Michael R. Haberman
Michael R. Haberman
Assistant Professor, Department of Mechanical Engineering, The University of Texas at Austin
Bestätigte E-Mail-Adresse bei utexas.edu - Startseite
Zitiert von
Zitiert von
Sound isolation and giant linear nonreciprocity in a compact acoustic circulator
R Fleury, DL Sounas, CF Sieck, MR Haberman, A Alù
Science 343 (6170), 516-519, 2014
Negative stiffness honeycombs for recoverable shock isolation
DM Correa, T Klatt, S Cortes, M Haberman, D Kovar, C Seepersad
Rapid Prototyping Journal, 2015
Analytical and experimental investigation of buckled beams as negative stiffness elements for passive vibration and shock isolation systems
BA Fulcher, DW Shahan, MR Haberman, C Conner Seepersad, ...
Journal of Vibration and Acoustics 136 (3), 2014
Nonreciprocal acoustics
R Fleury, D Sounas, MR Haberman, A Alu
Acoustics Today 11 (ARTICLE), 14-21, 2015
Acoustic metamaterials
MR Haberman, MD Guild
Phys. Today 69 (6), 42-48, 2016
Design, fabrication, and evaluation of negative stiffness elements using SLS
L Kashdan, CC Seepersad, M Haberman, PS Wilson
Rapid Prototyping Journal, 2012
Cancellation of acoustic scattering from an elastic sphere
MD Guild, A Alù, MR Haberman
The Journal of the Acoustical Society of America 129 (3), 1355-1365, 2011
Non-reciprocal wave propagation in modulated elastic metamaterials
H Nassar, H Chen, AN Norris, MR Haberman, GL Huang
Proceedings of the Royal Society A: Mathematical, Physical and Engineering …, 2017
Mechanical design of negative stiffness honeycomb materials
DM Correa, CC Seepersad, MR Haberman
Integrating Materials and Manufacturing Innovation 4 (1), 10, 2015
A nonlinear negative stiffness metamaterial unit cell and small-on-large multiscale material model
T Klatt, MR Haberman
Journal of Applied Physics 114 (3), 033503, 2013
Plasmonic cloaking and scattering cancelation for electromagnetic and acoustic waves
MD Guild, MR Haberman, A Alù
Wave Motion 48 (6), 468-482, 2011
Experimental evidence of Willis coupling in a one-dimensional effective material element
MB Muhlestein, CF Sieck, PS Wilson, MR Haberman
Nature communications 8 (1), 1-9, 2017
Micromechanical modeling of viscoelastic voided composites in the low-frequency approximation
MR Haberman, YH Berthelot, J Jarzynski, M Cherkaoui
The Journal of the Acoustical Society of America 112 (5), 1937-1943, 2002
Plasmonic-type acoustic cloak made of a bilaminate shell
MD Guild, MR Haberman, A Alù
Physical Review B 86 (10), 104302, 2012
Origins of Willis coupling and acoustic bianisotropy in acoustic metamaterials through source-driven homogenization
CF Sieck, A Alù, MR Haberman
Physical Review B 96 (10), 104303, 2017
Use of parabolic reflector to amplify in-air signals generated during impact-echo testing
X Dai, J Zhu, YT Tsai, MR Haberman
The Journal of the Acoustical Society of America 130 (4), EL167-EL172, 2011
Design of high loss viscoelastic composites through micromechanical modeling and decision based materials design
MR Haberman
Georgia Institute of Technology, 2007
Multiscale design of a rectangular sandwich plate with viscoelastic core and supported at extents by viscoelastic materials
Y Koutsawa, MR Haberman, M Cherkaoui
International Journal of Mechanics and Materials in Design 5 (1), 29-44, 2009
Hierarchical design of negative stiffness metamaterials using a bayesian network classifier
J Matthews, T Klatt, C Morris, CC Seepersad, M Haberman, D Shahan
Journal of Mechanical Design 138 (4), 2016
A differential effective medium model for piezoelectret foams
MR Haberman, YH Berthelot
Journal of Applied Physics 102 (12), 124903, 2007
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