Introduction Radar Absorbing Materials (RAM) are engineered to mitigate the reflection of electromagnetic (EM) waves, particularly in radar frequencies, by absorbing incident energy and converting it into negligible heat. This property significantly reduces the radar cross-section (RCS) of an object, making it less detectable to radar systems. RAMs serve as a pivotal technology in modern […]
Introduction Surface Plasmon Resonance (SPR) sensors have emerged as powerful tools for label-free, real-time detection of biomolecular interactions. Their operational basis lies in monitoring shifts in the refractive index at a metal-dielectric interface, which correlates directly with molecular binding events occurring on the sensor’s surface. This capability has propelled SPR sensors into critical roles across […]
Introduction Electronic Design Automation (EDA) simulations have become a fundamental pillar in modern electronics and semiconductor design. As electronic systems grow in complexity, the need for tools that can manage, validate, and optimize intricate circuit layouts and chip architectures has become paramount. At its core, EDA simulation refers to the use of computational models to […]
Introduction Semiconductor simulation represents a fundamental shift in how electronic devices are conceived, designed, and validated. As devices shrink to nanometer scales and integrate multifaceted physical phenomena, the use of software like COMSOL Multiphysics—specifically its Semiconductor Module—has become indispensable. Semiconductor simulation entails the numerical solution of complex physical equations to predict how devices will behave […]
Introduction Semiconductor simulation refers to the computational modeling of semiconductor devices and fabrication processes. These simulations span a vast landscape—from electron transport and thermal diffusion at the nanoscale to large-scale design rule verification—enabling engineers to analyze, predict, and optimize device behavior long before physical fabrication begins. As Moore’s Law continues to approach its physical limits, […]
Introduction The demand for ultra-high bandwidth, energy-efficient data transmission has pushed traditional electrical interconnects to their limits. As computational workloads scale exponentially—particularly within artificial intelligence (AI), high-performance computing (HPC), and data-intensive applications—optical communication links have emerged as a transformative alternative. Photonic interconnects use photons instead of electrons to transfer data, promising to alleviate latency and […]
Introduction As the semiconductor industry scales toward increasingly compact, complex, and energy-efficient devices, simulation has become a foundational component of modern electronic design workflows. Semiconductor simulation refers to the use of computational tools to model, analyze, and predict the behavior of semiconductor devices and fabrication processes. These simulations are critical to reducing design cycles, minimizing […]
A PN junction is the fundamental building block of nearly every modern semiconductor device, including diodes, transistors, solar cells, and LEDs. In this blog post, we’ll walk through the key physics behind the PN junction and show how to simulate it in COMSOL Multiphysics using the Semiconductor Module. We’ll also derive relevant equations and compare […]
Introduction Photonic Crystal Fibers (PCFs) have emerged as one of the most transformative innovations in the field of optical communications. Distinguished by their unique internal microstructure—typically an arrangement of air holes running longitudinally through the fiber—PCFs offer distinct advantages over traditional step-index or graded-index fibers. Their ability to confine light through mechanisms such as index […]
Introduction Orbital angular momentum (OAM) modes have emerged as a promising candidate for dramatically expanding the information-carrying capacity of optical fibers. Unlike conventional modes that carry only spin angular momentum, OAM modes possess a helical phase front characterized by an azimuthal phase dependence of the form $\exp(i\ell\phi)$, where $\ell$ is the topological charge and $\phi$ […]
