The Science Behind Stronger, Smarter Materials | HackerNoonPolyethylene-based metamaterials enable advanced acoustic control using relaxed micromorphic modeling approaches.
The Role of Curl Terms in Micromorphic Models | HackerNoonThe paper presents an automated fitting procedure for relaxed micromorphic parameters in metamaterials, enhancing their modeling for acoustic applications.
How Symmetric and Skew-Symmetric Tensors Interact | HackerNoonPolyethylene-based metamaterials hold potential for advanced acoustic control applications.
Fine-Tuning Acoustic and Optical Waves in Metamaterials | HackerNoonThe article explores a polyethene-based metamaterial for acoustic control using relaxed micromorphic modeling and dispersion curve analysis.
Semi-Analytical Algorithm for Metamaterial Parameter Fitting | HackerNoonThe study emphasizes a fitting algorithm for relaxed micromorphic models over specific fitting results, highlighting material properties consistency.
The Science Behind Stronger, Smarter Materials | HackerNoonPolyethylene-based metamaterials enable advanced acoustic control using relaxed micromorphic modeling approaches.
The Role of Curl Terms in Micromorphic Models | HackerNoonThe paper presents an automated fitting procedure for relaxed micromorphic parameters in metamaterials, enhancing their modeling for acoustic applications.
How Symmetric and Skew-Symmetric Tensors Interact | HackerNoonPolyethylene-based metamaterials hold potential for advanced acoustic control applications.
Fine-Tuning Acoustic and Optical Waves in Metamaterials | HackerNoonThe article explores a polyethene-based metamaterial for acoustic control using relaxed micromorphic modeling and dispersion curve analysis.
Semi-Analytical Algorithm for Metamaterial Parameter Fitting | HackerNoonThe study emphasizes a fitting algorithm for relaxed micromorphic models over specific fitting results, highlighting material properties consistency.
A New Method for Predicting How Waves Move Through Materials | HackerNoonThe relaxed micromorphic model provides a framework for simplifying the analysis of acoustic metamaterials through Fourier-based methods.
Scientists Figured Out How to Recycle Plastic by Vaporizing ItA new recycling method for polypropylene and polyethylene may significantly reduce plastic waste by effectively breaking down tough polymer bonds.
Vaporizing plastics recycles them into nothing but gasNew UC Berkeley method efficiently recycles difficult-to-process plastics like polypropylene and polyethylene using economical catalysts.The recycling process converts polyolefins into gasses that can be reused to create new plastics.
Scientists Figured Out How to Recycle Plastic by Vaporizing ItA new recycling method for polypropylene and polyethylene may significantly reduce plastic waste by effectively breaking down tough polymer bonds.
Vaporizing plastics recycles them into nothing but gasNew UC Berkeley method efficiently recycles difficult-to-process plastics like polypropylene and polyethylene using economical catalysts.The recycling process converts polyolefins into gasses that can be reused to create new plastics.