Research Featured on Cover of Journals

Invited Speaker

Colloquium 610 | Emerging Topics in Acoustic and Mechanical Metamaterials, 2022, Spain. 

ESMC 2022 | European Solid Mechanics Conference, 2022, Ireland.

Journal Articles

[1] Anastasiia O Krushynska et al. “Emerging topics in nanophononics and elastic, acoustic, and mechanical metamaterials: an overview”. In: Nanophotonics 12.4 (2023), pp. 659–686.

[2] David MJ Dykstra, Shahram Janbaz, and Corentin Coulais. “The extreme mechanics of viscoelastic metamaterials”. In: APL Materials 10.8 (2022), p. 080702.

[3] Mahya Ganjian et al. “Controlled metal crumpling as an alternative to folding for the fabrication of nanopatterned meta-biomaterials”. In: Materials & Design 220 (2022), p. 110844.

[4] Shahram Janbaz and Corentin Coulais. “Slow kinks in dissipative kirigami”. In: arXiv preprint arXiv:2211.11600 (2022).

[5] Shahram Janbaz et al. “3D printable strain rate-dependent machine-matter”. In: arXiv preprint arXiv:2206.15168 (2022).

[6] Teunis van Manen et al. “4D printing of reconfigurable metamaterials and devices”. In: Communications Materials 2.1 (2021), p. 56.

[7] Mehrshad Mehrpouya et al. “4D printing of shape memory polylactic acid (PLA)”. In: Polymer 230 (2021), p. 124080.

[8] Mohammad J Mirzaali et al. “Curvature Induced by Deflection in Thick Meta-Plates”. In: Advanced Materials 33.30 (2021), p. 2008082.

[9] FSL Bobbert et al. “Russian doll deployable meta-implants: Fusion of kirigami, origami, and multi-stability”. In: Materials & Design 191 (2020), p. 108624.

[10] S Janbaz et al. “Strain rate–dependent mechanical metamaterials”. In: Science Advances 6.25 (2020), eaba0616.

[11] Teunis van Manen et al. “Kirigami-enabled self-folding origami”. In: Materials Today 32 (2020), pp. 59–67.

[12] Mehrshad Mehrpouya et al. “Investigation on the functionality of thermoresponsive origami structures”. In: Advanced Engineering Materials 22.8 (2020), p. 2000296.

[13] MC Fokker, S Janbaz, and AA Zadpoor. “Crumpling of thin sheets as a basis for creating mechanical metamaterials”. In: RSC Advances 9.9 (2019), pp. 5174–5188.

[14] S Janbaz et al. “Ultra-programmable buckling-driven soft cellular mechanisms”. In: Materials Horizons 6.6 (2019), pp. 1138–1147.

[15] Sander Leeflang, Shahram Janbaz, and Amir A Zadpoor. “Metallic clay”. In: Additive Manufacturing 28 (2019), pp. 528–534.

[16] FSL Bobbert, S Janbaz, and AA Zadpoor. “Towards deployable meta-implants”. In: Journal of Materials Chemistry B 6.21 (2018), pp. 3449–3455.

[17] Shahram Janbaz, Molly McGuinness, and Amir A Zadpoor. “Multimaterial control of instability in soft mechanical metamaterials”. In: Physical Review Applied 9.6 (2018), p. 064013.

[18] Helena MA Kolken et al. “Rationally designed meta-implants: a combination of auxetic and conventional meta-biomaterials”. In: Materials Horizons 5.1 (2018), pp. 28–35.

[19] Teunis van Manen, Shahram Janbaz, and Amir A Zadpoor. “Programming the shape-shifting of flat soft matter”. In: Materials Today 21.2 (2018), pp. 144–163.

[20] MJ Mirzaali et al. “Length-scale dependency of biomimetic hard-soft composites”. In: Scientific Reports 8.1 (2018), p. 12052.

[21] MJ Mirzaali et al. “Multi-material 3D printed mechanical metamaterials: Rational design of elastic properties through spatial distribution of hard and soft phases”. In: Applied Physics Letters 113.24 (2018), p. 241903.

[22] MJ Mirzaali et al. “Shape-matching soft mechanical metamaterials”. In: Scientific Reports 8.1 (2018), p. 965.

[23] R Hedayati et al. “How does tissue regeneration influence the mechanical behavior of additively manufactured porous biomaterials?” In: Journal of the Mechanical Behavior of Biomedical Materials 65 (2017), pp. 831–841.

[24] Shahram Janbaz et al. “Origami lattices with free-form surface ornaments”. In: Science Advances 3.11 (2017), eaao1595.

[25] MJ Mirzaali et al. “Crumpling-based soft metamaterials: The effects of sheet pore size and porosity”. In: Scientific Reports 7.1 (2017), p. 13028.

[26] Teunis Van Manen, Shahram Janbaz, and Amir A Zadpoor. “Programming 2D/3D shape-shifting with hobbyist 3D printers”. In: Materials Horizons 4.6 (2017), pp. 1064–1069.

[27] Shahram Janbaz, Reza Hedayati, and AA Zadpoor. “Programming the shape-shifting of flat soft matter: from self-rolling/self-twisting materials to self-folding origami”. In: Materials Horizons 3.6 (2016), pp. 536–547.

[28] Shahram Janbaz, Harrie Weinans, and Amir A Zadpoor. “Geometry-based control of instability patterns in cellular soft matter”. In: RSC Advances 6.24 (2016), pp. 20431–20436.