In this paper, the phonon dispersion curves of several surface-based lattices are examined, and their energy transmission spectra, along with the corresponding bandgaps are identified. We demonstrate that these bandgaps may be controlled, or tuned, through the choice of cell type, cell size and volume fraction. Our results include two findings of high relevance to the designers of lattice structures: (i) network and matrix phase gyroid lattice structures develop bandgaps below 15 kHz while network diamond and matrix diamond lattices do not, and (ii) the bandwidth of a bandgap in the network phase gyroid lattice can be tuned by adjusting its volume fraction and cell size
This paper reports a comprehensive modeling and experimental characterization of a three-dimensional...
In the field of phononics, periodic patterning controls vibrations and thereby the flow of heat and ...
The development of custom cellular materials has been driven by recent advances in additive manufact...
In this paper, the phonon dispersion curves of several surface-based lattices are examined, and thei...
We report on numerical modelling of three-dimensional lattice structures designed to provide phononi...
Vibrations are undesirable and cause many problems in engineering. Among the many techniques to redu...
Because of their outstanding characteristics, micro/nano-mechanical (MM) structures have found a ple...
Phononic crystals and acoustic metamaterials are heterogeneous materials that enable manipulation of...
This research was supported by the Undergraduate Research Opportunities Program (UROP)
Engineering the architecture of materials is a new and very promising approach to obtain vibration i...
Bandgaps, or frequency ranges of forbidden wave propagation, are a hallmark of Phononic Crystals (Pn...
We discuss the simultaneous existence of phononic and photonic band gaps in two types of phononic cr...
Supersonic aircraft deal with turbulent conditions during flight. These turbulent conditions lead to...
The design and the combination of innovative metamaterials are attracting increasing interest in the...
In this paper, modified two-dimensional periodic lattice materials with local resonance phononic ban...
This paper reports a comprehensive modeling and experimental characterization of a three-dimensional...
In the field of phononics, periodic patterning controls vibrations and thereby the flow of heat and ...
The development of custom cellular materials has been driven by recent advances in additive manufact...
In this paper, the phonon dispersion curves of several surface-based lattices are examined, and thei...
We report on numerical modelling of three-dimensional lattice structures designed to provide phononi...
Vibrations are undesirable and cause many problems in engineering. Among the many techniques to redu...
Because of their outstanding characteristics, micro/nano-mechanical (MM) structures have found a ple...
Phononic crystals and acoustic metamaterials are heterogeneous materials that enable manipulation of...
This research was supported by the Undergraduate Research Opportunities Program (UROP)
Engineering the architecture of materials is a new and very promising approach to obtain vibration i...
Bandgaps, or frequency ranges of forbidden wave propagation, are a hallmark of Phononic Crystals (Pn...
We discuss the simultaneous existence of phononic and photonic band gaps in two types of phononic cr...
Supersonic aircraft deal with turbulent conditions during flight. These turbulent conditions lead to...
The design and the combination of innovative metamaterials are attracting increasing interest in the...
In this paper, modified two-dimensional periodic lattice materials with local resonance phononic ban...
This paper reports a comprehensive modeling and experimental characterization of a three-dimensional...
In the field of phononics, periodic patterning controls vibrations and thereby the flow of heat and ...
The development of custom cellular materials has been driven by recent advances in additive manufact...