Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials

NOVAK, Nejc ;REN, Zoran ;VESENJAK, Matej .
Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials. 
Articles in Press, [S.l.], v. 0, n.0, p. , june 2025. 
ISSN 0039-2480.
Available at: <https://www.sv-jme.eu/sl/article/integrated-design-simulation-and-experimental-validation-of-advanced-cellular-metamaterials/>. Date accessed: 25 aug. 2025. 
doi:http://dx.doi.org/.

Novak, N., Ren, Z., & Vesenjak, M.
(0).
Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials.
Articles in Press, 0(0), .
doi:http://dx.doi.org/

@article{.,
	author = {Nejc  Novak and Zoran  Ren and Matej  Vesenjak},
	title = {Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials},
	journal = {Articles in Press},
	volume = {0},
	number = {0},
	year = {0},
	keywords = {cellular structures; metamaterials; experimental testing; computational simulations; mechanical properties; },
	abstract = {Cellular metamaterials offer supreme properties for engineering, medicine, and defence, but their transition to industrial use faces design, fabrication, and characterisation challenges. This review bridges these gaps by surveying 20 years of advancements in cellular structures, from open-cell foams to triply periodic minimal surfaces (TPMS), presenting novel fabrication techniques (e.g., explosive compaction for UniPore structures) and demonstrating validated computational models for optimising graded auxetic and hybrid TPMS lattices. The study indicates that porosity and base material primarily govern energy absorption, with closed-cell foams and TPMS outperforming other geometries. Additive manufacturing enables spatially graded designs with tailored mechanical properties. This work accelerates the development of next-generation metamaterials for crash absorption, blast protection, and biomedical devices.},
	issn = {0039-2480},	pages = {},	doi = {},
	url = {https://www.sv-jme.eu/sl/article/integrated-design-simulation-and-experimental-validation-of-advanced-cellular-metamaterials/}
}

Novak, N.,Ren, Z.,Vesenjak, M.
0 June 0. Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials. Articles in Press. [Online] 0:0

%A Novak, Nejc 
%A Ren, Zoran 
%A Vesenjak, Matej 
%D 0
%T Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials
%B 0
%9 cellular structures; metamaterials; experimental testing; computational simulations; mechanical properties; 
%! Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials
%K cellular structures; metamaterials; experimental testing; computational simulations; mechanical properties; 
%X Cellular metamaterials offer supreme properties for engineering, medicine, and defence, but their transition to industrial use faces design, fabrication, and characterisation challenges. This review bridges these gaps by surveying 20 years of advancements in cellular structures, from open-cell foams to triply periodic minimal surfaces (TPMS), presenting novel fabrication techniques (e.g., explosive compaction for UniPore structures) and demonstrating validated computational models for optimising graded auxetic and hybrid TPMS lattices. The study indicates that porosity and base material primarily govern energy absorption, with closed-cell foams and TPMS outperforming other geometries. Additive manufacturing enables spatially graded designs with tailored mechanical properties. This work accelerates the development of next-generation metamaterials for crash absorption, blast protection, and biomedical devices.
%U https://www.sv-jme.eu/sl/article/integrated-design-simulation-and-experimental-validation-of-advanced-cellular-metamaterials/
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%& 
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%N 0
%@ 0039-2480
%8 2025-06-09
%7 2025-06-09

Novak, Nejc, Zoran  Ren, & Matej  Vesenjak.
"Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials." Articles in Press [Online], 0.0 (0): . Web.  25 Aug. 2025

TY  - JOUR
AU  - Novak, Nejc 
AU  - Ren, Zoran 
AU  - Vesenjak, Matej 
PY  - 0
TI  - Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials
JF  - Articles in Press
DO  - 
KW  - cellular structures; metamaterials; experimental testing; computational simulations; mechanical properties; 
N2  - Cellular metamaterials offer supreme properties for engineering, medicine, and defence, but their transition to industrial use faces design, fabrication, and characterisation challenges. This review bridges these gaps by surveying 20 years of advancements in cellular structures, from open-cell foams to triply periodic minimal surfaces (TPMS), presenting novel fabrication techniques (e.g., explosive compaction for UniPore structures) and demonstrating validated computational models for optimising graded auxetic and hybrid TPMS lattices. The study indicates that porosity and base material primarily govern energy absorption, with closed-cell foams and TPMS outperforming other geometries. Additive manufacturing enables spatially graded designs with tailored mechanical properties. This work accelerates the development of next-generation metamaterials for crash absorption, blast protection, and biomedical devices.
UR  - https://www.sv-jme.eu/sl/article/integrated-design-simulation-and-experimental-validation-of-advanced-cellular-metamaterials/

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TY  - JOUR
AU  - Novak, Nejc 
AU  - Ren, Zoran 
AU  - Vesenjak, Matej 
PY  - 2025/06/09
TI  - Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials
JF  - Articles in Press; Vol 0, No 0 (0): Articles in Press
DO  - 
KW  - cellular structures, metamaterials, experimental testing, computational simulations, mechanical properties, 
N2  - Cellular metamaterials offer supreme properties for engineering, medicine, and defence, but their transition to industrial use faces design, fabrication, and characterisation challenges. This review bridges these gaps by surveying 20 years of advancements in cellular structures, from open-cell foams to triply periodic minimal surfaces (TPMS), presenting novel fabrication techniques (e.g., explosive compaction for UniPore structures) and demonstrating validated computational models for optimising graded auxetic and hybrid TPMS lattices. The study indicates that porosity and base material primarily govern energy absorption, with closed-cell foams and TPMS outperforming other geometries. Additive manufacturing enables spatially graded designs with tailored mechanical properties. This work accelerates the development of next-generation metamaterials for crash absorption, blast protection, and biomedical devices.
UR  - https://www.sv-jme.eu/sl/article/integrated-design-simulation-and-experimental-validation-of-advanced-cellular-metamaterials/

Novak, Nejc, Ren, Zoran, AND Vesenjak, Matej.
"Integrated Design, Simulation, and Experimental Validation of Advanced Cellular Metamaterials" Articles in Press [Online], Volume 0 Number 0 (09 June 2025)