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The search for smarter energy and water strategies
April 25, 2016
By: Wallace Ravven

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Ashok Gadgil and postdoctoral researcher Chinmayee Subban are refining an affordable water treatment technology to produce fresh drinking water from brackish water, one of many projects supported by CERC-WET. Photo: Peg Skorpinski

As the changing climate disrupts familiar weather patterns, many countries face a dual threat: swamping along the coasts, but also unexpected shrinking freshwater supplies in many regions.

“Water has never been evenly distributed around the world, but droughts and an alarming decrease in groundwater create potentially catastrophic conditions,” says Ashok Gadgil, Deputy for Science and Technology for the Energy Technologies Area at LBNL and professor of environmental engineering at UC Berkeley.

Gadgil is the principal investigator on the U.S. side of a new $64 million collaboration between China and the United States to develop strategies and technologies to conserve water in energy production and use.

“Energy and water are coupled,” he says. “We require energy to transport water and to desalinate water. At the same time, we require great volumes of water to produce energy, whether for hydroelectric power or cooling of thermal power plants.

“The challenges of meeting energy and water needs on the societal scale are two of the most critical problems of this century for both developing and industrial societies.”

The Clean Energy Research Center for Water Energy Technologies (CERC-WET) brings the expertise of American and Chinese scientists, engineers, climate modelers and planners to take on the challenge. Researchers from both countries will be able to demonstrate new technologies on test beds in China, Gadgil says.

“Let’s say we develop the technology for running gas turbines using less water — say a huge gas turbine that requires a test rig the size of California Hall at UC Berkeley. We could run tests for the pilot turbine at a Chinese research institute. The Chinese are hungry for this. They need to build new plants no matter what. With a new turbine technology demonstrated in China, the Chinese will be publishing the results. That gets the new technology a much more credible entry into the Chinese market.”


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About 140 million people worldwide are affected by arsenic contamination in drinking water. Gadgil and his lab developed an inexpensive arsenic remediation technology, now being introduced in India and Bangladesh. Gadgil, PhD student Siva Bandaru and project scientist Susan Amrose discuss arsenic removal chemistry at a rural high school in India where they were setting up a field experiment.

Gadgil has learned first-hand — and many times — how institutional buy-in boosts the chances for adoption of even the simplest new technologies. After receiving a masters degree in physics from the Indian Institute of Technology Kanpur, and his physics Ph.D. from UC Berkeley, he spent five years back in India working for a non-profit. His work focused on energy efficiency and renewable energy technologies and policies for the energy-strapped India.

In the early 1990s, only about a third of India’s 130 million households were electrified, and most of these households were so poor that the government subsidized their basic electricity use. Many families had only an incandescent bulb hanging on a wire.

Gadgil argued that the electric utility should rent highly efficient, but relatively costly Compact Fluorescent Lamps (CFLs) to these households. The utility could borrow money at four percent a year to buy the CFLs, while individuals would likely be charged as much as ten percent interest per month by moneylenders.

Even with the added rental cost, he concluded that the bulbs’ efficiency would cut net household electric bills. He and his colleagues tested and proved the benefit of utility-sponsored energy-efficiency lighting programs in a few developing countries starting with Mexico.

Today, more than 100 million poor households in more than 20 developing countries deploy such programs, saving energy and saving about $ 5 billion per year on electric bills.

“Every time there is a wicked problem, we should look for what are the wrong-headed incentives that keep it in place. It’s not like you can simply give someone a new light bulb. You need to understand the feedback loops that are often complex and interacting that allow a wicked problem to persist. You need to find a way to cut the Gordian knot.”

In the 1990s, Gadgil developed an inexpensive water disinfection process for rural areas of developing countries. The invention earned him Discover magazine’s 1996 Discover Award for the most significant environmental invention of the year. Now it serves more than five million people daily, and Gadgil estimates that it saves about 1,000 children annually from diarrheal deaths.

More recently, he and his students devised a clean-burning stove for use in rural Africa. The stove uses only about half as much wood as traditional wood stoves, saving families time and money, and reducing exposure to toxic fumes. More than 45,000 of these stoves are now in use in Darfur, Sudan.

The CERC-WET effort, of course, aims to develop much larger-scale technologies. But whether it’s needed for billions of light bulbs or thousands of factories, Gadgil says, energy must be produced more efficiently and the water used for societal purposes must be conserved, reused and recycled using less energy.

“There’s no doubt that this is a challenge of international scope, and it’s no overstatement to say that addressing it is essential for a prosperous and sustainable future.”
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The Department of Energy recently selected UC Berkeley to lead a multi-million dollar US-China research consortium focused on the energy-water nexus. The US-China Clean Energy Research Center for Water-Energy Technologies (CERC-WET) focuses on new technologies to reduce industrial water use, yield hydroelectric power and treat water more efficiently. At the center of this $64M effort is DOE funding to Berkeley and its partners, and Chinese government funding to research institutions in that country. A similar effort already exists at Berkeley Lab focused on enhancing the energy efficiency of buildings.

The search for smarter energy and water strategies | Research UC Berkeley
 
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China's first heavy-ion medical accelerator ready for clinical trials
By Shan Juan (chinadaily.com.cn) Updated: 2016-04-26 11:12

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The heavy-ion medical accelerator in Gansu. [Photo/IC]

An advanced piece of medical equipment that is used in cutting-edge cancer treatments has been developed in China, making it the fourth country in the world to possess such technology.

The heavy-ion medical accelerator generates particles for a type of radiotherapy that aims to cure malignant tumors by bombarding them with high-energy charged heavy-ion beams.

Currently, only Japan, Germany and the United States have the capacity to produce such medical accelerators.

Developed by the Modern Physics Institute of the Chinese Academy of Science and a subsidiary company in northwest Gansu province, the new accelerator is now undergoing quality assessment tests and will have to pass a clinical trial before it is approved by the drug authority, according to Xiao Guoqing, the institute director.

"It's a great milestone as it marks an end of China's long term dependence on imported large-scale radiotherapy equipment," he said.

According to Xiao, the accelerator is the result of six decades of related research, with development on the technology itself starting in 2012.

About 30 patients will be recruited in Gansu for the clinical trials and "if everything runs smoothly it's expected to formally receive patients by the end of the year," said Ye Yancheng, head of the Wuwei Cancer Hospital, which is one of three hospitals conducting the trials.

The public hospital in Wuwei, a small city about three hours' drive from Lanzhou, bought the first machine under a joint development and technology transfer contract with the developer for a price of 550 million yuan ($84 million). Local governments and several other private companies have also contributed to the investment.

A 1,600-bed subsidiary hospital called Gansu Heavy Ion Cancer Center is now under construction, where the accelerator will be placed and receive at least 2,000 patients each year, Ye said.

"Cancer patients from abroad are welcome as well," he said.
 
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China develops graphene electronic paper
Updated: 2016-04-27 21:27
(Xinhua)

GUANGZHOU -- China has developed a new electronic paper, a huge breakthrough that will catapult the material to a new level.

The new material has been heralded as "the world's first graphene electronic paper," by Chen Yu, general manager of Guangzhou OED Technologies, which developed it in partnership with a company in Chongqing.

Graphene is the world's strongest and lightest known material; a single layer of graphene is only 0.335 nanometers thick, and it can conduct heat and electricity.

The material can be used to create hard or flexible graphene displays, used in electronic products such as e-readers and wearable smart devices.

Compared with traditional e-papers, graphene e-paper is more pliable and has more intensity and its high-light transmittance means optical displays will be much brighter.

In addition, graphene is derived from carbon, meaning production costs will be much lower than for traditional e-papers, which use the rare, expensive metal indium.

E-papers have been produced on a commercial scale since 2014. Compared with liquid crystal displays, e-papers are thinner, bendable and energy efficient, meaning products are more portable.

The team's graphene e-paper will be put into production within a year.

http://usa.chinadaily.com.cn/china/2016-04/27/content_24909192.htm
 
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Reflecting on success
Source:Xinhua Published: 2016-4-28 1:03:01

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Engineers at the Changchun Institute of Optics, Fine Mechanics and Physics under the Chinese Academy of Sciences surround their newly developed silicon carbide mirror, which has a diameter of 4.03 meters. The larger the mirror, the higher the resolution and the greater the light-gathering power of the telescope or satellite in which it is used. Photo: Xinhua
 
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China develops advanced PET scan technology
(People's Daily Online) 14:25, April 28, 2016

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China has developed the world's first clinical all-digital positron emission tomography (PET) scan which helps significantly with the early detection of cancer.(People.cn/Photo)

It was announced on Wednesday that Chinese scientists have developed the world's first clinical all-digital positron emission tomography (PET) scan, which is used for checking the whole human body, and also helps significantly with the early detection of cancer.

Developed by Huazhong University of Science and Technology, the new PET represents today's cutting-edge medical imaging technology. In addition to cancer prevention, the new technology will be used to diagnose cardiovascular and neurological diseases.

The all-digital PET has been granted 81 patents at home and abroad, and will be put into clinical application soon, said professor Xie Qingguo, who led the research for the project.

The machine consists of more than 300 modules that take just five minutes to scan an entire body. The resolution of its scans reaches 2.2 millimeters, which is twice as good as the capability of current imported models.

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China has developed the world's first clinical all-digital positron emission tomography (PET) scan which helps significantly with the early detection of cancer.(People.cn/Photo)
 
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China Delivers First Home-design Mega Component to Its "Manmade Sun" ITER
By Xi Zhu (People's Daily Online) 06:50, April 29, 2016

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The first major transformer of the Pulsed Power Electrical Network (PPEN) has been shipped by China from the Tianjin port on April 17, according to China International Nuclear Fusion Energy Execution Center on April 27, 2016. The mega component is expected to arrive in France in this June.

As a member of International Thermonuclear Experimental Reactor (ITER) project, China has been responsible for the design and manufacture of the first major transformer of PPEN for ITER. The 400 KV transformer has a capacity of 300 MVA, weighing 278 tonnes. It is 13.4 meters in length, 4 meters in width and 4.7 meters in height.

ITER is an international nuclear fusion research and engineering megaproject. It is the world's largest magnetic confinement plasma physics experiment in the Cadarache facility, south of France. China joined the project in 2013. ITER’s other partners include U.S., India, Japan, the European Union, and the Republic of Korea.
 
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Public Release: 28-Apr-2016
Fiber optic biosensor-integrated microfluidic chip to detect glucose levels
By integrating microfluidic chips with fiber optic biosensors, researchers in China are creating ultrasensitive lab-on-a-chip devices to detect glucose levels

The Optical Society

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Fiber optic biosensor-integrated microfluidic chip detects glucose levels from droplets of sweat.
Credit: Dr. A. P. Zhang and team, The Hong Kong Polytechnic University

WASHINGTON - Insulin deficiency and hyperglycemia are two well-known culprits behind diabetes, both of which are reflected in blood glucose concentrations. Now, researchers are working to create ultrasensitive lab-on-a-chip devices to quickly measure glucose concentrations with the goal of developing device for early diagnosis and prevent of diabetes

A team of researchers from The Hong Kong Polytechnic University and Zhejiang University in China report integrating fiber optic glucose sensors into a microfluidic chip to create portable, high-performance, low-cost devices for measuring glucose levels. In a paper published this week in the journal Biomedical Optics Express, from The Optical Society (OSA).



Con't reading -> Fiber optic biosensor-integrated microfluidic chip to detect glucose levels | EurekAlert! Science News
 
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Shenzhen's jetpack company takes off with 200orders
By Chai Hua in Shenzhen, Guangdong (China Daily)Updated: 2016-04-27 07:29


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A Martin Jetpack, the world's first practical and commercial jetpack, which is developed by KuangChiScience, an innovative high-tech startup in Shenzhen, Guangdong province.[Provided to China Daily]

Shenzhen, the innovative city in southern China's Guangdong province, has received resultsfrom its enormous investment in some of the most cutting-edge technologies in the world.

KuangChi Science Ltd, an innovative high-tech startup in the city, has received 200 orders forits Martin Jetpack, the world's first practical and commercial jetpack, at the price of 2 millionyuan ($308,640) each.

"Our buyers are from all over the world," said Zhang Yangyang, CEO of the company. "Forexample, a rescue team in Dubai ordered about 30 units because the jetpack is easier tooperate than helicopters in a city full of skyscrapers."

The jetpack is powered by a gasoline engine driving twin ducted fans, which producesufficient thrust to lift the aircraft and a pilot, and to enable sustained flight. It can operateclose to or between buildings, near trees and in confined spaces that other aircraft are unableto access.

The jetpack can carry commercial payloads of up to 120 kilograms with a maximum flyingtime of 45 minutes at a speed of up to 80 km per hour.

The innovative aircraft is mainly produced in New Zealand, but Zhang told China Daily theywill transfer the entire manufacturing process to China in the future.

The startup was established by five students who came back to China after studying abroad,said Zhang.

"In the beginning, almost everyone was very skeptical of the concept of the personal jetpack,"Zhang said.

"It was Shenzhen's recognition that makes our technological development and researchpossible," Zhang added.

The team was brought into Shenzhen through "peacock campaign", a plan the ShenzhenScience and Technology Innovation Commission launched to attract tech talent.

The plan has played a key role in gearing up the city to develop into a key zone for innovationand the development of modern services in the region.

Since 2011, the commission has lured 64 "peacock" teams to the city, most of which havenow grown into striking high-tech enterprises such as DJI Innovation Technology Co,KuangChi, Royole and BGI. These teams received government's financial support of tens ofmillions yuan each.

In addition, the plan is only one of the investments the city has made in promoting innovativeand emerging industries. The city's R&D investment accounted for 4 percent of its GDP lastyear, which is about the same as of South Korea.

Shenzhen Mayor Xu Qin said the investment was important for the city's long-term economicdevelopment.

http://www.chinadaily.com.cn/business/tech/2016-04/27/content_24877981.htm
 
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http://www.hpcwire.com/2016/05/02/china-focuses-exascale-goals/

China Sets Ambitious Goal to Reach Exascale by 2020
Tiffany Trader
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At the 12th HPC Connections Workshop in Wuhan, China, Beihang University Professor Depei Qian disclosed new information regarding HPC development in China and exascale plans that are shaping up under China’s 13th five-year plan (2016-2020). Since 1996 Professor Professor Qian has served on the expert committee for the National High-tech Research & Development Program (the 863 program). Currently, he is the chief scientist of the 863 key project on high productivity computer and application service environment.

Professor Qian acknowledged that despite export restrictions on processor and software technology imposed by the US, work continues on two 100 petaflops (peak) systems: the next iteration of Tianhe-2, installed at the National Supercomputer Center in Guangzhou, and the upcoming Sunway system coming to the Jiangnan Institute of Computer Technology in Wuxi, China, near Shanghai. The official line is that these systems will be ready “by the end of the year,” but there have been rumblings that one or both of these systems will be introduced during the ISC’16 event in June.

In a Tuesday session at ISC, Professor Dr. Guangwen Yang, the director of the National Supercomputer Center at Wuxi, China, is slated to deliver talk titled “The New Sunway Supercomputer System at Wuxi.” Dr. Yang will describe the hardware and software elements that make up the system and some of the applications that will be deployed on it. A notice for that talk mentions that the system will be formally announced this summer.

China has been known to play its cards close to the vest before and launched its current supercomputing star, Tianhe-2, two years ahead of schedule. With a theoretical peak speed of 54.9 petaflops and a LINPACK rating of 33.86 petaflops, Tienhe-2 (the name means “Milky Way”) has been the world’s fastest number-cruncher since it debuted on the June 2013 TOP500 list.

Both systems were developed under the auspices of China’s 12th five-year plan (2011 to 2015). Also under this program, China has been exploring new operation models and mechanism for CNGrid (China’s national HPC environment) and developing cloud-like application villages over CNGrid to promote applications.

The implementation scheme of the second phase of Tienhe-2 was evaluated and approved in July 2014. The original plan was to use next-generation Intel Xeon Phi (Knights Landing) processors for the upgrade path but due to export blocks put in place by the US, China was stimulated to accelerate its native chip development efforts. The new plan relies on Chinese made processors. “The development of the new FeiTeng processor is underway and we are waiting for the processor to upgrade the Tianhe-2 system,” said Professor Quin.

The second 100 petaflops system will use the next-generation Chinese-made ShenWei chips and will be implemented together with a general purpose cluster system of 1 petaflops performance. This configuration is designed to meet a wide variety of application requirements.

CNGrid

The CNGrid service environment is a major resource of computing and storage across China. Currently, this environment is enabled by the CNGrid Suite, a software package used for the operation of the environment, Qian noted. There are 14 nodes altogether, more than 8 petaflops aggregated computing power and more than 15 petabytes of storage. The organizers have deployed more than 400 software applications and tools and also use this environment to support more than 1,000 projects.

Domain-oriented application villages are being established on top of CNGrid to provide services to the users. There are three current application villages under development: industrial product design and optimization, new drug discovery and digital media.

China has also deployed a number of parallel software development efforts to support fusion simulation, CFD for aircraft design, drug discovery, rendering for digital media, structural mechanics for large machinery, and simulation for electro-magnetic environment. The level of parallelism required is more than 300,000 cores with an efficiency of more than 30 percent.

Challenges

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Professor Qian provided an overview of China’s main weaknesses, the most significant being a gap in kernel technologies and the lack of a suitable accelerator for the Tienhe-2 upgrade on account of the US embargo. “Currently there is no available accelerator to upgrade the system and it’s a major issue from the point of view of the Chinese government,” he said. “We had to change our plan and rely on our own processors. We are in urgent need for the system software, for the domestic processor, for the tool software and also the application software. Without an ecosystem around the domestic processors, we will not succeed in this respect.”

Also noted were a weakness in novel devices — memory storage and network as well as large-scale parallel algorithms and programs, system software, commercial software. “This is a very special phenomenon in China,” said Qian. “Currently China relies on the imported commercial application software, that software is very expensive and also limited in parallelism and limited by regulations. The center in Guangzhou cannot freely purchase system software from the vendor.” The third weakness is one shared by many countries: a talent shortage. “We don’t have enough people to work in HPC because either they only know the IT side or the domain side. We need more talented people that are also cross-disciplinary,” stated Qian.

13th Five-Year Plan Targets Exascale

After updating the continued supercomputing progress being made under the 12th five-year plan, Qian walked through brand-new elements of China’s 13th five-year plan, which puts into motion one of the most ambitious exascale programs in the world. If successful the program will stand up an exaflops supercomputer by the end of 2020 within a 35 MW power limit.

China is in the midst of overhauling its national research system and restructuring 100 programs into five tracks: Basic research program; mega-research program; key research and development program; enterprise-oriented research program; research centers and talents program.

The new track that is being focused on in the session is the third one – the key research and development program. A proposal for the track-3 key project on HPC was submitted in September 2015 and launched on February 2016.

The major pillars for the key project are developing exascale computers, promoting computer industry by technology transfer and a China-controlled HPC technology set. The major tasks are next-generation supercomputing development, CNGrid upgrading and transformation, and domain HPC applications development. A robust supercomputing program is seen as a critical for addressing grand challenge problems spanning the environment, energy, climate, medicine, industry and science.

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According to Professor Qian, the number one priority task is the development of an exascale supercomputer, based on a multi-objective optimized architecture that balances performance, energy consumption programmability, reliability and cost.

To achieve this goal, China is funding research into novel high performance interconnects with 3-D chip packaging, silicon photonics and on-chip networks. Programming models for heterogeneous computers will emphasize ease in writing programs and exploitation of performance of the heterogeneous architectures.

The program includes the development of prototype systems for verification of the exascale computer technologies. The computer scientists will explore possible exascale computer architectures, interconnects which can support more than 10,000 nodes, and energy efficiency technologies, as power demand is known to be one of the biggest obstacles toward exascale.

The exascale prototype will be about 512 nodes, offering 5-10 teraflops-per-node, 10-20 Gflops/watt, point to point bandwidth greater than 200 Gbps. MPI latency should be less than 1.5 us, said Qian. Development will also include system software and three typical applications that will be used to verify effectiveness.

From there, work will begin on an efficient computing node and a scheme for high-performance processor/accelerator design.

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“Based on those key technology developments, we will finally build the exascale system,” said Qian. “Our goal is not so ambitious – it is to have exaflops in peak. We are looking for a LINPACK efficiency of greater than 60 percent. Memory is rather limited, about 10 petabytes, with exabyte levels of storage.

“We don’t think we can reach the 20 megawatts system goal in less than five years so our goal is about 35 megawatts for the system; that means 30 Gflops/watt energy efficiency. The expected interconnect performance is greater than 500 Gbps.”

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The final goal of the exascale program is technology transfer. Qian said that China will work to field high-end domain-oriented servers based on exascale system technologies. These servers will take advantage of the advances at the node, the interconnect, scalable I/O, storage, energy savings, reliability and application software.

The professor also spoke at length about China’s software strategies.”We cannot distinguish key technologies from applications, so there will be a joint effort in this direction.” Demo applications span a numerical nuclear reactor, a numerical aircraft, a numerical earth and a numerical engine.

The plan is to transfer some of the software into products to be adopted by a minimum of 50 users. To support this effort, China will establish three national-level research and development centers for HPC application software.

The professor emphasized that China’s “self-control” strategy to eliminate dependence on foreign tech doesn’t just refer to the processor and other hardware. “One of the efforts reflected in our plan is to develop parallel algorithms and parallel libraries for the system to improve the capability of developing modern-scale systems,” he said.

The final new element of China’s renovated program is the development of a platform for education that will provide computing resources and service to undergraduate and graduate students.

A call for proposals for the new key project was issued on February 19, 2016. The proposals will be reviewed over the next two months and then the selected projects will be announced.
 
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Research shows DNA dating back 45,000 years ago
By Cheng Yingqi (chinadaily.com.cn) Updated: 2016-05-02 23:06

Interspecies sex between ancient humans and Neanderthals – a relative of our ancestors who had smaller figure and low, flat, elongated skulls like dwarfs in the in The Lord of the Rings – had given 1.6 to 1.8 percent Neanderthals' gene to every one in Europe and Asia nowadays.

An International research team led by Fu Qiaomei from the Institute of Vertebrate Paleontology and Paleoanthropology at the Chinese Academy of Sciences shows the reason that we did not inherit the dwarfs' figure is because their gene was eliminated by the process of natural selection.

The research drew the conclusion after analyzing genome-wide data from 51 Eurasians lived 45,000 to 7,000 years ago. Their findings were published as in Nature on Monday.

"Before our research, it was believed that the decrease in the proportion of Neanderthal ancestry in Eurasians was the result of interspecies sex with other human groups that diluted the Neanderthal's gene," said Fu.

"However, our research finds that the Neanderthal's gene decreased fast and steadily from between 37,000 and 14,000 years ago, in a period that there was not major admixture of other population outside of Europe."

Over this period of time, the proportion of Neanderthals ancestry in Eurasians decreased from six percent to around two percent within descents of a single founding population.

"This suggests that the Neanderthal's gene was eliminated in the evolution," Fu said.

Moreover, the influence of Neanderthal's origin in modern human is more muted in major functional gene fragments than in other genome parts, which points to the same conclusion.

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"The Neanderthals might have had more inferior genes that their part did not manage to survive," Fu said.

An earlier research published by Nature in December 2013 found that the A gene that increases the risks for Type 2 diabetes was inherited from the Neanderthals.

Other studies suggested that modern Europeans and Asians have taken over the Neanderthals' fair skin and a number of their diseases such as lupus and Crohn's Disease.

David Reich, professor of genetics at Harvard Medical School and co-senior author of the paper, said, "This study raises by about tenfold the number of ice aged hunter-gatherers for which there is ancient DNA, and in so doing, it makes it possible to track genetic change over time."

"It's a great privilege to be able to work on these samples; it's like being an art historian given full access to the treasures of the Louvre."

Co-senior author Svante Pääbo said, "Prior to this work, we had a static view of the first 30,000 years of modern human history in Europe. Now we can begin to see how people moved around and mixed with one another during this period."

The second major surprise came when the researchers found another previously unknown population turnover: the Europeans started to show a genetic relationship to present-day Near Easterners during the first major warming period 14,000 years ago, some 6,000 years earlier than the agriculture established connection between the two parts of world.

The authors speculate that it could be the warming weather rather than development of agriculture - as it was previously believed - that drove early Near East residents to Europe and led to the gene fusion.

Fu, from Vertebrate Paleontology and Paleoanthropology at the Chinese Academy of Sciences, said,"The goal of our research is to figure out what happened to the human ancestors during the last ice age and its influence to modern people."

The research, as Fu said, is the largest-scale ancient DNA research on ancient humans living 45,000 to 10,000 years ago.

"Previous researches usually include genome-wide data on only one or two Upper Paleolithic individuals. But this research managed to collect valid genome-wide data from 51 individuals from a more than 100 sample bases."

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The genetic history of Ice Age Europe : Nature : Nature Publishing Group
 
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http://phys.org/news/2016-05-technology-metre-aperture-spherical-telescope.html


The technology behind the Five hundred metre Aperture Spherical Telescope (FAST)
May 5, 2016

The 500 metre Aperture Spherical Telescope (FAST) under construction. Credit: NAOC

The National Astronomical Observatories of the Chinese Academy of Sciences (NAOC) has teamed up with CSIRO engineers in the development of the world's largest single dish telescope – the Five hundred metre Aperture Spherical Telescope (FAST).

With a diameter of half a kilometre wide, FAST will dwarf the current largest single-dish telescope, the Arecibo Observatory in Puerto Rico. It will also be one of the most sensitive, able to receive weaker and more distant radio signals, helping to explore the nature, origins and evolution of the universe.

The telescope's 19-beam receiver, a key component, is being designed and built in Australia by CSIRO engineers.

CSIRO Chief Executive Dr Larry Marshall said the project was a great example of Australia's innovative technology being delivered on the world stage.

"Global collaboration is an integral part of CSIRO's Strategy 2020, as it maps out our desire to deliver science, technology and innovation to new customers and markets, while also delivering benefit back to Australia," Dr Marshall said.

"This is a really exciting project and builds on 40 years of CSIRO collaboration with Chinese industry and research organisations."

Most radio telescopes use receivers that can only see one piece of sky at a time, but CSIRO has designed receivers with many separate, simultaneous beams, making it practical for FAST to search a large portion of the sky for faint and hidden galaxies.


A section of the 500 metre Aperture Spherical Telescope (FAST). Credit: NAOC
"The powerful receiver we've created for FAST is the result of our long history developing cutting-edge astronomy technology to receive and amplify radio waves from space," Acting Director CSIRO Astronomy and Space Science, Dr Douglas Bock said.

"Extending our technology and collaboration to China and working on what will become the world's largest radio telescope really cements our position as a global R&D leader in this space."

Professor Rendong Nan from NAOC said the state-of-the-art instrument would help astronomers to expand their understanding of the universe.

"FAST will make it possible for us to look for a range of extremely interesting and exotic objects, like detecting thousands of new pulsars in our galaxy, and possibly the first radio pulsar in other galaxies," he said.



Read more at: http://phys.org/news/2016-05-technology-metre-aperture-spherical-telescope.html#jCp

So, it appears that FAST is an international collaboration, with scientists and institutions from Australia involved. I also some months back posted news, that some of the critical suppliers were from Germany for the project.
 
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Monash signs MOU with Chinese Academy of Science, Monash University
Friday, 22 April 2016

Academics from Australia and China this morning gathered at Monash University’s Clayton campus to formally sign an agreement heralding a historic partnership between Monash University and the Chinese Academy of Science (CAS).


(L-R) Professor Suojiang Zhang, Director General of IPE,Chinese Academy of Science and Professor Cristina Varsavsky, Deputy Dean of the Faculty of Science, Monash University

The Memorandum of Understanding (MoU) will see the creation of the China Australia Centre for Ionic Liquids (CACIL) and involves an enhanced exchange of staff, students and resources between the two institutions.

This partnership with Cas's Institute for Process Engineering builds on the international reputation of the Monash Ionic Liquids Group (MILG) which has been developing ionic materials and their applications for over fifteen years. MILG Lead Scientist, Professor Doug Macfarlane from the School of Chemistry, highlighted the formation of the Joint Centre as a new era in closer collaboration.

“This historic partnership represents the world’s largest collaboration in this area, offering a very broad scope of expertise and resources to support new ideas and initiatives,” Professor Macfarlane said.

Having already made massive strides in the field of ionic liquids, the partnership boosts Monash’s exposure to the immense opportunities in Chinese industry in fields such as energy storage.

“The Centre will cement relationships between our two organisations and support exchange of research students and young researchers between the laboratories, expanding their experience and access to facilities, as well as encouraging industry engagement, particularly in China,” Professor Bart Follink, Head of School of Chemistry, said.

What are ionic liquids?

Ionic liquids are a family of ionic solvents (salts that are liquid at or around room temperature) that have extensive applications in sustainable chemistry and energy generation and storage. Potential areas of use include advanced battery technology for electric vehicles, dissolving materials for use in biofuel synthesis and stabilising therapeutic proteins for medicinal use.

For more information, please visit Monash Ionic Liquids Group.
 
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Ink with carbon nanodots luminesces via three different mechanisms
May 5, 2016

Banknotes, documents, branded products, and sensitive goods like pharmaceuticals or technical components are often marked to distinguish them from imitations. However, some counterfeiters have learned to copy conventional fluorescent tags. In the journal Angewandte Chemie, Chinese scientists have now introduced a new, exceptional anti-counterfeit ink made with carbon nanodots. Their ingenious composite material emits three different types of luminescence.


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Wednesday, May 4, 2016, 11:07
Tianjin institute exports 3-D printers to South America

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Two engineers at the Tianjin Jinhang Physics Research Institute under China Aerospace Science and Industry Corp conduct test on a 3-D printer. (Provided To China Daily)

A State-owned space institute has sold its 3-D printers to Argentina, marking China's first 3-D printer exports to South America, said a senior engineer at the institute.

Tang Xiaoyu, who heads the 3-D printer development at the Tianjin Jinhang Physics Research Institute under China Aerospace Science and Industry Corp, told China Daily that a consumer electronics wholesaler in Argentina has placed orders for 1,000 3-D printers developed by the institute and the first batch of 100 were delivered to the buyer in December.

"The client would sell our products to retailers in Argentina, Brazil and Uruguay," Tang said. He did not reveal the contract's value and his products' prices.

During the mid-March CeBIT, the largest and most internationally represented information technology and electronics expo held in Hanover, Germany, companies from more than 20 nations, including the United States, Egypt, Iran and Japan, expressed interest or intent to buy the institute's 3-D printers.

"We brought four sets of 3-D printers to the CeBIT 2016 and all of them were sold at the expo. A buyer from Germany placed an order for 20 of our products at the event while two retailers from France and the Netherlands respectively are in talks with us on their procurement contract after they saw our 3-D printer at CeBIT," Tang said.

Tianjin Jinhang specializes in laser-related equipment and has produced many types of optoelectronic instruments for China's carrier rockets and spacecraft.

He said the institute has developed seven types of desktop 3-D printers.

Most of their users in China are schools and research organizations while some State-owned aircraft and space enterprises also use its products.

"The core part of a high-end 3-D printer is the laser, which is our specialty. Therefore, we are good at developing 3-D printers and we have full intellectual property rights of our products, which is why many foreign clients favor our products rather than those made by some Chinese private firms despite their lower prices," the engineer said.

Domestically, there are more than 200 retailers selling the institute's 3-D printers, according to Tang.

He said the institute expects a total revenue of about 100 million yuan (US$15.4 million) from its 3-D printers within the coming five years.

According to the Shenzhen-based consulting firm Qianzhan Industry Research Institute, the market value of 3-D printer industry in China will reach 10 billion yuan by the end of this year while International Data Corp, a US-based market research, analysis and advisory company, expects nearly 160,000 made-in-China 3-D printers would be sold this year, more than doubling last year's sales of 77,000 units.
 
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Chinese company to develop human organ delivery drone
Source: Xinhua 2016-05-05 21:34:53

GUANGZHOU, May 5 (Xinhua) -- Chinese Aerial technology company EHang Holdings Limited on Thursday announced a collaboration with U.S. company Lung Biotechnology to develop and purchase 1,000 drones to automate organ transplant delivery.

They will develop a modified version of EHang's 184, the world's first autonomous drone capable of carrying humans, to optimize it for organ delivery. The companies have agreed to work together over the next 15 years under a program named the Manufactured Organ Transport Helicopter (MOTH) system.

The collaboration could revolutionize the way organs are transported in the United States, with the potential to save tens of thousands of lives, according to EHang.

Lung Biotechnology specializes in producing artificial lungs and other organs for transplant.

It plans to station MOTH rotorcraft outside its organ production facilities and use preprogrammed flight plans to hospitals and re-charging pads within the MOTH radius, allowing organs to be delivered within their viability windows.

The 184 is an autonomous drone that can carry a passenger more than 10 miles through the air at speeds of up to 65 miles per hour when a destination is entered into a mobile app.

It is perfectly suited for many medical emergency transportation services, according to Ehang.

Ehang is a leading aerial technology company headquartered in the south China city of Guangzhou. It unveiled the world's first autonomous aerial vehicle at the International Consumer Electronics Show (CES) 2016 earlier this year in Las Vegas.

Photo of Ehang 184

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