Monday, August 5, 2013

Disorder can improve the performance of plastic solar cells, Stanford scientists say

Disorder can improve the performance of plastic solar cells, Stanford scientists say [ Back to EurekAlert! ] Public release date: 4-Aug-2013
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Contact: Mark Shwartz
mshwartz@stanford.edu
650-723-9296
Stanford University

Scientists have spent decades trying to build flexible plastic solar cells efficient enough to compete with conventional cells made of silicon. To boost performance, research groups have tried creating new plastic materials that enhance the flow of electricity through the solar cell. Several groups expected to achieve good results by redesigning pliant polymers of plastic into orderly, silicon-like crystals, but the flow of electricity did not improve.

Recently, scientists discovered that disorder at the molecular level actually improves the polymers' performance. Now Stanford University researchers have an explanation for this surprising result. Their findings, published in the Aug. 4 online edition of the journal Nature Materials, could speed up the development of low-cost, commercially available plastic solar cells.

"People used to think that if you made the polymers more like silicon they would perform better," said study co-author Alberto Salleo, an associate professor of materials science and engineering at Stanford. "But we found that polymers don't naturally form nice, well-ordered crystals. They form small, disordered ones, and that's perfectly fine."

Instead of trying to mimic the rigid structure of silicon, Salleo and his colleagues recommend that scientists learn to cope with the inherently disordered nature of plastics.

Speedy electrons

In the study, the Stanford team focused on a class of organic materials known as conjugated or semiconducting polymers chains of carbon atoms that have the properties of plastic, and the ability to absorb sunlight and conduct electricity.

Discovered nearly 40 years ago, semiconducting polymers have long been considered ideal candidates for ultrathin solar cells, light-emitting diodes and transistors. Unlike silicon crystals used in rooftop solar panels, semiconducting polymers are lightweight and can be processed at room temperature with ink-jet printers and other inexpensive techniques. So why aren't buildings today covered with plastic solar cells?

"One reason they haven't been commercialized is because of poor performance," Salleo said. "In a solar cell, electrons need to move through the materials fast, but semiconducting polymers have poor electron mobility."

To find out why, Salleo joined Rodrigo Noriega and Jonathan Rivnay, who were Stanford graduate students at the time, in analyzing more than two decades of experimental data. "Over the years, many people designed stiffer polymers with the goal of making highly organized crystals, but the charge mobility remained relatively poor," Salleo said. "Then several labs created polymers that looked disordered and yet had very high charge mobility. It was a puzzle why these new materials worked better than the more structured crystalline ones."

X-ray analysis

To observe the disordered materials at the microscopic level, the Stanford team took samples to the SLAC National Accelerator Laboratory for X-ray analysis. The X-rays revealed a molecular structure resembling a fingerprint gone awry. Some polymers looked like amorphous strands of spaghetti, while others formed tiny crystals just a few molecules long.

"The crystals were so small and disordered you could barely infer their presence from X-rays," Salleo said. "In fact, scientists had assumed they weren't there."

By analyzing light emissions from electricity flowing through the samples, the Stanford team determined that numerous small crystals were scattered throughout the material and connected by long polymer chains, like beads in a necklace. The small size of the crystals was a crucial factor in improving overall performance, Salleo said.

"Being small enables a charged electron to go through one crystal and rapidly move on to the next one," he said. "The long polymer chain then carries the electron quickly through the material. That explains why they have a much higher charge mobility than larger, unconnected crystals."

Another disadvantage of large crystalline polymers is that they tend to be insoluble and therefore cannot be produced by ink-jet printing or other cheap processing technologies, he added.

"Our conclusion is that you don't need to make something so rigid that it forms large crystals," Salleo said. "You need to design something with small, disordered crystals packed close together and connected by polymer chains. Electrons will move through the crystals like on a superhighway, ignoring the rest of the plastic material, which is amorphous and poorly conducting.

"In some sense, the synthetic chemists were ahead of us, because they made these new materials but didn't know why they worked so well," he said. "Now that they know, they can go out and design even better ones."

And Salleo offered a final piece of advice. "Try to design a material that can live with as much disorder as possible," he said. "Take the disorder for granted. Personally, I really like disorder. Just look at my office."

###

Other authors of the study are postdoctoral scholar Koen Vandewal of Stanford; Felix Koch and Paul Smith of ETH Zurich; Natalie Stingelin of Imperial College London; and Michael Toney of the SLAC Stanford Synchrotron Radiation Lightsource.

The study was supported by a Stanford Center for Advanced Molecular Photovoltaics award from the King Abdullah University of Science and Technology; and by the European Research Council.

This article was written by Mark Shwartz of the Precourt Institute for Energy at Stanford University.

Comment:

Alberto Salleo, Department of Materials Science and Engineering: (650) 725-1025, asalleo@stanford.edu


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AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.


Disorder can improve the performance of plastic solar cells, Stanford scientists say [ Back to EurekAlert! ] Public release date: 4-Aug-2013
[ | E-mail | Share Share ]

Contact: Mark Shwartz
mshwartz@stanford.edu
650-723-9296
Stanford University

Scientists have spent decades trying to build flexible plastic solar cells efficient enough to compete with conventional cells made of silicon. To boost performance, research groups have tried creating new plastic materials that enhance the flow of electricity through the solar cell. Several groups expected to achieve good results by redesigning pliant polymers of plastic into orderly, silicon-like crystals, but the flow of electricity did not improve.

Recently, scientists discovered that disorder at the molecular level actually improves the polymers' performance. Now Stanford University researchers have an explanation for this surprising result. Their findings, published in the Aug. 4 online edition of the journal Nature Materials, could speed up the development of low-cost, commercially available plastic solar cells.

"People used to think that if you made the polymers more like silicon they would perform better," said study co-author Alberto Salleo, an associate professor of materials science and engineering at Stanford. "But we found that polymers don't naturally form nice, well-ordered crystals. They form small, disordered ones, and that's perfectly fine."

Instead of trying to mimic the rigid structure of silicon, Salleo and his colleagues recommend that scientists learn to cope with the inherently disordered nature of plastics.

Speedy electrons

In the study, the Stanford team focused on a class of organic materials known as conjugated or semiconducting polymers chains of carbon atoms that have the properties of plastic, and the ability to absorb sunlight and conduct electricity.

Discovered nearly 40 years ago, semiconducting polymers have long been considered ideal candidates for ultrathin solar cells, light-emitting diodes and transistors. Unlike silicon crystals used in rooftop solar panels, semiconducting polymers are lightweight and can be processed at room temperature with ink-jet printers and other inexpensive techniques. So why aren't buildings today covered with plastic solar cells?

"One reason they haven't been commercialized is because of poor performance," Salleo said. "In a solar cell, electrons need to move through the materials fast, but semiconducting polymers have poor electron mobility."

To find out why, Salleo joined Rodrigo Noriega and Jonathan Rivnay, who were Stanford graduate students at the time, in analyzing more than two decades of experimental data. "Over the years, many people designed stiffer polymers with the goal of making highly organized crystals, but the charge mobility remained relatively poor," Salleo said. "Then several labs created polymers that looked disordered and yet had very high charge mobility. It was a puzzle why these new materials worked better than the more structured crystalline ones."

X-ray analysis

To observe the disordered materials at the microscopic level, the Stanford team took samples to the SLAC National Accelerator Laboratory for X-ray analysis. The X-rays revealed a molecular structure resembling a fingerprint gone awry. Some polymers looked like amorphous strands of spaghetti, while others formed tiny crystals just a few molecules long.

"The crystals were so small and disordered you could barely infer their presence from X-rays," Salleo said. "In fact, scientists had assumed they weren't there."

By analyzing light emissions from electricity flowing through the samples, the Stanford team determined that numerous small crystals were scattered throughout the material and connected by long polymer chains, like beads in a necklace. The small size of the crystals was a crucial factor in improving overall performance, Salleo said.

"Being small enables a charged electron to go through one crystal and rapidly move on to the next one," he said. "The long polymer chain then carries the electron quickly through the material. That explains why they have a much higher charge mobility than larger, unconnected crystals."

Another disadvantage of large crystalline polymers is that they tend to be insoluble and therefore cannot be produced by ink-jet printing or other cheap processing technologies, he added.

"Our conclusion is that you don't need to make something so rigid that it forms large crystals," Salleo said. "You need to design something with small, disordered crystals packed close together and connected by polymer chains. Electrons will move through the crystals like on a superhighway, ignoring the rest of the plastic material, which is amorphous and poorly conducting.

"In some sense, the synthetic chemists were ahead of us, because they made these new materials but didn't know why they worked so well," he said. "Now that they know, they can go out and design even better ones."

And Salleo offered a final piece of advice. "Try to design a material that can live with as much disorder as possible," he said. "Take the disorder for granted. Personally, I really like disorder. Just look at my office."

###

Other authors of the study are postdoctoral scholar Koen Vandewal of Stanford; Felix Koch and Paul Smith of ETH Zurich; Natalie Stingelin of Imperial College London; and Michael Toney of the SLAC Stanford Synchrotron Radiation Lightsource.

The study was supported by a Stanford Center for Advanced Molecular Photovoltaics award from the King Abdullah University of Science and Technology; and by the European Research Council.

This article was written by Mark Shwartz of the Precourt Institute for Energy at Stanford University.

Comment:

Alberto Salleo, Department of Materials Science and Engineering: (650) 725-1025, asalleo@stanford.edu


[ Back to EurekAlert! ] [ | E-mail | Share Share ]

?


AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.


Source: http://www.eurekalert.org/pub_releases/2013-08/su-dci080113.php

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Saturday, August 3, 2013

Acer Aspire V5-131 Atheros WLAN Driver 10.0.0.75 for Windows 8 64-bit

Specifications:

Processor & Chipset:
- Processor Manufacturer: Intel
- Processor Type: Celeron
- Processor Model: 847
- Processor Speed: 1.10 GHz
- Processor Core: Dual-core (2 Core)

Memory:
- Standard Memory: 4 GB
- Maximum Memory: 8 GB
- Memory Technology: DDR3 SDRAM
- Number of Total Memory Slots: 2
- Memory Card Reader: Yes
- Memory Card Supported: MultiMediaCard (MMC), Secure Digital (SD) Card

Storage:
- Hard Drive Capacity: 500 GB
- Hard Drive Interface: Serial ATA
- Optical Drive Type: No

Display & Graphics:
- Screen Size: 11.6"
- Display Screen Technology: CineCrystal
- Screen Mode: HD
- Screen Resolution: 1366 x 768
- Backlight Technology: LED
- Graphics Controller Manufacturer: Intel
- Graphics Memory Technology: DDR3 SDRAM
- Graphics Memory Accessibility: Shared

Network & Communication:
- Wi-Fi Standard: IEEE 802.11a/b/g/n
- Ethernet Technology: Gigabit Ethernet
- Bluetooth Standard: Bluetooth 4.0 + HS

Built-in Devices:
- Webcam: Yes
- Microphone: Yes
- Finger Print Reader: No

Interfaces/Ports:
- HDMI: Yes
- Total Number of USB Ports: 3
- Number of USB 3.0 Ports: 3
- VGA: Yes
- Network (RJ-45): Yes

Input Devices:
- Keyboard: Yes
- Pointing Device Type: TouchPad

It is highly recommended to always use the most recent driver version available.

Do not forget to check with our site as often as possible in order to stay updated on the latest drivers, software and games.

Try to set a system restore point before installing a device driver. This will help if you installed a wrong driver. Problems can arise when your hardware device is too old or not supported any longer.

Source: http://drivers.softpedia.com/get/NETWORK-CARD/Atheros/Acer-Aspire-V5-131-Atheros-WLAN-Driver-100075-for-Windows-8-64-bit.shtml

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Friday, August 2, 2013

Higher costs hurt Big Oil profits, which could mean higher gas prices

Sorry, Readability was unable to parse this page for content.

Source: http://www.dailyrecord.com/article/20130801/NJBIZ/308010039/1005/RSS

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The Ambitious Nvidia SHIELD Gaming Console with Android Hits ...

Presented at the Consumer Electronics Show in January, the Nvidia SHIELD remains a powerful mobile console with buttons, joysticks and Android features and the ability to stream spectacular PC games remains an ambitious challenge with the proliferation of entertainment devices with equivalent capacity of phones, tablets, laptops and other PC consoles.

Nvidia has put up for sale on Wednesday its new handheld with Nvidia Android Shield. The device, which incorporates the NVIDIA Tegra 4 and 720p HD graphics, is now available in USA and Canada market at $299.

The console features the Nvidia Tegra mobile processor 4 720p HD graphics and high quality stereo sound. In addition, the new Nvidia Shield allows the user to transfer the image of their favorite games from the PC to the console via Wi-Fi and play in it. The gaming console has a screen 5-inch touchscreen (720p) connected to what looks like an Xbox controller. Under the hood is installed an Nvidia processor and Android 4.2 Jelly Bean operating system. It also has 2GB RAM and 16GB of storage (expandable with microSD). Moreover, it has the usual smart specs like integrated GPS, Wi-Fi, mic and the works.

PC users looking for a solution to streaming games may find that Shield keeps its promises?if they have already invested in an Nvidia graphics card and a router worthy of the name.

So far, early reviews for the Nvidia Shield have been generally positive. Technology-savvy sites such as AnandTech, Engadget, Laptopmag, Slashgear, Tom?s Hardware and The Verge give Shield a pretty good reviews due to the hardware used with Tegra 4 processor.

Google Play Compatible

Nvidia Shield seeks to provide a gaming experience closer to that of portable consoles but taking full advantage of a system like Android. With 35 SHIELD games optimized for Tegra and over 65 additional Android games with built-in controller support, a host of talented development studios have delivered big time with their games for Tegra devices. The games include OneQ Soft?s Blood Sword: Sword of Ruin, inXile?s Choplifter HD, Niffler?s Chuck?s Challenge 3D, Strawdog Studios?s Space Ark, and Ravn Studios?s Tainted Keep.

Those who purchase Shield will receive a free gift of two games: Sonic 5 Episode II THD and Expendable Rearmed. You can also download and run virtually any application available on the Google Play Store, including almost 130 games optimized for the buttons and controllers of Nvidia Shield.

While pretty much every game on Tegra Zone will play very nicely on Nvidia?s Shield, there are plenty of games outside of the Tegra Zone that will work with the Shield. Nvidia posted a list of games currently available that play well on their new handheld gaming device that are not on Tegra Zone or Tegra exclusive including Alpha Wave Demo, Andor?s Trail, Another World, Avenger, Bike Mania Moto Free ? Racing, Dark Incursion, Drag Racing, Gachinko Tennis, Legends of Yore Full, Monster Madness: Grave Danger, Zenonia and others.

In addition, Bitsquid launched a game engine for NVIDIA SHIELD to enable game developers to target the new Tegra 4-powered gaming and entertainment portable. The flexibility of the engine makes it usable for a large variety of games targeting a wide variety of platforms.

Source: http://siliconangle.com/blog/2013/08/01/the-ambitious-nvidia-shield-gaming-console-with-android-hits-stores/

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California fishermen file suit in effort to keep 'otter-free zone'

Commercial fishermen have filed a lawsuit in federal court challenging the U.S. Fish and Wildlife Service for abandoning a program to create an "otter-free zone" in Southern California coastal waters that sustain shellfish industries.

The lawsuit, filed this week by the Pacific Legal Foundation on behalf of harvesters of sea urchin, abalone and lobster south of Point Conception, accuses the agency of illegally terminating the program without congressional approval or authorization. Otters are voracious eaters of shellfish.

Federal officials ended the program in January after determining that capturing and trans-locating sea otters that wander into the "otter-free zone" was hurting efforts to protect and recover the species ? even as it succeeded in protecting shellfish fisheries.

The sea otter population has not risen much in recent years, as the creatures suffer from disease, parasites, inadequate food supplies, shark bites and the occasional bullet wound. An estimated 2,792 now exist off the California coast.

Tuesday, a coalition of environmental groups led by Friends of the Sea Otter announced that it would intervene in the case on behalf of federal wildlife authorities.

"The problem is that the shellfish industry flourished after sea otters were all but wiped out by the fur trade," said Jim Curland, advocacy program director of the nonprofit Friends of the Sea Otter. "Now, if the fishermen's lawsuit were to prevail, our concern is that harm, injury and even death to sea otters would follow."

Pacific Legal Foundation attorney Jonathan Wood argued that the no-otter zone was needed to prevent the furry, button-nose marine mammals from "ravaging fragile nearby fisheries and destroying local economies."

"We're not attacking sea otters," Wood said. "It's just that without a sea otter management zone, the fisheries our clients rely on will be decimated in 10 to 20 years."

Plaintiffs include the California Abalone Assn., the California Lobster and Trap Fishermen's Assn., Commercial Fishermen of Santa Barbara, and the California Sea Urchin Commission, a state panel dedicated to promoting education about the nutritional value of the sea urchin.

"This case is about balance in environmental policies, and adherence to the rule of law," Wood said.

Congress established the "otter-free zone" in the late 1980s as part of an effort by federal wildlife authorities to move 140 otters from Monterey Bay to San Nicolas Island, about 60 miles off the coast of Ventura County.

State and federal marine biologists said the program was necessary because sea otters could be threatened with extinction if their breeding grounds off Monterey were hit with an oil spill or disease. They also figured that the small, rocky island was perfectly suited for the 40- to 60-pound mammals because its pristine coastal waters teemed with their favorite foods ? abalone, crabs, lobster, mussels and sea urchins.

In a deal with fishermen who worried that moving otters to the island could interfere with commercial harvesting activities, the government declared waters south of Point Conception off limits to otters.

Scientists estimate that about 16,000 Southern sea otters once lived along the California coast before they were hunted nearly to extinction in the 18th and 19th centuries for their pelts. The federal government declared them threatened with extinction in 1977 and protected them under the Endangered Species Act.

louis.sahagun@latimes.com

Source: http://feeds.latimes.com/~r/latimes/news/science/~3/BU9UVA8f08o/la-me-otters-20130802,0,1283000.story

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North Texas Man Discovers World War II-Era Shell

Updated: Thursday, August 1 2013, 11:56 AM CDT

A North Texas property owner discovered a World War II-era artillery shell on his land near Corsicana.

Ubaldo Mijares and his sons were clearing brush when he noticed something sticking out of the base of a tree.

?I never seen nothing like that,? he said. ?At first, I think it?s a bottle for oil.?

But when he dug it up and showed it to his boss, he found out the two-foot tall rusty relic was much more than that.

?He said it?s a bomb,? Mirarjes said.

He contacted the Navarro County Sheriff?s Department who called in federal help. Fort Hood sent a team to examine it and they determined it was a 155mm howitzer shell dating back 70 years or more.

The team destroyed the shell but the mystery of how it got there in the first place remains.

Sheriff Elmer Tanner theorizes that someone simply buried it under the tree decades ago. He also said that Mijares is lucky he and his boys were not hurt.

?We certainly believed it was a live round and easily could have caused damage and destruction had it been set off,? Sheriff Tanner said. ?I?ve never seen anything like this in my law enforcement tenure here in the Sheriff?s office.?

North Texas Man Discovers World War II-Era Shell

Source: http://www.keyetv.com/news/features/top-stories/stories/north-texas-man-discovers-world-war-iiera-shell-10915.shtml

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