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Superlubricity speeds up microtechnology

2013-07-02


A collaboration between researchers at Tsinghua University and Tel Aviv University shows how a phenomenon called superlubricity, long thought to be of purely academic interest, can enable microscopic devices to move at speeds of up to 90km/h, as fast as cars on a highway.

CNMM-Research News-Superlubricity speeds up microtechnology


Imagine there’s no friction. It’s not easy, even if you try. Friction gives shoes and tires the grip to move people and cars forward. Without it, roads would be more slippery than ice. But friction is also a great waster of energy. To reduce it, lubricants are used in everything from door hinges to car engines, at considerable expense. Despite lubrication, estimates are that over one third of the fuel energy used in passenger cars is burnt to overcome friction[1], providing no useful power at all.

Things only get worse as moving parts shrink from the size of cars to the size of microchips. On the microscopic scale, the ratio of the surface area of objects to their total volume increases dramatically. This means that friction, which is a surface phenomenon, overwhelms the tendency of moving objects to keep moving, which depends on their mass and hence their volume. And introducing lubricants in microscopic machines is tricky, precisely due to their small size.

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郑泉水 教授 Professor Zheng Quanshui
Photo credit: Chinese society of Theoretical and Applied Mechanics

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Yang Jiarui,PhD student Tsinghua University

So an article published in Physical Review Letters last week, by Jiarui Yang et al. [110, 255504 (2013)], highlighted with a Synopsis by Physics website[2], represents a breakthrough in demonstrating the practical utility of a phenomenon called superlubricity – long considered a theoretical concept that could only be demonstrated under extreme conditions – in overcoming friction on the microscopic scale.

The article builds on work by the group of Quanshui Zheng, director of the Centre for Nano and Micro Mechanics (CNMM) at Tsinghua University. The group previously demonstrated that microscopic structures made of crystalline graphite, when sheared, restore themselves to their original shape to minimize the total exposed surface[3].

This self-retraction phenomenon, as Prof. Zheng and his co-workers have shown, is due to a special structure occurring at the sheared interface, called a twist boundary. This structure means that the crystalline lattice of carbon atoms either side of the sheared interface is misaligned. So rather than neatly locking into place, as layers of carbon atoms do in a normal graphite crystal, the layers at this interface slide easily past each other with almost no friction at all: this is what superlubricity means.

In the latest work, which is a collaboration with an expert in the theory of friction, Michael Urbakh at Tel Aviv University, lead author Jiarui Yang built a device to detect the speed at which the self-retraction occurred, using a laser technique precise and fast enough to catch the fleeting motion in such small objects. Prof. Urbakh remarks “I have been studying superlubricity from a theoretical perspective for years, so suddenly seeing the effect in action like this under an ordinary microscope is a major step forward”.

The results show maximum speeds of 25m/s (90km/h) for a thin, square graphite wafer just three micrometers on a side, as it self-retracts after being sheared by a microprobe. Intriguingly, the highest speeds are reached by heating the graphite to over 100 °C. The reason put forward for this by the researchers, is that the increased jiggling of atoms due to temperature enables the sliding surfaces to overcome inevitable atomic-scaled defects that occur at the interface.

Prior to this work, the velocity of objects exhibiting superlubricity was typically measured in micrometers per second – a snail’s pace. And this was under conditions of ultra-high vacuum, for a specially controlled interface on the scale of nanometers. Commenting on the breakthrough, Prof. Zheng notes that “observing high-speed superlubricity on the much larger scale of micrometers, and even under normal atmospheric conditions, immediately raises the possibility of practical applications”.

Possible uses include future miniaturized hard disk drives and microscopic high-frequency oscillators for telecommunications, in other words microscopic devices whose performance depends on high-speed motion.



For more information about superlubricity here:

Superlubricity - Wikipedia, the free encyclopedia


Previous work done by Prof Zheng:

Nanomachines could benefit from superlubricity
Nanomachines could benefit from superlubricity - physicsworld.com
 
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Hepatic stem cells to cure terminal liver diseases: study

English.news.cn 2013-07-19

Xinhuanet


SHANGHAI, July 19 (Xinhua) -- Hepatic stem cells, produced by a patients' own cells, could possibly help cure end-stage liver diseases, a study led by Chinese scientists has shown.

The four-year study on mice, led by Prof. Hu Yiping of the Department of Cell Biology under the Shanghai-based Second Military Medical University, has been published in the latest online version of the U.S. "Cell Stem Cell" journal, 18 July 2013 issue.

The article, titled "Reprogramming Fibroblasts into Bipotential Hepatic Stem Cells by Defined Factors," marks a breakthrough in China's hepatic stem cells study, said a statement from Hu's team.

Various liver diseases, including those at the terminal stage, would be curable by using the patients' own cells to produce hepatic stem cells and repopulating them into the patients' body, if the clinical research makes key progress, according to He Zhiying, an associate professor of the team.

Although the number of original hepatic stem cells in human liver is small, they play an important role in maintaining the organ's structure and performance.

Funded by the Chinese government, the research team reprogrammed fibroblasts and established a laboratory-based system of producing hepatic stem cells.

The hepatic stem cells produced in this way can be augmented in the lab and then used to repair the injured liver, according to the statement.

It added that the research result lays new foundations for liver disease treatment, development of new drugs and tissue engineering research.

Prof. Hu started research on hepatic stem cells in the early 1990s and focused on the relation between the cells and liver diseases.

He gradually realized that new cell therapy based on hepatic stem cells could be an effective cure for end-stage liver illnesses



CELL Stem Cell

18 July 2013

Reprogramming Fibroblasts into Bipotential Hepatic Stem Cells by Defined Factors

Authors and Affiliations

Bing Yu-1,2, Zhi-Ying He-1,2, Pu You-1,2, Qing-Wang Han-1,2, Dao Xiang-1,2, Fei Chen-1,2, Min-Jun Wang-1,2, Chang-Cheng Liu--1,2, Xi-Wen Lin-3, Uyunbilig Borjigin-4, Xiao-Yuan Zi-1,2, Jian-Xiu Li-1,2, Hai-Ying Zhu-1,2, Wen-Lin Li-1,2, Chun-Sheng Han-3, Kirk J. Wangensteen-4, Yufang Shi-6,7, Li-Jian Hui-8, Xin Wang-4,8,9, Yi-Ping Hu-1,2

1-Department of Cell Biology, Second Military Medical University, Shanghai 200433, China
2-Center for Stem Cell and Medicine, The Graduate School, Second Military Medical University, Shanghai 200433, China
3-State Key Laboratory of Reproductive Biology, Institute of Zoology, Chinese Academy of Sciences, Beijing 100101, China
4-The Key Laboratory of National Education Ministry for Mammalian Reproductive Biology and Biotechnology, Inner Mongolia University, Huhhot 010070, China
5-Department of Medicine, Division of Gastroenterology, University of Pennsylvania, Philadelphia, PA 19104, USA
6-Key Laboratory of Stem Cell Biology, Institute of Health Sciences, Shanghai Institutes for Biological Sciences, Chinese Academy of Sciences/Shanghai Jiao Tong University School of Medicine, Shanghai 200025, China
7-Child Health Institute of New Jersey and Department of Pharmacology, Robert Wood Johnson Medical School, University of Medicine and Dentistry of New Jersey, 89 French Street, New Brunswick, NJ 08901, USA
8-Laboratory of Molecular Cell Biology, Institute of Biochemistry and Cell Biology, Shanghai Institute for Biological Sciences, Chinese Academy of Sciences, Shanghai 200031, China
9-Department of Laboratory Medicine and Pathology, University of Minnesota, Minneapolis, MN 55455, USA




上海第二军医大学 Second Military Medical University, Shanghai


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中科院 上海生物研究所 Shanghai Institute for Biological Science, China Academy Of Science


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中国科学院上海生物化学与细胞生物学研究所
Shanghai Institute of Biochemistry and Cell Biology

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Chinese researchers use the Kinect to translate sign language to text
By Grant Brunner on July 19, 2013

Chinese researchers use the Kinect to translate sign language to text | ExtremeTech

Microsoft Research Asia and the Institute of Computing Technology at the Chinese Academy of Sciences have teamed up to use Kinect for Windows to effectively track complex hand motions in 3D space. By combining the data from both the RGB camera and the depth-sensing infrared camera in the Kinect, these researchers were able to develop an impressive system to aid communication between the deaf and the hearing.

中国科学院 计算技术研究所 Institute of Computing Technology at the Chinese Academy of Sciences

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Scientists discover a solution for making environmental friendly lead cells


A green lead hydrometallurgical process based on a hydrogen-lead oxide fuel cell
http://www.nature.com/ncomms/2013/130719/ncomms3178/full/ncomms3178.html

22-Jul-13

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Extract

The automobile industry consumed 9 million metric tons of*lead*in 2012 for lead-acid batteries. Recycling*lead*from spent lead-acid batteries is not only related to the sustainable development of the lead industry, but also to the reduction of*lead*pollution in the environment. The existing lead pyrometallurgical processes have two main issues, toxic*lead*emission into the environment and high energy consumption; the developing hydrometallurgical processes have the disadvantages of high electricity consumption, use of toxic chemicals and severe corrosion of metallic components. Here we demonstrate a new green hydrometallurgical process to recover*lead*based on a hydrogen-lead oxide fuel cell. High-purity*lead, along with electricity, is produced with only*water*as the by-product. It has a >99.5%*lead*yield, which is higher than that of the existing pyrometallurgical processes (95–97%). This greatly reduces*lead*pollution to the environment.


Authors and Affiliations
State Key Laboratory of Chemical Resource Engineering, Beijing University of Chemical Technology, Beijing 100029, China
Junqing Pan

Electrochemical Energy Laboratory, Materials Science and Engineering Program, The University of Texas at Austin, Austin, Texas 78712, USA
Junqing Pan, Wei Li, James Knight & Arumugam Manthiram

National Fundamental Research Laboratory of New Hazardous Chemicals Assessment and Accident Analysis, Beijing University of Chemical Technology, Beijing 100029, China
Yanzhi Sun


北京化工大学 Beijing University of Chemical Technology


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China buys Thielert diesel engine company out of bankruptcy

Purchase made by AVIC which owns Continental

July 23, 2013 By Alton K. Marsh

The company Aviation Industry Corporation of China (AVIC) has bought Thielert Aircraft Engines out of bankruptcy in Germany, adding it to a stable of manufacturers that includes Continental Motors and Cirrus Aircraft.

Continental now has a full family of diesel engines. Continental’s 230-horsepower diesel engine certified in December 2012 is now part of a complete family of diesel engines that Continental President Rhett Ross said will all be marketed under the Centurion name. Gasoline engines will continue to be marketed with the O/IO/TSIO moniker, he added.

"All engines, gasoline or diesel will be marketed under the Continental Brand and can be ordered directly from our 1-800 number or website," Ross said in an email. "We will be working over the next few weeks to better integrate sales and support functions so that we can operate on a global basis."

Thielert (to be known in the future as Technify Motors) manufactures 135- and 155-hp diesel engines. Before bankruptcy, Thielert mounted a 350-hp diesel prototype engine on several Cessna 206 aircraft. Development was stalled during the Thielert bankruptcy. Thielert has a distribution and warranty company called Centurion that was created as part of German bankruptcy regulations. Both will be under the Technify Motors banner.

Ross says in a special AOPA Pilot report on diesel technology in the August issue that his company has staked its future on diesel engines. That also means the company has staked its future on foreign sales, since it is expected that worldwide sales of diesel engines will far outpace those in the United States. That’s another point made in the special Pilot report, "Will we all be flying diesels?“

Observers had expected the purchase by AVIC would be completed in March, but one industry observer said Germany wanted to move cautiously on deals with China.

Continental’s 230-hp engine is based on first-generation SMA technology. The type certificate says that engine is limited to 12,500 feet, but that altitude is expected to quickly increase. SMA shared its diesel secrets, but Continental made its own parts for the engine. Customers for the engine may be announced at EAA AirVenture 2013.

In 2008 there were 24 bidders for Thielert, but the economic crisis caused a delay in the sale.

China buys Thielert diesel engine company out of bankruptcy - Aircraft Owners and Pilots Association
 
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Hope for a green China and the world

China scientists discovered a new chemical helping plants fight drought

AgroNews

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Photo credit: sina.com

China scientists discovered a new chemical that mimicks ABA, a key phytohormone that helps plants cope with drought and other environmental stresses.

The phytohormone abscisic acid (ABA) plays a critical role in plants to combat abiotic stresses, such as drought, salinity and extreme temperatures. Data from the World Bank shows that drought stress accounts for more than half of global crop losses and the situation is getting worse with climate changes presumably caused by global warming. ABA can be used in agriculture to help different crops survive severe drought. However, the use of ABA in agricultural applications has been hampered by its chemical instability and expensive cost of industrial production of ABA.

A collaborative research led by Dr. Jian-Kang Zhu of the Shanghai Center for Plant Stress Biology, CAS, has discovered a chemical alternative, ABA Mimics 1 (AM1), that can mimic ABA function in enhancing drought resistance in plants. The findings were published in the latest issue of Cell Research (2013, Jul 10.1038/cr.2013.95).

AM1 is a sulfonamide-based structural analog of ABA and pyrabactin; it was shown to be effective in boosting drought resistance in plants with similar characteristics to that induced by ABA. AM1 can mimic the function of ABA through binding to multiple members of the PYR/PYL family of ABA receptors, thereby inhibiting the activity of protein phosphatase 2Cs (PP2Cs) and activating the downstream ABA signaling pathway.

The structural analyses of AM1 in complex with PYL2-HAB1 revealed an AM1-ligand mediated gate-latch-lock interacting network, a structural feature that is conserved in the ABA-bound receptor/PP2C complex.

In vivo assays further demonstrated that AM1 is capable of activating the expression of ABA-responsive genes, preventing transpirational water loss from leaves and dramatically enhancing drought resistance in plants.

Furthermore, AM1 is easily synthesized and more resistant to photolysis than ABA, indicating that AM1 has a great potential to become an ABA replacement in agricultural applications for stabilizing crop yield and conserve previous water resource under environmental stresses.


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Photo credit: Xinjiang Bazhou Government



More of the above in detail here:

Cell Research - Abstract of article: An ABA-mimicking ligand that reduces water loss and promotes drought resistance in plants

Minjie Cao, 1,*, Xue Liu1,2,*, Yan Zhang,3, Xiaoqian Xue,3,4, X Edward Zhou,5, Karsten Melcher,5, Pan Gao,1, Fuxing Wang,1, Liang Zeng,1, Yang Zhao,6, Yang Zhao,7, Pan Deng,8, Dafang Zhong,8, Jian-Kang Zhu,1,6, H Eric Xu,2,5 and Yong Xu,3

1-Shanghai Center for Plant Stress Biology and Shanghai Institute of Plant Physiology and Ecology, Shanghai Institutes of Biological Sciences, Chinese Academy of Sciences, 300 Fenglin Road, Shanghai 200032, China
2-VARI-SIMM Center, Center for Structure and Function of Drug Targets, Key Laboratory of Receptor Research, Shanghai Institute of Materia Medica, Chinese Academy of Sciences, Shanghai 201203, China
3-Institute of Chemical Biology, Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences, No.190 Kaiyuan Avenue, Guangzhou Science Park, Guangzhou, Guangdong 510530, China
4-Shenyang Pharmaceutical University, No.103 Wenhua Road, Shenhe District, Shenyang, Liaoning 110016, China
5-Laboratory of Structural Sciences, Center for Structural Biology and Drug Discovery, Van Andel Research Institute, 333 Bostwick Ave., N.E., Grand Rapids, MI 49503, USA
6-Department of Horticulture and Landscape Architecture, Purdue University, West Lafayette, IN 47906, USA
7-Shanghai Institute of Plant Physiology and Ecology, Shanghai Institutes of Biological Sciences, Chinese Academy of Sciences, 300 Fenglin Road, Shanghai 200032, China
8-Shanghai Institute of Materia Medica, Chinese Academy of Sciences, Shanghai 201203, China
Correspondence: Jian-Kang Zhu, E-mail: zhu132@purdue.edu; H Eric Xu, E-mail: Eric.Xu@vai.org; Yong Xu, E-mail: xu_yong@gibh.ac.cn

*These two authors contributed equally to this work.

Received 26 April 2013; Revised 18 June 2013; Accepted 3 July 2013
Advance online publication 9 July 2013



中国科学院 上海药物研究所 Shanghai Institute of Materia Medica, Chinese Academy of Sciences

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中国科学院 广州生物医药与健康研究院 化学生物学研究所
Institute of Chemical Biology, Guangzhou Institutes of Biomedicine and Health, Chinese Academy of Sciences


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上海植物逆境生物学研究中心
Shanghai Center for Plant Stress Biology, China Academy of Sciences

中国科学院 上海生命科学研究院 植物生理生态研究所
Shanghai Institute of Plant Physiology and Ecology, Shanghai Institutes of Biological Sciences, Chinese Academy of Sciences


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沈阳药科大学 Shenyang Pharmaceutical University

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New campus plan

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Chinese spending billions of dollars on science & technology amounts to nothing. Here is an example.
Legacy Of Failure Is Hard To Shake

July 24, 2013: Russia and China continue to have problems getting their latest SLBM (Sea Launched Ballistic Missile) designs to work reliably. The Russian Bulava and Chinese JL-2 have both been announced as ready for use yet neither has actually entered service. This is a common pattern with Russian and Chinese military technology and is especially true with SLBMs.


Strategic Weapons: Legacy Of Failure Is Hard To Shake

There seems to be an unending series of problems with the new Russian and Chinese SLBMs. The latest Russian SLBM, the Bulava (also known as R-30 3M30 and SS-NX-30), was almost cancelled because test flights kept failing. The Bulava finally successfully completed its test program on December 23rd, 2011. That made 11 successful Bulava test firings out of 18 attempts. The last two missiles make five in a row that were successfully fired. As a result of this, the Bulava has been accepted into service, with a development test firing success rate of 61 percent. But there are still problems to be worked out and more test firings are coming. In early 2012 Russia announced that its SSBNs (nuclear powered ballistic missile boats) would resume long range "combat patrols" within a year. On schedule, the Russian Navy finally accepted its first new Borei class SSBN (Yury Dolgoruky) for service last December 30th. Thus, it appears that the newly commissioned Yury Dolgoruky will be the first Russian SSBN in many years to make a long range cruise, as soon as it has a working SLBM to arm it. The Russians will probably not announce this until it’s all over, lest something go wrong at sea. So far there has been no announcement one way or the other.

Then there is the Chinese JL (Julang) 2 SLBM, which was supposed to enter service five years ago and still hasn’t. This missile has had a lot of problems, as have the SSBNs that carried them. The 42 ton JL-2 has a range of 7,000 kilometers and would enable China to aim missiles at any target in the United States from a 094 class SSBN cruising off Hawaii or Alaska. Each 094 boat can carry twelve of these missiles, which are naval versions of the existing land based 42 ton DF-31 ICBM. No Chinese SSBN has ever gone on a combat cruise because these boats have been very unreliable in addition to having no dependable SLBMs to carry. The Type 94 class sub was seen recently undergoing what appears to be sea trials but it is unclear if that was a success. America, Russia, Britain, and France have all sent SSBNs out on patrols and still do. The U.S. has had SSBNs going out with nuclear armed, and ready to fire, missiles for over half a century. What is going on with China? There appears to be an unending supply of technical and political (fear of failure) problems. Russia and China are having similar problems with many other new ballistic and cruise missile designs that have been reported as out of development but not yet in service because additional problems showed up.

It doesn’t always have to be that way, but you don’t often hear about complex weapons that consistently perform flawlessly. They do exist. For example, test firings of production models of the U.S. Navy Trident II SLBM have never failed. Trident II is the standard SLBM for U.S. SSBNs. There have been 143 of these missile launches, which involve an SSBN (ballistic missile carrying nuclear sub) firing one of their Trident IIs, with the nuclear warhead replaced by one of similar weight but containing sensors and communications equipment.

The test results for the Trident while in development were equally impressive, with 87 percent successful (in 23 development tests) for the Trident I and 98 percent (49 tests) of the Trident II. The Trident I served from 1979-2005, while the Trident II entered service in 1990.
 
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Where is India?Where does India stand in relation to China?Dark age?:omghaha:

Huawei to Bring 5G Technology in 2020?

By Vittorio Hernandez | July 23, 2013 9:48 AM EST

Video:Huawei to Bring 5G Technology in 2020? (VIDEOS) - International Business Times

The frequently belittled Chinese tech company Huawei may just surprise techies and take centre stage in 2020 when it makes available 5G technology. The hint of being on the forefront of technological advancement from the Chinese tech giant comes even if 4G has barely landed.

Tony Wen, Huawei head of 5g technology development, said fibre broadband connection speeds from the next-gen mobile network with possible download speeds of 100Mbps is within sight in the next 7 years.

Mr Wen said Huawei has 200 people working on the 5G project and it allocated a specified amount for the research and development of 5G technology.

South Korean tech giant Samsung has about the same timetable of a commercial roll-out of a 5G technology by 2020.

But before 5G arrives, Huawei is conducting a trial run to test the speed of its 4G technology on the high-speed MagLev train in Shanghai. The Chinese tech firm deployed an LTR network on the train which travels from the centre of the Shanghai district to the international airport. The train achieved a speed of up to 431 km per hour throughout the length of its 31-kilometre track.

Huawei is providing equipment to 85 networks that have begun moving toward high-speed long term evolution or 4G networks.
 
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Where is India?Where does India stand in relation to China?Dark age?:omghaha:

Huawei to Bring 5G Technology in 2020?

By Vittorio Hernandez | July 23, 2013 9:48 AM EST

Video:Huawei to Bring 5G Technology in 2020? (VIDEOS) - International Business Times

The frequently belittled Chinese tech company Huawei may just surprise techies and take centre stage in 2020 when it makes available 5G technology. The hint of being on the forefront of technological advancement from the Chinese tech giant comes even if 4G has barely landed.

Tony Wen, Huawei head of 5g technology development, said fibre broadband connection speeds from the next-gen mobile network with possible download speeds of 100Mbps is within sight in the next 7 years.

Mr Wen said Huawei has 200 people working on the 5G project and it allocated a specified amount for the research and development of 5G technology.

South Korean tech giant Samsung has about the same timetable of a commercial roll-out of a 5G technology by 2020.

But before 5G arrives, Huawei is conducting a trial run to test the speed of its 4G technology on the high-speed MagLev train in Shanghai. The Chinese tech firm deployed an LTR network on the train which travels from the centre of the Shanghai district to the international airport. The train achieved a speed of up to 431 km per hour throughout the length of its 31-kilometre track.

Huawei is providing equipment to 85 networks that have begun moving toward high-speed long term evolution or 4G networks.

actually your article is misdirect. Samsung already made 5G, and they are now testing it. Reported Speed as 1.056Gbps to a distant up to 2 kilometre. (it's 1000Mbps not 100Mbps for 5G speed.......)

5G Is Already Ridiculously Fast - SourceFed - SourceFed
 
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Unbelievable!

This thread all for Chinese science and innovations has attracted some jealous incapable indians et al and the unscrupulous to troll!
 
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Low-Water Lunch: A Chinese Breakthrough on Irrigation?

JULY 8, 2013

http://www.theworld.org/

Growing more food with less water will be one of the biggest challenges in the coming era of surging populations and increasing climate disruption. In China, scientists say they’ve developed a new irrigation method that’s twice as efficient as today’s best technology, part of an increasingly urgent effort by researchers around the world to meet the water challenge.

No lunch is complete without water – the water you drink, the water that helped grow the wheat in your sandwich bread, and the water that helped grow the vegetables or meat between the slices.

China’s got a problem here. It has a chronic and growing water shortage, and on the arid northern plain, where many thirsty crops are grown – the water table is plummeting, down hundreds of feet within living memory. Most of China’s water use goes to agriculture, and much of that water is used inefficiently.

Surface irrigation is king in China – and on a farm on the outskirts of Beijing, a mushroom farmer is letting water gush from a hose – at high noon – onto a long raised mound of soil

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Normal surface irrigation on a controlled patch of experimental farm. (Photo: Mary Kay Magistad)

The inefficient use of water is common in China, but this is no common farm. A stone’s throw away is another long, raised mound of soil, with no water source in sight. Yet, the mushrooms underneath the canvas covering are firm and healthy, and the soil is slightly moist.

The first field is the ‘control’ – which shows what happens when you do normal surface irrigation. The second field is trying out a new underground irrigation system, where the plants roots draw only the water they need. Gu Yunxia, the agronomist managing this project, is impressed with what the new system makes possible.

“It cuts down on pests, and fungus and weeds,” she says. “We save a huge amount of water, and the vegetables also have great flavor.”

This system was dubbed ‘trace irrigation,’ by its inventor, Beijing native and businessman Zhu Jun.

“I found if I put the chopsticks in water, and took them out, there was a little water going up between the chopsticks,” he says. “And if I held the chopsticks higher, the water goes higher. And I realized, that’s actually the capillary force that I learned in the textbooks in primary school. And maybe that is a good way for irrigation.”

Capillary force, for those who might be rusty on what they learned in school, is when molecules are so attracted to each other that they can pull liquid against the force of gravity – kind of the way a kerosene lamp works. In this case, it’s the roots of a plant pulling water, and when they have enough, they stop pulling.

This system uses PV pipes, buried a foot or even deeper in soil. The pipes get narrower, and narrower, until they’re like thin straws, with something that looks like a tiny showerhead at the end, with little white threads coming out of it. These pipes are buried in the soil – and the plant sucks the moisture it needs from these threads.

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Trace Irrigation inventor Zhu Jun holds one of his applications for a patent on the technology. Zhu has so far been granted patents in China, New Zealand and Japan, and has applications pending in the United States and elsewhere. (Photo: Mary Kay Magistad)

Zhu says, he has worked on this system for about a decade. Before that, he’d worked on a technology called “dry water” – encasing water droplets in silicon. A couple of pounds of the stuff is enough to grow a tree in a desert for 100 days – one of many solutions that the world’s scientists have been busy developing, to cope with a growing global water shortage.

Another is underground drip irrigation – similar to Zhu’s system, but with a recurring problem. He says, in such systems, there’s a small and irregular flow of water, so pipes can easily get clogged. And that’s been a limit on the otherwise revolutionary technology of drip irrigation that Israel first introduced decades ago.

“I found that if the capillary pipe gets too small, no matter how you purify the water, the particles in the water will still block the pipe,” he says. “That was a bottleneck for me, for awhile.”

Eventually, he experimented with a double-membrane to filter particles, and found a combination that wouldn’t clog, even with very low water pressure. That’s one of the innovations for which he’s seeking patents.

Zhu says his system saves 70 or more of the water used in surface irrigation in China, and 30 to 50 percent compared to drip irrigation. Those are big claims, says Bob von Bernuth, the education director of the US Irrigation Association.

“Well, I guess anytime someone claims to save 50 percent of water, especially over drip irrigation, one becomes immediately skeptical,” von Bernuth says. “I can tell you that it’s possible, but unlikely….it suggests they weren’t doing a very good job of saving water to begin with.”

In China, that’s true. Many farmers don’t consider the true cost of the water they’re using, because they just divert rivers or drill wells to get it, so they often don’t use water efficiently.

And in China, there’s been significant interest in Zhu’s new system. He has already received two patents his China and one in New Zealand and Japan for trace irrigation, and he has applications pending in dozens of other countries, including the United States. Von Bernuth reviewed Zhu’s US patent application, and said it doesn’t seem that different from underground drip technology already in use. But Zhu Jun says it is, and local Chinese governments are keenly interested.

Beijing’s municipal Science & Technology Commission, and its Municipal Agriculture Commission started doing their own trace irrigation trials six years ago, liked the results, and invested. The city of Wuhan has offered him land to build a factory, and the government of Xinjiang – one of China’s driest regions – is now growing test crops. If all goes well, they plan to use the system on a larger scale next year. Saving half the water, without a fussy system that needs electrical power and lots of human supervision, would be a godsend for growing crops in the desert.

IrrigationInGreenhouseAgronomistKimJiSeokPointsToSoilWithTraceIrrigationThatIsMoistButNotWet.jpg

Agronomist Kim Ji-Seok points to soil with trace irrigation that is moist, but not wet. (Photo: Mary Kay Magistad)

Meanwhile, Kim Ji-Seok, a Korean agronomist, was so intrigued by this new technology that he left his job with agribusiness giant Syngenta to join Zhu company Puquan – which means ‘spreading spring.’ He takes me for a tour around the experimental farm on the edge of Beijing – past walnut groves, peach trees, corn, cotton and peanut fields.

“The government is quite excited about the result last year,” he says. Excited enough to greenlight bigger scale trials – growing grapes, watermelon, jujubes, and licorice.

And Kim’s excited too. It’s not so often an agronomist gets to work on what just might prove to be a game-changing technology that could help solve one of China’s – and the world’s — biggest problems – lack of adequate water — and maybe one or two other problems, to boot.

We walk into a greenhouse, with rain pattering overhead. One section of the greenhouse– which uses drip irrigation – feels humid. The other section, using trace irrigation, doesn’t. Kim says, that’s because there’s less water in the soil to evaporate up.

“In this way, the diseases decrease,” he says. “So we use less pesticides, less fungicides than drip line.”

And half as much fertilizer, too. If the ‘trace irrigation’ system is used on a large scale throughout China, that would be good news for China’s lakes and rivers and groundwater, now choked with agricultural runoff.

Kim also shows off how uniformly attractive the vegetables on the trace irrigation side of the greenhouse are, compared to those using drip irrigation.

“If you use a drip line, the first one (along the line) is very big and tasty,” he says. But then they get smaller, and at the end, you get a tiny one. If it’s not uniform, you cannot sell them.”

It’s time to break for lunch, and Kim suggests we start with crudités – a little trace irrigation-grown celery. I crunch into mine and declare it delicious. Kim grins broadly. And if this is a taste of things to come in China, growing better produce with less fertilizer, pesticide and much less water, there’s certainly something to smile about.

“What’s for Lunch” is the latest chapter in “Food for 9 Billion,” a two-year project spearheaded by Homelands Productions and the Center for Investigative Reporting, and broadcast partners PBS NewsHour and American Public Media’s Marketplace.
 
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Unbelievable!

This thread all for Chinese science and innovations has attracted some jealous incapable indians et al and the unscrupulous to troll!

Well, I am just pointing out the Article does not have the UPDATED information, Samsung MADE 5G May this year and the Tested Speed for 5G is 1.056 Gbps over 2KM, rebuttal welcome

2KM means it's nearly unusable, maybe it's only for LAN/WAN not internet

Well, as they say they are still testing the 5G capability, the range could be extended and/or speed may be dialled back for a longer lambda frequency, who knows.

But one thing for sure, 100MBps is 4G speed, not 5G speed.

In theory, 4G speed can reach 672 Mbps on paper, the fastest actual 4G network is LTE-Advance standard, claim was 1Gbps peak download and 500Mbps peak upload but actually they can do 300 Mbps downstream and 50Mbps upstream

LTE Advanced - Wikipedia, the free encyclopedia

2 km will be more than the usual LAN/WAN usage, a standard land size (front) in Australia is 10 meter per house, 2 Km would have cover 200 household (without road) and the Australian standard is already the largest. There are no point connecting LAN/WAN with 2 Km range.

Also, cell tower often have less than 2Km range in metro city anyway so it is for mobile internet (Standard Metro Tower range in Sydney is 1.5 km), not LAN or WAN or even Wifi

For example, the current 802.11n Wifi frequency have an indoor range of 70 meter.

http://en.wikipedia.org/wiki/IEEE_802.11n-2009#Comparison
 
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actually your article is misdirect. Samsung already made 5G, and they are now testing it. Reported Speed as 1.056Gbps to a distant up to 2 kilometre. (it's 1000Mbps not 100Mbps for 5G speed.......)

5G Is Already Ridiculously Fast - SourceFed - SourceFed

We are talking about network infrastructure and the large-scale commercial roll of same。

Samsung is not even an infrastructure player,Its speciality will be in handsets making use of 5G network。

As a matter of fact,Huawei had completed an in-house demonstration at 5Gbps throughput:

Light Reading - Huawei Sets Out Its 5G Stall

:coffee:
 
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