Stiffness, Metamaterial, Nonlinear system, Statistical physics and Classical mechanics are his primary areas of study. His work is dedicated to discovering how Stiffness, Modulus are connected with Lattice, Ceramic, Polymer, Finite element method and Parameter space and other disciplines. His Metamaterial research is multidisciplinary, incorporating perspectives in Acoustics, Mechanics, Instability, Structural engineering and Elastic modulus.
As part of the same scientific family, Dennis M. Kochmann usually focuses on Nonlinear system, concentrating on Bistability and intersecting with Elastic energy, Electronic engineering, Dissipative system and Pulse. The study incorporates disciplines such as Polygon mesh, Energy based, Microstructure and Dissipation in addition to Statistical physics. Dennis M. Kochmann interconnects Wave propagation, Hardening and Energy functional in the investigation of issues within Classical mechanics.
Dennis M. Kochmann mainly focuses on Finite element method, Composite material, Metamaterial, Stiffness and Classical mechanics. His Finite element method research is multidisciplinary, relying on both Mathematical analysis, Boundary value problem, Lattice and Homogenization. Many of his research projects under Composite material are closely connected to Negative stiffness with Negative stiffness, tying the diverse disciplines of science together.
The concepts of his Metamaterial study are interwoven with issues in Topology and Multistability, Nonlinear system. His research in Stiffness intersects with topics in Mechanical engineering, Modulus, Truss and Scaling. His study in Classical mechanics is interdisciplinary in nature, drawing from both Wave propagation, Linear elasticity, Dissipative system and Dissipation.
The scientist’s investigation covers issues in Metamaterial, Finite element method, Topology, Nonlinear system and Morphing. His Metamaterial study combines topics from a wide range of disciplines, such as Classical mechanics, Soft robotics, Dissipation, Stiffness and Bistability. His Stiffness research is multidisciplinary, incorporating elements of Mechanical engineering, Resilience, Curvature and Scaling.
In general Finite element method study, his work on Meshfree methods often relates to the realm of Microscale chemistry, thereby connecting several areas of interest. When carried out as part of a general Topology research project, his work on Space is frequently linked to work in Network topology, therefore connecting diverse disciplines of study. In his research on the topic of Nonlinear system, Kinematics and Beam is strongly related with Mathematical analysis.
Dennis M. Kochmann mainly investigates Metamaterial, Stiffness, Curvature, Damage tolerance and Topology. He combines subjects such as Space, Bistability and Nonlinear system with his study of Metamaterial. His studies in Stiffness integrate themes in fields like Parametrization, Spinodal, Inverse and Truss.
The various areas that he examines in his Curvature study include Mechanical engineering, Resilience and Scaling.
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Resilient 3D hierarchical architected metamaterials
Lucas R. Meza;Alex J. Zelhofer;Nigel Clarke;Arturo J. Mateos.
Proceedings of the National Academy of Sciences of the United States of America (2015)
Stable propagation of mechanical signals in soft media using stored elastic energy.
Jordan R. Raney;Neel Nadkarni;Chiara Daraio;Chiara Daraio;Dennis M. Kochmann.
Proceedings of the National Academy of Sciences of the United States of America (2016)
Composite Materials with Viscoelastic Stiffness Greater Than Diamond
T. Jaglinski;D. M. Kochmann;D. Stone;R. S. Lakes.
Reexamining the mechanical property space of three-dimensional lattice architectures
Lucas R. Meza;Gregory P. Phlipot;Carlos M. Portela;Alessandro Maggi.
Acta Materialia (2017)
Exploiting Microstructural Instabilities in Solids and Structures: From Metamaterials to Structural Transitions
Dennis M. Kochmann;Katia Bertoldi.
Applied Mechanics Reviews (2017)
Dynamics of periodic mechanical structures containing bistable elastic elements: From elastic to solitary wave propagation
Neel Nadkarni;Chiara Daraio;Chiara Daraio;Dennis M. Kochmann.
Physical Review E (2014)
Unidirectional Transition Waves in Bistable Lattices.
Neel Nadkarni;Andres F. Arrieta;Andres F. Arrieta;Christopher Chong;Christopher Chong;Dennis M. Kochmann.
Physical Review Letters (2016)
Electrochemically reconfigurable architected materials.
Xiaoxing Xia;Arman Afshar;Heng Yang;Carlos M. Portela.
3D Auxetic Microlattices with Independently Controllable Acoustic Band Gaps and Quasi‐Static Elastic Moduli
Sebastian Krödel;Tommaso Delpero;Andrea Bergamini;Paolo Ermanni.
Advanced Engineering Materials (2014)
Guided transition waves in multistable mechanical metamaterials.
Lishuai Jin;Lishuai Jin;Romik Khajehtourian;Jochen Mueller;Jochen Mueller;Ahmad Rafsanjani;Ahmad Rafsanjani.
Proceedings of the National Academy of Sciences of the United States of America (2020)
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