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Engineering Nanoparticles for Maximum Strength
October 21, 2008BERKELEY, CA - Because they are riddled with defects, bulk crystalline materials never achieve their ideal strength; nanocrystals, on the other hand, are so small there's no room for defects. ("Nano" is short for nanometer, a billionth of a meter.) Yet while nanocrystalline materials may approach ideal strength in their resistance to stress, most nanostructures have shown only a limited ability to withstand large internal strains before they fail. Overcoming this limitation could lead to great advances in engineered materials on all scales.
Scientists at the U.S. Department of Energy's Lawrence Berkeley National Laboratory and the University of California at Berkeley have used in situ transmission electron microscopy to measure hollow spherical nanoparticles that withstand extreme stress and deform without losing strength. The geometry of the novel nanospheres can be engineered to approach the theoretical ideal shear strength of the material from which they are made, in this case cadmium sulfide. The researchers report their results in the November, 2008 issue of Nature Materials, available to subscribers in advanced online publication.
"To understand what happens to the individual nanoparticles when stress is applied, you need to actually see the deformation as it is happening," says Andrew Minor of the National Center for Electron Microscopy (NCEM) in Berkeley Lab's Materials Sciences Division (MSD); Minor is also a member of UC Berkeley's Department of Materials Science and Engineering (MSE). "We put the nanospheres on a flat silicon substrate inside NCEM's In Situ Microscope sample chamber and compressed them with a flat-faced diamond punch until they fractured. Using videos of the compression tests, we could determine exactly when they fractured, and then measure the force applied at that exact moment."
Minor refers to one video in which the graph of applied pressure drops suddenly when the compressed nanosphere squirts out from between the substrate and the punch like a watermelon seed. "If you didn't see that happening, you'd have no way of knowing why the force suddenly vanished," he says. "So while setting up the experiment in the In Situ Microscope is a little more difficult and time-consuming, it's essential."
Engineered nanospheres
The nanospheres of cadmium sulfide were prepared in the laboratories of Paul Alivisatos, Berkeley Lab's Deputy Director and Division Director of MSD, and a member of UC Berkeley's MSE and Chemistry Departments. The chemical methods used to create the hollow spheres allow their dimensions to be manipulated with great precision, including the outer diameter of the spheres and the thickness of the shells.
"Essentially we're investigating structural hierarchy, which is known to play an important role in determining the strength of many bulk materials - bone, for example - only here we're applying it on the nanoscale," says Minor. "In this case the hierarchy is the size of the crystal domains, from three or four nanometers up to 10 nanometers; the thickness of the shells, from 35 to 70 nanometers; and the diameter of the spheres, from about 200 to 450 nanometers. We experimented on dozens of nanospheres with variations in each of these dimensions."
What they observed as the diamond anvil slowly bore down on the hollow nanospheres was that the spheres gradually bulged at the sides as they were squashed. Cadmium sulfide is inherently brittle and might have been expected to break easily, but instead the spheres deformed by as much as 20 percent of their original diameter before they shattered.
To understand the distribution of stresses throughout the sphere, Daryl Chrzan of MSD and MSE and his research group performed theoretical calculations. The sphere was computationally divided into a fine grid and the deformation for each grid element was calculated, giving the reaction to the applied force for the overall geometry of the sphere at that point.
These local strengths were combined to model the behavior of the whole sphere, a process called finite element analysis, or FEA. When simulated by a computer, the strain at each point in a sphere of specific dimensions, subjected to the applied compression, could be calculated and visualized. The simulations revealed that as displacement increased, the sphere's shape served to transfer stress to certain regions experiencing maximum shear - regions corresponding to the top and bottom of the sphere where it contacted the substrate and the diamond anvil. This is where the spheres were usually observed to fail in the actual experiments. Indeed, the experimental results generally followed the predictions of the FEA model.
Models and experiments
"The model incorporates the actual experimental conditions as well as possible," says Minor, "including the 'glue' we use to hold the nanosphere on the substrate. This is just a little of the carbonaceous material left over from the chemical process used to create the cadmium sulfide nanospheres. Originally we cleaned this away, but after we experienced a couple of instances of the spheres slipping away when they were squeezed, we stopped cleaning them so they would stay attached to the surface. The FEA model had to take this carbonaceous material into account."
The FEA model showed that the stresses within the FEA model at the point of fracture were indeed quite high. For example, a nanosphere 450 nanometers in diameter with a shell about 69 nanometers thick, deformed by compression to some eight percent of its original diameter, experiences local shear stresses approaching the ideal shear strength of cadmium sulfide. A 'fracture criterion,' derived by the researchers from their model, accurately predicts that a typical nanosphere experiences some 70 percent of the ideal shear strength at its point of failure.
"These are the most complete analyses of the mechanical properties of single nanoparticles that I am aware of," says Minor, "because in situ observations under the transmission electron microscope allowed us to see the precise dimensions of each particle and see exactly when and how it fails - thus eliminating the gap between experiment and theory."
Previous attempts to increase the deformability of nanomaterials, in order to reduce their tendency to fail under limited strains, have also unfortunately reduced their strength. The new experiments with hollow nanospheres show that, by combining strength and deformability, the hollow spherical geometry confers both high strength and relatively high strains at failure. The ability to endure high stress and strain is a direct result of structural hierarchy: the small grain size gives high strength, while the overall shape of the sphere distributes stress and allows the structure to withstand high strains.
"This work could only have been done with an In Situ Microscope like NCEM's, plus a quantitative mechanical testing holder like the one developed by Hysitron, Inc. and NCEM, and with hollow nanospheres like those made in the Alivisatos lab - as well as the complete analysis with sophisticated computational tools provided by the Chrzan group," says Minor. "We believe the surprising results have opened a path toward much greater possible advances in structural materials at a range of scales."
"Ultrahigh stress and strain in hierarchically structured hollow nanoparticles," by Zhiwei Shan, Giulia Adesso, Andreu Cabot, Matthew Sherburne, S. A. Syed Asif, Oden Warren, Daryl Chrzan, Andrew Minor, and A. Paul Alivisatos, appears in the November issue of Nature Materials and is available in advanced online publication to subscribers at http://dx.doi.org/10.1038/nmat2295.
Berkeley Lab is a U.S. Department of Energy national laboratory located in Berkeley, California. It conducts unclassified scientific research and is managed by the University of California. Visit our website at http://www.lbl.gov.
Lawrence Berkeley National Laboratory
Minor refers to one video in which the graph of applied pressure drops suddenly when the compressed nanosphere squirts out from between the substrate and the punch like a watermelon seed. "If you didn't see that happening, you'd have no way of knowing why the force suddenly vanished," he says. "So while setting up the experiment in the In Situ Microscope is a little more difficult and time-consuming, it's essential."
Engineered nanospheres
The nanospheres of cadmium sulfide were prepared in the laboratories of Paul Alivisatos, Berkeley Lab's Deputy Director and Division Director of MSD, and a member of UC Berkeley's MSE and Chemistry Departments. The chemical methods used to create the hollow spheres allow their dimensions to be manipulated with great precision, including the outer diameter of the spheres and the thickness of the shells.
"Essentially we're investigating structural hierarchy, which is known to play an important role in determining the strength of many bulk materials - bone, for example - only here we're applying it on the nanoscale," says Minor. "In this case the hierarchy is the size of the crystal domains, from three or four nanometers up to 10 nanometers; the thickness of the shells, from 35 to 70 nanometers; and the diameter of the spheres, from about 200 to 450 nanometers. We experimented on dozens of nanospheres with variations in each of these dimensions."
What they observed as the diamond anvil slowly bore down on the hollow nanospheres was that the spheres gradually bulged at the sides as they were squashed. Cadmium sulfide is inherently brittle and might have been expected to break easily, but instead the spheres deformed by as much as 20 percent of their original diameter before they shattered.
To understand the distribution of stresses throughout the sphere, Daryl Chrzan of MSD and MSE and his research group performed theoretical calculations. The sphere was computationally divided into a fine grid and the deformation for each grid element was calculated, giving the reaction to the applied force for the overall geometry of the sphere at that point.
These local strengths were combined to model the behavior of the whole sphere, a process called finite element analysis, or FEA. When simulated by a computer, the strain at each point in a sphere of specific dimensions, subjected to the applied compression, could be calculated and visualized. The simulations revealed that as displacement increased, the sphere's shape served to transfer stress to certain regions experiencing maximum shear - regions corresponding to the top and bottom of the sphere where it contacted the substrate and the diamond anvil. This is where the spheres were usually observed to fail in the actual experiments. Indeed, the experimental results generally followed the predictions of the FEA model.
Models and experiments
"The model incorporates the actual experimental conditions as well as possible," says Minor, "including the 'glue' we use to hold the nanosphere on the substrate. This is just a little of the carbonaceous material left over from the chemical process used to create the cadmium sulfide nanospheres. Originally we cleaned this away, but after we experienced a couple of instances of the spheres slipping away when they were squeezed, we stopped cleaning them so they would stay attached to the surface. The FEA model had to take this carbonaceous material into account."
The FEA model showed that the stresses within the FEA model at the point of fracture were indeed quite high. For example, a nanosphere 450 nanometers in diameter with a shell about 69 nanometers thick, deformed by compression to some eight percent of its original diameter, experiences local shear stresses approaching the ideal shear strength of cadmium sulfide. A 'fracture criterion,' derived by the researchers from their model, accurately predicts that a typical nanosphere experiences some 70 percent of the ideal shear strength at its point of failure.
"These are the most complete analyses of the mechanical properties of single nanoparticles that I am aware of," says Minor, "because in situ observations under the transmission electron microscope allowed us to see the precise dimensions of each particle and see exactly when and how it fails - thus eliminating the gap between experiment and theory."
Previous attempts to increase the deformability of nanomaterials, in order to reduce their tendency to fail under limited strains, have also unfortunately reduced their strength. The new experiments with hollow nanospheres show that, by combining strength and deformability, the hollow spherical geometry confers both high strength and relatively high strains at failure. The ability to endure high stress and strain is a direct result of structural hierarchy: the small grain size gives high strength, while the overall shape of the sphere distributes stress and allows the structure to withstand high strains.
"This work could only have been done with an In Situ Microscope like NCEM's, plus a quantitative mechanical testing holder like the one developed by Hysitron, Inc. and NCEM, and with hollow nanospheres like those made in the Alivisatos lab - as well as the complete analysis with sophisticated computational tools provided by the Chrzan group," says Minor. "We believe the surprising results have opened a path toward much greater possible advances in structural materials at a range of scales."
"Ultrahigh stress and strain in hierarchically structured hollow nanoparticles," by Zhiwei Shan, Giulia Adesso, Andreu Cabot, Matthew Sherburne, S. A. Syed Asif, Oden Warren, Daryl Chrzan, Andrew Minor, and A. Paul Alivisatos, appears in the November issue of Nature Materials and is available in advanced online publication to subscribers at http://dx.doi.org/10.1038/nmat2295.
Berkeley Lab is a U.S. Department of Energy national laboratory located in Berkeley, California. It conducts unclassified scientific research and is managed by the University of California. Visit our website at http://www.lbl.gov.
Lawrence Berkeley National Laboratory
Nanospheres Current Events and Nanospheres News RSSSpecial gold nanoparticles show promise for 'cooking' cancer cells
Researchers are describing a long-awaited advance toward applying the marvels of nanotechnology in the battle against cancer. They have developed the first hollow gold nanospheres - smaller than the finest flecks of dust - that search out and "cook" cancer cells.
Hollow gold nanospheres show promise for biomedical and other applications
A new metal nanostructure developed by researchers at the University of California, Santa Cruz, has already shown promise in cancer therapy studies and could be used for chemical and biological sensors and other applications as well.
Targeted nanospheres find, penetrate, then fuel burning of melanoma
Hollow gold nanospheres equipped with a targeting peptide find melanoma cells, penetrate them deeply, and then cook the tumor when bathed with near-infrared light, a research team led by scientists at The University of Texas M. D. Anderson Cancer Center reported in the Feb. 1 issue of Clinical Cancer Research.
Gold nanostars outshine the competition
Novel nanoparticles being tested at the National Institute of Standards and Technology (NIST) have researchers seeing stars. In a recent paper, NIST scientists used surface-enhanced Raman spectroscopy (SERS) to demonstrate that gold nanostars exhibit optical qualities that make them superior for chemical and biological sensing and imaging.
New technique sees into tissue at greater depth, resolution
By coupling a kicked-up version of microscopy with miniscule particles of gold, Duke University scientists are now able to peer so deep into living tissue that they can see molecules interacting.
Turning Waste Material into Ethanol
Say the word "biofuels" and most people think of grain ethanol and biodiesel. But there's another, older technology called gasification that's getting a new look from researchers at the U.S. Department of Energy's Ames Laboratory and Iowa State University. By combining gasification with high-tech nanoscale porous catalysts, they hope to create ethanol from a wide range of biomass, including distiller's grain left over from ethanol production, corn stover from the field, grass, wood pulp, animal waste, and garbage.
Killer pulses help characterize special surfaces
Detecting deadly fumes in subways, toxic gases in chemical spills, and hidden explosives in baggage is becoming easier and more efficient with a measurement technique called surface-enhanced Raman scattering. To further improve the technique's sensitivity, scientists must design better scattering surfaces, and more effective ways of evaluating them.
Platinum nanocrystals boost catalytic activity for fuel oxidation, hydrogen production
A research team composed of electrochemists and materials scientists from two continents has produced a new form of the industrially-important metal platinum: 24-facet nanocrystals whose catalytic activity per unit area can be as much as four times higher than existing commercial platinum catalysts.
UC Davis researchers use heated nanoprobes to destroy breast cancer cells in mice
In experiments with laboratory mice that bear aggressive human breast cancers, UC Davis researchers have used hot nanoprobes to slow the growth of tumors — without damage to surrounding healthy tissue. The researchers describe their work in the March issue of the Journal of Nuclear Medicine.
Gold Nanorods May Make Safer Cancer Treatment
Researchers at the Georgia Institute of Technology and the University of California, San Francisco, have found an even more effective and safer way to detect and kill cancer cells.
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Nanovor: Welcome to the Nanosphere: A Nanovor Field Guide by Smith & Tinker (Creator) Increase your knowledge of the Nanovor world with this comprehensive field guide! Get a first-hand glimpse into the Nanosphere and the epic battles that take place within. Each character is dissected in this guide to provide an in-depth look into the anatomy and behavior of the critters that keep our world in balance. |
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Ultrasound Creates Hollow Nanospheres.: An article from: High Tech Ceramics News by Business Communications Company, Inc. (Publisher) This digital document is an article from High Tech Ceramics News, published by Business Communications Company, Inc. on March 1, 2005. The length of the article is 350 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Citation Details Title: Ultrasound Creates Hollow Nanospheres. Publication: High Tech Ceramics News (Newsletter) Date: March 1, 2005 Publisher: Business Communications Company, Inc. Volume: 16 Issue: 10 Page: NA Distributed by Thompson... | |
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Self-assembling gold nanoparticles on thiol-functionalized poly(styrene-co-acrylic acid) nanospheres for fabrication of a mediatorless biosensor [An article from: Analytica Chimica Acta] by S. Xu (Author), G. Tu (Author), B. Peng (Author), X. Han (Author) This digital document is a journal article from Analytica Chimica Acta, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: A novel strategy to construct a sensitive mediatorless sensor of H"2O"2 was described. At first, a cleaned gold electrode was immersed in thiol-functionalized poly(styrene-co-acrylic acid) (St-co-AA) nanosphere latex prepared by emulsifier-free emulsion polymerization St with AA and function with dithioglycol to assemble the nanospheres, then gold nanoparticles were chemisorbed onto the thiol groups and formed monolayers on the surface of poly(St-co-AA) nanospheres. Finally, horseradish peroxidase (HRP) was... |
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