TY - JOUR
T1 - Nondestructive measurements of the mechanical and structural properties of nanostructured metalattices
AU - Abad, Begoña
AU - Knobloch, Joshua L.
AU - Frazer, Travis D.
AU - Hernández-Charpak, Jorge N.
AU - Cheng, Hiu Y.
AU - Grede, Alex J.
AU - Giebink, Noel C.
AU - Mallouk, Thomas E.
AU - Mahale, Pratibha
AU - Nova, Nabila N.
AU - Tomaschke, Andrew A.
AU - Ferguson, Virginia L.
AU - Crespi, Vincent H.
AU - Gopalan, Venkatraman
AU - Kapteyn, Henry C.
AU - Badding, John V.
AU - Murnane, Margaret M.
N1 - Publisher Copyright:
© 2020 American Chemical Society.
PY - 2020/5/13
Y1 - 2020/5/13
N2 - Metalattices are artificial 3D solids, periodic on sub-100 nm length scales, that enable the functional properties of materials to be tuned. However, because of their complex structure, predicting and characterizing their properties is challenging. Here we demonstrate the first nondestructive measurements of the mechanical and structural properties of metalattices with feature sizes down to 14 nm. By monitoring the time-dependent diffraction of short wavelength light from laser-excited acoustic waves in the metalattices, we extract their acoustic dispersion, Young's modulus, filling fraction, and thicknesses. Our measurements are in excellent agreement with macroscopic predictions and potentially destructive techniques such as nanoindentation and scanning electron microscopy, with increased accuracy over larger areas. This is interesting because the transport properties of these metalattices do not obey bulk predictions. Finally, this approach is the only way to validate the filling fraction of metalattices over macroscopic areas. These combined capabilities can enable accurate synthesis of nanoenhanced materials.
AB - Metalattices are artificial 3D solids, periodic on sub-100 nm length scales, that enable the functional properties of materials to be tuned. However, because of their complex structure, predicting and characterizing their properties is challenging. Here we demonstrate the first nondestructive measurements of the mechanical and structural properties of metalattices with feature sizes down to 14 nm. By monitoring the time-dependent diffraction of short wavelength light from laser-excited acoustic waves in the metalattices, we extract their acoustic dispersion, Young's modulus, filling fraction, and thicknesses. Our measurements are in excellent agreement with macroscopic predictions and potentially destructive techniques such as nanoindentation and scanning electron microscopy, with increased accuracy over larger areas. This is interesting because the transport properties of these metalattices do not obey bulk predictions. Finally, this approach is the only way to validate the filling fraction of metalattices over macroscopic areas. These combined capabilities can enable accurate synthesis of nanoenhanced materials.
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U2 - 10.1021/acs.nanolett.0c00167
DO - 10.1021/acs.nanolett.0c00167
M3 - Article
C2 - 32227973
AN - SCOPUS:85084696094
SN - 1530-6984
VL - 20
SP - 3306
EP - 3312
JO - Nano letters
JF - Nano letters
IS - 5
ER -