NEWSWORTHY
Nerves and Nanowires
To study the biocompatibility of nanoelectrodes researchers at Lund University injected nanowires into the brains of rats and found that microglia (the brain’s “clean-up” cells) ate away the nanowires, while a major astrocyte cells’ (who help in the healing process) response observed initially declined later on. The results prove that nanowires had no drastic or chronic affects on the brain. See AtoZ Nano, Nanotech Wire, Nanovip, and ACS Nano.
Optical Nanoantennas
Wireless data transmission requires a dipole antenna on both the transmitter and receiver ends, and communication is most effective and efficient when the total length of the dipole antennas is about half of the wavelength of the electromagnetic wave. KIT scientists have developed for the first time gold nanoantennas with an extremely high frequency (1 million times higher than radio frequencies) allowing fast modulation causing high data transmission rates. See AtoZ Nano, First Science, Nanotech Wire, and Nanowerk.
Nanochip for massive data storage
Engineers at North Carolina State University have created a nanochip with an ability to store data equivalent to 20-high definition DVDs or 250 pages or texts. Selective doping was performed with nickel being added to magnesium oxide; groups of nickel atoms were formed no bigger than 10 square nanometers. This feature enables more data storage capacity in a chip than usual. See First Science, Nanotech Wire, and Nanowerk.
“Nanotest” to detect prostate cancer
Using a process involving the use of gold nanoparticles with DNA that attach themselves to prostat-specific antigen (PSA) in blood, researchers of Northwestern University are able to now detect low levels of PSA in post-radical prostatectomy patients. They were able to measure PSA values of less than 0.1 milligrams per milliliter. See First Science, Nanotech Wire, Nanovip, Nanowerk, and PNAS.
HONORABLE MENTIONS
“Kinked” nanowires
Researchers at Harvard University have created two and three dimensional zigzag nanowires which can be useful in detecting small electrical currents in cells and tissues. The process involves the introduction of triangular “stereocenters” of 120° joints (which appear as “kinks”) into 1D nanowires. These kinked junctions enable functionality at different points on a nanowire, making it possible to develop nanoelectronics, photodetectors, or biological sensors into complex nanoscale structures. See AtoZ Nano, First Science, Nanovip, Nanowerk, and Nature Nano.
Nanoscale crystal
Researchers at California Institute of technology (CalTech) have developed a method to confine both light and sound in a nanoscale crystal device called an optomechanical crystal. This confinement can lead to the production of frequencies as high as tens of gigahertz, making transmission of large amounts of information possible. See AtoZ Nano and Nanowerk.
Mechanism for nanopillars
Scientists from CalTach have devised a mechanism to build high precision arrays of nanoscale pillars of any pattern on a polymer film. The mechanism involves photolithography and can be used to create three dimensional nano and micro-scale structures for optical, photonic, and biofluidic devices. See AtoZ Nano, Nanotech Wire, Nanowerk, and Physical Review Letters.
Tiny battery
Researchers at Yale University and National Institute of Standards and Technology (NIST) have developed a tiny battery with a capacity to generate electricity for ten minutes. The battery consists of two droplets, each consisting of a 200 nanoliter water based solution of potassium and chloride ions enclosed in a lipid wall. The small battery is created by varying the concentration of solution in two cells and inserting electrodes. These batteries are predicted to replace conventional solid-state energy-generating devices in the future. See AtoZ Nano, Nanowerk, and Advanced Materials.
Carbon nanotubes harmful to lungs
Carbon nanotubes are being used in various applications and equipments without substantial knowledge of their effects on health. A study by North Carolina State University, the Hamner Institutes for Health Sciences, and the National Institute of Environmental Health Sciences shows that inhalation of carbon nanotubes affects the pleura ( an outer lining of the lungs) causing fibrosis for a short time. A single exposure of the nanotubes resulted in either scarring of the pleural surface or fibrosis in mice. See AtoZ Nano, First Science, Nanotech Wire, and Nanowerk.
CNTs for crop growth
Scientists in Arkansas have reported that use of carbon nanotubes (CNTs) for seeds could be a new avenue in “nano-agriculture”. They found that CNTs penetrated the hard outer seed coating and enhanced its sprouting while making its seedlings heavier. These positive effects of germination and growth enhancement could reap economic benefits in agriculture, horticulture, and energy sector especially for plant-based biofuels. See Nanowerk and ACS Nano.
Tuesday, October 27, 2009
Wednesday, October 21, 2009
SEPARATING THE HYPE AND THE BUZZ - Wednesday, October 21, 2009
NEWSWORTHY
Nanoscale cantilevers to measure “Persistent current”
Physicists at Yale University used nanoscale cantilevers to develop a new method of measuring persistent current through a metal ring. They were able to do so by measuring the variations in magnetic force that resulted from the current flow in the ring. Persistent current is sensitive and extremely weak with a low-level magnetic field that cannot be measured using a SQUID. Nanoscale cantilevers were employed successfully to measure these extremely low levels of magnetic force in aluminum rings thereby making it possible to measure persistent currents. See AtoZ Nano, Nanotech Wire, Nanowerk, and Science.
Gold “snowflakes”
Kansas State University engineers formed 24-carat gold “snowflake” islands on a single atom thick material called graphene. They placed graphene dioxide sheets in a gold ion solution with a growth catalyst. Gold did not evenly coat the sheet but formed islands on it. Engineers called these islands snowflake-shaped gold nanostars, or SFGNs. They are continuing work on this discovery and hope to create a graphene-gold DNA sensor. See AtoZ Nano, First Science , Nanotech Wire, and ACS Nano.
Microwave “fridge” for your nano devices
Nanoscale measurement of a material when above absolute zero (-273°C) is difficult as heat produces atomic movements within it. In order to record accurate measurements there is a need to cool the material. This is now possible for ‘micro’ or ‘nano-scale mechanical resonators’ with the new tiny microwave-powered room-temperature refrigerator developed by National Physical Laboratory scientists. See Nanotech Wire, Nanowerk, and Applied Physics Letters.
Nano Butterfly Wings
Scientists of the State University of Pennsylvania (USA) and the Universidad Autónoma de Madrid (UAM) have found a way to create optically active nanostructures similar to those found in the insect world. Insects have the ability to appear metallic, multi-colored or iridescent. These properties are the result of photonic nanostructures, such as those found in the cuticles of butterfly wings. Their research team has developed a method for replicating these structures, which may be useful in a number of optically active devices (e.g.,optical diffusers in solar panels). See AtoZ Nano, First Science, Nanotech Wire, and Bioinspiration and Biomimetics.
Control of carbon nanotubes
Carbon nanotubes’ (cylindrical carbon molecules) structure and function, or chirality, can now be controlled by mixing different metals in a catalyst. Case Western Reserve researchers found that altering the structure of the catalyst through its composition can result in an ability to control the chirality, as well as the electrical and optical properties, of the nanotubes. See AtoZ Nano and Nanotech Wire.
HONORABLE MENTIONS
Nano-scale test tube
Melting, capillarity, and diffusion are now possible at a very small scale. Researchers from the University of Texas at Austin conducted an experiment with a nano-scale test tube composed of a thin shell of carbon. A gold-tipped nanowire was inserted into the test tube and heated to observe melting. The experiment could only be observed through a high power electron microscope. See AtoZ Nano, First Science, Nanotech Wire, and Nanovip.
Nanoaluminum rocket propellant
A frozen mixture of water and nanoscale aluminum particles could provide a more environmentally friendly rocket propellant. ALICE or aluminum (Al) – ice can be used to launch rockets into orbit or for long distance space missions. The fuel can be produced on the Moon, Mars, or any other water-bearing bodies. See AtoZ Nano, First Science, Nanotech Wire, and Nanowerk.
Nanoparticle electric propulsion
NanoFET is an electric rocket thruster that uses nanoparticle electric propulsion to improve the speed of a spacecraft while using less propellant than usual. The Air Force Office of Scientific Research is funding a professor from the University of Michigan to develop this electric rocket thruster. See AtoZ Nano, Nanovip, and Nanowerk.
Artificial neuromuscular junction
Neuromuscular junctions are nerve-muscle connections that help the brain control muscular movements. Researchers from the University of Michigan have developed an artificial neuromuscular junction that can improve the performance of prosthetic hands with a possibility to restore the sense of touch. The artificial junction consists of muscle cells and a nano-sized polymer placed on a biological scaffold. See AtoZ Nano and Nanowerk.
Artificial Photosynthesis
Four chemists from the University of Rochester are developing a three module process to effectively generate hydrogen from water through artificial photosynthesis using carbon nanotubes. In the first module a chromophore (a complex naturally occurring molecule found in plants) is used to create free electrons from visible light. In the second module a membrane of carbon nanotubes acts as a bridge to transport these electrons to the third module, where catalytic reaction is used to extract hydrogen from water. See AtoZ Nano, Nanotech Wire, and Nanowerk.
Nanoscale cantilevers to measure “Persistent current”
Physicists at Yale University used nanoscale cantilevers to develop a new method of measuring persistent current through a metal ring. They were able to do so by measuring the variations in magnetic force that resulted from the current flow in the ring. Persistent current is sensitive and extremely weak with a low-level magnetic field that cannot be measured using a SQUID. Nanoscale cantilevers were employed successfully to measure these extremely low levels of magnetic force in aluminum rings thereby making it possible to measure persistent currents. See AtoZ Nano, Nanotech Wire, Nanowerk, and Science.
Gold “snowflakes”
Kansas State University engineers formed 24-carat gold “snowflake” islands on a single atom thick material called graphene. They placed graphene dioxide sheets in a gold ion solution with a growth catalyst. Gold did not evenly coat the sheet but formed islands on it. Engineers called these islands snowflake-shaped gold nanostars, or SFGNs. They are continuing work on this discovery and hope to create a graphene-gold DNA sensor. See AtoZ Nano, First Science , Nanotech Wire, and ACS Nano.
Microwave “fridge” for your nano devices
Nanoscale measurement of a material when above absolute zero (-273°C) is difficult as heat produces atomic movements within it. In order to record accurate measurements there is a need to cool the material. This is now possible for ‘micro’ or ‘nano-scale mechanical resonators’ with the new tiny microwave-powered room-temperature refrigerator developed by National Physical Laboratory scientists. See Nanotech Wire, Nanowerk, and Applied Physics Letters.
Nano Butterfly Wings
Scientists of the State University of Pennsylvania (USA) and the Universidad Autónoma de Madrid (UAM) have found a way to create optically active nanostructures similar to those found in the insect world. Insects have the ability to appear metallic, multi-colored or iridescent. These properties are the result of photonic nanostructures, such as those found in the cuticles of butterfly wings. Their research team has developed a method for replicating these structures, which may be useful in a number of optically active devices (e.g.,optical diffusers in solar panels). See AtoZ Nano, First Science, Nanotech Wire, and Bioinspiration and Biomimetics.
Control of carbon nanotubes
Carbon nanotubes’ (cylindrical carbon molecules) structure and function, or chirality, can now be controlled by mixing different metals in a catalyst. Case Western Reserve researchers found that altering the structure of the catalyst through its composition can result in an ability to control the chirality, as well as the electrical and optical properties, of the nanotubes. See AtoZ Nano and Nanotech Wire.
HONORABLE MENTIONS
Nano-scale test tube
Melting, capillarity, and diffusion are now possible at a very small scale. Researchers from the University of Texas at Austin conducted an experiment with a nano-scale test tube composed of a thin shell of carbon. A gold-tipped nanowire was inserted into the test tube and heated to observe melting. The experiment could only be observed through a high power electron microscope. See AtoZ Nano, First Science, Nanotech Wire, and Nanovip.
Nanoaluminum rocket propellant
A frozen mixture of water and nanoscale aluminum particles could provide a more environmentally friendly rocket propellant. ALICE or aluminum (Al) – ice can be used to launch rockets into orbit or for long distance space missions. The fuel can be produced on the Moon, Mars, or any other water-bearing bodies. See AtoZ Nano, First Science, Nanotech Wire, and Nanowerk.
Nanoparticle electric propulsion
NanoFET is an electric rocket thruster that uses nanoparticle electric propulsion to improve the speed of a spacecraft while using less propellant than usual. The Air Force Office of Scientific Research is funding a professor from the University of Michigan to develop this electric rocket thruster. See AtoZ Nano, Nanovip, and Nanowerk.
Artificial neuromuscular junction
Neuromuscular junctions are nerve-muscle connections that help the brain control muscular movements. Researchers from the University of Michigan have developed an artificial neuromuscular junction that can improve the performance of prosthetic hands with a possibility to restore the sense of touch. The artificial junction consists of muscle cells and a nano-sized polymer placed on a biological scaffold. See AtoZ Nano and Nanowerk.
Artificial Photosynthesis
Four chemists from the University of Rochester are developing a three module process to effectively generate hydrogen from water through artificial photosynthesis using carbon nanotubes. In the first module a chromophore (a complex naturally occurring molecule found in plants) is used to create free electrons from visible light. In the second module a membrane of carbon nanotubes acts as a bridge to transport these electrons to the third module, where catalytic reaction is used to extract hydrogen from water. See AtoZ Nano, Nanotech Wire, and Nanowerk.
Monday, October 12, 2009
SEPARATING THE HYPE AND THE BUZZ - Monday, October 12, 2009
BREAKTHROUGH
Carbon nanotubes for detection
Stanford scientists have developed a chip consisting of carbon nanotubes that detects low levels of trinitrotoluene (TNT) and sarin in water. The plastic substrate chip is flexible, cheap, and operates efficiently under water. See AtoZ Nano, Nanowerk, and ACS Nano.
NEWSWORTHY
Brain implants
Scientists at University of Michigan have observed that brain implants in rats are more efficient when coated with nanotubes made up of poly(3,4-ethylenedioxythiophene) (PEDOT). The coated implants have shown an improvement of 30 percent in high-quality unit activity as compared to uncoated implants. See AtoZ Nano, Nanotech Wire, Nanowerk, and Journal of Advanced Materials.
Artificial pore
Biomedical researchers from the University of Cincinnati have developed an artificial pore that when inserted into a lipid membrane allows single and double stranded DNA to pass through it. This modified core of a nanomotor could find applications in drug loading, gene delivery, nano sensing and DNA sequencing. See AtoZ Nano, Nanowerk, and Nature Nanotechnology.
Nanosensors to measure insulin level
Iranian researchers have developed nanosenors that can detect insulin levels for diabetic patients. To produce nanosensors, the researchers used silicon carbide nanoparticles in ethanol on glass carbon electrodes. They were left to evaporate and were stabilized on the electrode to form detectors. See Nanowerk.
Quantum dots to treat skin cancer
Researchers from the US and Canada are collaborating to develop quantum dots as photsensitizers to treat skin cancer. Photosensitizers combining with light, as in photodynamic therapy can produce oxygen species that are harmful to cancer cells. See Nanoscale and Nanowerk.
HONORABLE MENTIONS
Nanotechnology for space environment
Researchers at Georgia Institute of Technology are conducting experiments to develop shielding devices to protect microelectronics and other integrated circuits used in spacecrafts and satellites from harmful space radiations. The researchers note that an alloy of Silicon and Germanium at the nanoscale could act as a shielding agent. Investigations are on to figure ways of improving the combination so this alloy can shield most radiations. See AtoZNano.
Quantum dot directed assembly gains momentum
Directed assembly is a process of controlling quantum dots through manipulation of atoms in quantum dots to control their properties and behavior. But lack of information regarding their atomic –scale, chemical, and structural properties was slowing this process down. But, researchers from University of Michigan have created atomic scale maps of these quantum dots to regain the lost pace of directed assembly. See AtoZNano and Nanowerk.
Controlled movement in the nanoworld
Scientists in the UK are making efforts to control directed movement of molecules of nanoparticles. They developed a surface containing both hydrophobic and hydrophilic sections producing an energy gradient, where particles move in a directed pattern. See AtoZNano, Nanowerk, and ACS Nano.
Nanochip for cancer detection
Early detection of the type and severity of cancer is now possible thanks to researchers from the University of Toronto. They have developed a microchip made from nanomaterials that is sensitive enough to do so within 30 minutes. See Nanowerk and Nanotech Wire.
Carbon nanotubes for detection
Stanford scientists have developed a chip consisting of carbon nanotubes that detects low levels of trinitrotoluene (TNT) and sarin in water. The plastic substrate chip is flexible, cheap, and operates efficiently under water. See AtoZ Nano, Nanowerk, and ACS Nano.
NEWSWORTHY
Brain implants
Scientists at University of Michigan have observed that brain implants in rats are more efficient when coated with nanotubes made up of poly(3,4-ethylenedioxythiophene) (PEDOT). The coated implants have shown an improvement of 30 percent in high-quality unit activity as compared to uncoated implants. See AtoZ Nano, Nanotech Wire, Nanowerk, and Journal of Advanced Materials.
Artificial pore
Biomedical researchers from the University of Cincinnati have developed an artificial pore that when inserted into a lipid membrane allows single and double stranded DNA to pass through it. This modified core of a nanomotor could find applications in drug loading, gene delivery, nano sensing and DNA sequencing. See AtoZ Nano, Nanowerk, and Nature Nanotechnology.
Nanosensors to measure insulin level
Iranian researchers have developed nanosenors that can detect insulin levels for diabetic patients. To produce nanosensors, the researchers used silicon carbide nanoparticles in ethanol on glass carbon electrodes. They were left to evaporate and were stabilized on the electrode to form detectors. See Nanowerk.
Quantum dots to treat skin cancer
Researchers from the US and Canada are collaborating to develop quantum dots as photsensitizers to treat skin cancer. Photosensitizers combining with light, as in photodynamic therapy can produce oxygen species that are harmful to cancer cells. See Nanoscale and Nanowerk.
HONORABLE MENTIONS
Nanotechnology for space environment
Researchers at Georgia Institute of Technology are conducting experiments to develop shielding devices to protect microelectronics and other integrated circuits used in spacecrafts and satellites from harmful space radiations. The researchers note that an alloy of Silicon and Germanium at the nanoscale could act as a shielding agent. Investigations are on to figure ways of improving the combination so this alloy can shield most radiations. See AtoZNano.
Quantum dot directed assembly gains momentum
Directed assembly is a process of controlling quantum dots through manipulation of atoms in quantum dots to control their properties and behavior. But lack of information regarding their atomic –scale, chemical, and structural properties was slowing this process down. But, researchers from University of Michigan have created atomic scale maps of these quantum dots to regain the lost pace of directed assembly. See AtoZNano and Nanowerk.
Controlled movement in the nanoworld
Scientists in the UK are making efforts to control directed movement of molecules of nanoparticles. They developed a surface containing both hydrophobic and hydrophilic sections producing an energy gradient, where particles move in a directed pattern. See AtoZNano, Nanowerk, and ACS Nano.
Nanochip for cancer detection
Early detection of the type and severity of cancer is now possible thanks to researchers from the University of Toronto. They have developed a microchip made from nanomaterials that is sensitive enough to do so within 30 minutes. See Nanowerk and Nanotech Wire.
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