6 research outputs found
Making glassy solids ductile at room temperature by imparting flexibility into their amorphous structure
<p>Making glasses ductile at room temperature is a daunting challenge, but has been shown to be feasible in recent years. We explain the plastic flow from the standpoint of the flexibility available in the amorphous structure: imparting flexibility into the structure facilitates bond switching needed to mediate shear transformations to carry strain. This structure–property correlation is demonstrated using molecular dynamics simulation data. The flexibility can be improved via ultrafast quench or rejuvenation. In particular, the flexibility volume parameter offers a quantitative metric to explain the flexibility and deformability, even for glasses where the commonly cited free volume is not applicable.</p> <p>This Perspective demonstrates using examples and models that it is the flexibility rather than the excess volume that can be tuned to facilitate plastic flow and ductility in glassy materials.</p
Quantitative Evidence of Crossover toward Partial Dislocation Mediated Plasticity in Copper Single Crystalline Nanowires
In situ tensile tests of Cu single crystalline nanowires
in a high-resolution
transmission electron microscope reveal a novel effect of sample dimensions
on plasticity mechanisms. When the single crystalline nanowire size
was reduced to <∼150 nm, the normal full dislocation slip
was taken over by partial dislocation mediated plasticity (PDMP).
For the first time, we demonstrate this transition in a quantitative
manner by assessing the relative contributions to plastic strain from
PDMP and full dislocations. The crossover sample size is consistent,
well within model predictions. This discovery represents yet another
“sample size effect”, beyond other reported influence
of sample dimensions on the mechanical behavior of metals, such as
dislocation starvation or source truncation, and the “smaller
is stronger” trend
Growth Conditions Control the Elastic and Electrical Properties of ZnO Nanowires
Great
efforts have been made to synthesize ZnO nanowires (NWs) as building
blocks for a broad range of applications because of their unique mechanical
and mechanoelectrical properties. However, little attention has been
paid to the correlation between the NWs synthesis condition and these
properties. Here we demonstrate that by slightly adjusting the NW
growth conditions, the cross-sectional shape of the NWs can be tuned
from hexagonal to circular. Room temperature photoluminescence spectra
suggested that NWs with cylindrical geometry have a higher density
of point defects. In situ transmission electron microscopy (TEM) uniaxial
tensile-electrical coupling tests revealed that for similar diameter,
the Young’s modulus and electrical resistivity of hexagonal
NWs is always larger than that of cylindrical NWs, whereas the piezoresistive
coefficient of cylindrical NWs is generally higher. With decreasing
diameter, the Young’s modulus and the resistivity of NWs increase,
whereas their piezoresistive coefficient decreases, regardless of
the sample geometry. Our findings shed new light on understanding
and advancing the performance of ZnO-NW-based devices through optimizing
the synthesis conditions of the NWs
Radiation-Induced Helium Nanobubbles Enhance Ductility in Submicron-Sized Single-Crystalline Copper
The
workability and ductility of metals usually degrade with exposure
to irradiation, hence the phrase “radiation damage”.
Here, we found that helium (He) radiation can actually enhance the
room-temperature deformability of submicron-sized copper. In particular,
Cu single crystals with diameter of 100–300 nm and containing
numerous pressurized sub-10 nm He bubbles become stronger, more stable
in plastic flow and ductile in tension, compared to fully dense samples
of the same dimensions that tend to display plastic instability (strain
bursts). The sub-10 nm He bubbles are seen to be dislocation sources
as well as shearable obstacles, which promote dislocation storage
and reduce dislocation mean free path, thus contributing to more homogeneous
and stable plasticity. Failure happens abruptly only after significant
bubble coalescence. The current findings can be explained in light
of Weibull statistics of failure and the beneficial effects of bubbles
on plasticity. These results shed light on plasticity and damage developments
in metals and could open new avenues for making mechanically robust
nano- and microstructures by ion beam processing and He bubble engineering
Radiation-Induced Helium Nanobubbles Enhance Ductility in Submicron-Sized Single-Crystalline Copper
The
workability and ductility of metals usually degrade with exposure
to irradiation, hence the phrase “radiation damage”.
Here, we found that helium (He) radiation can actually enhance the
room-temperature deformability of submicron-sized copper. In particular,
Cu single crystals with diameter of 100–300 nm and containing
numerous pressurized sub-10 nm He bubbles become stronger, more stable
in plastic flow and ductile in tension, compared to fully dense samples
of the same dimensions that tend to display plastic instability (strain
bursts). The sub-10 nm He bubbles are seen to be dislocation sources
as well as shearable obstacles, which promote dislocation storage
and reduce dislocation mean free path, thus contributing to more homogeneous
and stable plasticity. Failure happens abruptly only after significant
bubble coalescence. The current findings can be explained in light
of Weibull statistics of failure and the beneficial effects of bubbles
on plasticity. These results shed light on plasticity and damage developments
in metals and could open new avenues for making mechanically robust
nano- and microstructures by ion beam processing and He bubble engineering
Radiation-Induced Helium Nanobubbles Enhance Ductility in Submicron-Sized Single-Crystalline Copper
The
workability and ductility of metals usually degrade with exposure
to irradiation, hence the phrase “radiation damage”.
Here, we found that helium (He) radiation can actually enhance the
room-temperature deformability of submicron-sized copper. In particular,
Cu single crystals with diameter of 100–300 nm and containing
numerous pressurized sub-10 nm He bubbles become stronger, more stable
in plastic flow and ductile in tension, compared to fully dense samples
of the same dimensions that tend to display plastic instability (strain
bursts). The sub-10 nm He bubbles are seen to be dislocation sources
as well as shearable obstacles, which promote dislocation storage
and reduce dislocation mean free path, thus contributing to more homogeneous
and stable plasticity. Failure happens abruptly only after significant
bubble coalescence. The current findings can be explained in light
of Weibull statistics of failure and the beneficial effects of bubbles
on plasticity. These results shed light on plasticity and damage developments
in metals and could open new avenues for making mechanically robust
nano- and microstructures by ion beam processing and He bubble engineering