We present here a design of the unit cell of a mechanical metamaterial based on the use of a tensegrity structural configuration with a metal rubber. Tensegrity combines the use of compression and tension-only elements, and allows the creation of structures with high rigidity per unit mass. Metal rubber is a multiscale porous metal material with high energy absorption and vibration damping capabilities under compressive load. The combination of the two structural and material concepts gives rise to a mechanical metamaterial with increased energy absorption and tuneable nonlinearity under quasi-static, vibration, and impact loading. We develop prototypes, models, and perform tests under static and dynamic loading conditions to assess the performance of this mechanical metamaterial.

1.
M.
Kadic
,
T.
Bückmann
,
N.
Stenger
,
M.
Thiel
, and
M.
Wegener
,
Appl. Phys. Lett.
100
(
19
),
191901
(
2012
).
2.
R.
Hedayati
,
A. M.
Leeflang
, and
A. A.
Zadpoor
,
Appl. Phys. Lett.
110
(
9
),
091905
(
2017
).
3.
Y.
Li
,
E.
Baker
,
T.
Reissman
,
C.
Sun
, and
W. K.
Liu
,
Appl. Phys. Lett.
111
(
25
),
251903
(
2017
).
4.
N.
Grima Joseph
,
M.
Luke
,
M.
Azzopardi Keith
, and
G.
Ruben
,
Adv. Mater.
28
(
2
),
385
(
2016
).
5.
M. J.
Mirzaali
,
R.
Hedayati
,
P.
Vena
,
L.
Vergani
,
M.
Strano
, and
A. A.
Zadpoor
,
Appl. Phys. Lett.
111
(
5
),
051903
(
2017
).
6.
X.
Wang
,
X.
Luo
,
H.
Zhao
, and
Z.
Huang
,
Appl. Phys. Lett.
112
(
2
),
021901
(
2018
).
7.
A. M.
Hewage Trishan
,
L.
Alderson Kim
,
A.
Andrew
, and
S.
Fabrizio
,
Adv. Mater.
28
(
46
),
10116
(
2016
).
8.
M.
Schaeffer
and
M.
Ruzzene
,
J. Appl. Phys.
117
(
19
),
194903
(
2015
).
9.
O.
Acher
,
M.
Ledieu
,
A.
Bardaine
, and
F.
Levassort
,
Appl. Phys. Lett.
93
(
3
),
032501
(
2008
).
10.
X.
Zhang
,
D.
Wu
,
C.
Sun
, and
X.
Zhang
,
Phys. Rev. B
76
(
8
),
085318
(
2007
).
11.
K.
Boba
,
M.
Bianchi
,
G.
McCombe
,
R.
Gatt
,
A. C.
Griffin
,
R. M.
Richardson
,
F.
Scarpa
,
I.
Hamerton
, and
J. N.
Grima
,
ACS Appl. Mater. Interfaces
8
(
31
),
20319
(
2016
).
12.
M. J.
Mirzaali
,
S.
Janbaz
,
M.
Strano
,
L.
Vergani
, and
A. A.
Zadpoor
,
Sci. Rep.
8
(
1
),
965
(
2018
).
13.
R.
Lakes
,
Appl. Phys. Lett.
90
(
22
),
221905
(
2007
).
14.
D.
Zhang
,
F.
Scarpa
,
Y.
Ma
,
K.
Boba
,
J.
Hong
, and
H.
Lu
,
Mater. Sci. Eng.: A
580
,
305
(
2013
).
15.
Y.
Ma
,
Q.
Zhang
,
D.
Zhang
,
F.
Scarpa
,
B.
Liu
, and
J.
Hong
,
Acta Mater.
96
,
89
(
2015
).
16.
M.
Yanhong
,
H.
Wenzhong
,
Z.
Dayi
,
Z.
Qicheng
, and
H.
Jie
,
Smart Mater. Struct.
25
(
9
),
095015
(
2016
).
17.
H.
Guo
,
T.
Qingbiao
,
J.
Guofeng
, and
L.
Qiuyan
,
Smart Mater. Struct.
23
(
9
),
095011
(
2014
).
18.
M.
Yanhong
,
S.
Fabrizio
,
Z.
Dayi
,
Z.
Bin
,
C.
Lulu
, and
H.
Jie
,
Smart Mater. Struct.
22
(
8
),
084012
(
2013
).
19.
K. D.
Snelson
, U.S. patent 3,169,611 (1 Feb
1965
).
20.
R. E.
Skelton
and
M. C. D.
Oliveira
,
Tensegrity Systems
(
Springer
,
Berlin
,
2011
).
21.
F.
Fraternali
,
G.
Carpentieri
,
A.
Amendola
,
R. E.
Skelton
, and
V. F.
Nesterenko
,
Appl. Phys. Lett.
105
(
20
),
201903
(
2014
).
22.
V.
SunSpiral
,
G.
Gorospe
,
J.
Bruce
,
A.
Iscen
,
G.
Korbel
,
S.
Milam
,
A.
Agogino
, and
D.
Atkinson
,
Int. J. Planet. Probes
7
(
2013
).
23.
K.
Liu
,
J.
Wu
,
G. H.
Paulino
, and
H. J.
Qi
,
Sci. Rep.
7
(
1
),
3511
(
2017
).
24.
D. P.
Williams
,
W. B.
Carlson
,
W. A.
Schulze
, and
S. M.
Pilgrim
,
Mater. Res. Innovations
3
(
4
),
226
(
2000
).
25.
F.
Fraternali
,
G.
Carpentieri
, and
A.
Amendola
,
J. Mech. Phys. Solids
74
,
136
(
2015
).
26.
D.
Zhang
,
Y.
Xia
,
F.
Scarpa
,
J.
Hong
, and
Y.
Ma
,
Sci. Rep.
7
,
12874
(
2017
).
27.
N. B. H.
Ali
and
I. F. C.
Smith
,
Int. J. Solids Struct.
47
,
1285
(
2010
).
28.
D.
Zhang
,
F.
Scarpa
,
Y.
Ma
,
J.
Hong
, and
Y.
Mahadik
,
Mater. Des. (1980-2015)
56
,
69
(
2014
).

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