to design a microfluidic device that can be tuned and adjusted to separate particles of various sizes. This paper reports on the proof of concept for a stretchable microfluidic device that can control the length via a stretching platform. By changing the channel dimensions, the device can be adapted to different particle sizes and flow rate ratios. We successfully demonstrate this approach with the separation of a mixture of 10 and 15-μm particles. Stretching the device significantly improves the focusing and separation efficiency of the specific particle sizes. We also show that there is an optimum stretch length, which results in the best separation performance. The proof of concept reported here is the first step towards designing stretchable inertial microfluidic devices that can be implemented for a wide range of biological and medical applications.
Analysis of the switching losses in a power MOSFET is crucial for the design of efficient power electronic systems. Currently, the state-of-the-art technique is based on measured drain current and drain-to-source voltage during the switching intervals. However, this technique does not separate the switching power due to the resistance of the MOSFET channel and due to the parasitic capacitances. In this paper, we propose a measurement method to extract the power dissipation due to the parasitic capacitances of a MOSFET, providing useful information for device selection and for the design of efficient power electronic systems. The proposed method is demonstrated on a basic boost converter. The proposed method shows that the existing method underestimates the turn-On losses by 41% and overestimates the turn-Off losses by 35%. INDEX TERMS Channel current, current diversion phenomenon, COSS losses, efficiency, power losses, power MOSFET, switching losses.
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