Ferroelectric material hysteresis In COMSOL Multiphysics®

🌟 Course Title: Ferroelectric Material Hysteresis in COMSOL Multiphysics

Course Headline:

Unlock the Secrets of Ferroelectric Material Modelling with Advanced Comsol Simulations! 🧙‍♂️✨

Course Description:

Welcome to the COMSOL Multiphysics course on Ferroelectric Material Simulation. This is not just any ordinary course; it's designed to be concise and impactful. Dive deep into the fascinating world of ferroelectrics and master the art of simulating hysteresis curves using COMSOL Multiphysics, with real-world insights drawn from over 5000 students across 105 countries!

👨‍🏫 About the Instructor:

• Over 5000 students taught till 2021.
• 17 international publications (including in nature materials, Result in Physics, and Optical fiber technology) to his credit.
• Author of the best-selling COMSOL courses on Udemy.
• The course content is continuously updated based on student feedback, ensuring you get the most current and relevant information. 🚀📚

What You Will Learn:

This course will empower you with the knowledge and skills to:

• Simulate Ferroelectric Materials: Understand the fundamental principles behind simulating ferroelectrics in COMSOL.
• Create a Ferroelectric Model: Follow step-by-step instructions to set up your own ferroelectric model in COMSOL Multiphysics.
• Simulate the Hysteresis Curve: Learn how to accurately simulate the hysteresis curve of ferroelectric materials using the Jiles-Atherton model.
• Model Hysteresis Using Jiles-Atherton Model: Gain expertise in modelling hysteresis effects with this widely used ferroelectric model.
• Utilize Interdomain Coupling, Pinning Loss, etc.: Discover advanced techniques to incorporate interdomain coupling and pinning loss into your simulations for more accurate results.

Ferroelectricity Explained:

Ferroelectric materials are a type of dielectric that exhibit spontaneous electric polarization. This property can be reversed by an external electric field, much like how a magnet's poles can be reversed. The phenomenon is analogous to ferromagnetism and is a key area of study in the fields of physics and materials science.

In simple terms, when an electric field is not present, a ferroelectric material will have a spontaneous polarization. This means that within the material, regions called domains will have an electric charge separation, resulting in a net dipole moment. When an external electric field is applied, these domains can rotate and align with the field, which can be reversed by changing the direction of the field.

See You in the Course!

Join us on this educational journey where you will gain hands-on experience with COMSOL Multiphysics to model ferroelectric materials and understand hysteresis behavior. Whether you're a student, researcher, or engineering professional, this course will equip you with valuable skills for your career in the field of simulation-driven design. 🧮🚀

Let's embark on this exciting learning adventure together! Sign up now and start exploring the fascinating world of ferroelectric materials and their simulations using COMSOL Multiphysics.