: Advancing computational techniques, such as accelerated dispersion curve calculations , to efficiently model how waves move through complex, repeating patterns.
Cool’s research primarily involves the design and validation of innovative materials that exhibit unique acoustic properties. Key areas of her work include:
: Experimentally validating 2D sandwich panels designed through topology optimization to reduce noise in industrial and aerospace applications. Notable Publications
: Developing methods to design the layout of materials to achieve specific performance goals, such as maximizing modal effective mass or minimizing sound transmission.
She has contributed to several high-impact journals, including:
: Investigating structures that use internal resonances to create "bandgaps"—frequency ranges where sound or vibrations cannot propagate.
: Advancing computational techniques, such as accelerated dispersion curve calculations , to efficiently model how waves move through complex, repeating patterns.
Cool’s research primarily involves the design and validation of innovative materials that exhibit unique acoustic properties. Key areas of her work include: vanessa cool
: Experimentally validating 2D sandwich panels designed through topology optimization to reduce noise in industrial and aerospace applications. Notable Publications : Advancing computational techniques
: Developing methods to design the layout of materials to achieve specific performance goals, such as maximizing modal effective mass or minimizing sound transmission. such as accelerated dispersion curve calculations
She has contributed to several high-impact journals, including:
: Investigating structures that use internal resonances to create "bandgaps"—frequency ranges where sound or vibrations cannot propagate.