China Science & Technology Forum

[JSCh]

New Measurements Suggest "Antineutrino Anomaly" Fueled by Modeling Error
Apr 05, 2017

Analysis indicates missing particles problem may stem from uranium isotope

Results from a new scientific study may shed light on a mismatch between predictions and recent measurements of ghostly particles streaming from nuclear reactors—the so-called “reactor antineutrino anomaly,” which has puzzled physicists since 2011.

The anomaly refers to the fact that scientists tracking the production of antineutrinos—emitted as a byproduct of the nuclear reactions that generate electric power—have routinely detected fewer antineutrinos than they expected. One theory is that some neutrinos are morphing into an undetectable form known as “sterile” neutrinos.

But the latest results from the Daya Bay reactor neutrino experiment, located at a nuclear power complex in China, suggest a simpler explanation—a miscalculation in the predicted rate of antineutrino production for one particular component of nuclear reactor fuel.

Antineutrinos carry away about 5 percent of the energy released as the uranium and plutonium atoms that fuel the reactor split, or “fission.” The composition of the fuel changes as the reactor operates, with the decays of different forms of uranium and plutonium (called “isotopes”) producing different numbers of antineutrinos with different energy ranges over time, even as the reactor steadily produces electrical power.

The new results from Daya Bay—where scientists have measured more than two million antineutrinos produced by six reactors during almost four years of operation—have led scientists to reconsider how the composition of the fuel changes over time and how many neutrinos come from each of the decay chains.

The scientists found that antineutrinos produced by nuclear reactions that result from the fission of uranium-235, a fissile isotope of uranium common in nuclear fuel, were inconsistent with predictions. A popular model for uranium-235 predicts about 8 percent more antineutrinos coming from decays of uranium-235 than what was actually measured.

In contrast, the number of antineutrinos from plutonium-239, the second most common fuel ingredient, was found to agree with predictions, although this measurement is less precise than that for uraninum-235.

If sterile neutrinos—theoretical particles that are a possible source of the universe’s vast unseen or “dark” matter—were the source of the anomaly, then the experimenters would observe an equal depletion in the number of antineutrinos for each of the fuel ingredients, but the experimental results disfavor this hypothesis.

The latest analysis suggests that a miscalculation of the rate of antineutrinos produced by the fission of uranium-235 over time, rather than the presence of sterile neutrinos, may be the explanation for the anomaly. These results can be confirmed by new experiments that will measure antineutrinos from reactors fueled almost entirely by uranium-235.

The work could help scientists at Daya Bay and similar experiments understand the fluctuating rates and energies of those antineutrinos produced by specific ingredients in the nuclear fission process throughout the nuclear fuel cycle. An improved understanding of the fuel evolution inside a nuclear reactor may also be helpful for other nuclear science applications.

Situated about 32 miles northeast of Hong Kong, the Daya Bay experiment uses an array of detectors to capture antineutrino signals from particle interactions occurring in a series of liquid tanks. The Daya Bay collaboration involves 243 researchers at 41 institutions in the U.S., China, Chile, Russia and the Czech Republic.

A complete list of funding agencies for the experiment can be found in the scientific paper: “Evolution of the Reactor Antineutrino Flux and Spectrum at Daya Bay.”


New Measurements Suggest "Antineutrino Anomaly" Fueled by Modeling Error---Chinese Academy of Sciences

New Particle Physics Study Says Modeling Error Could Explain 'Antineutrino Anomaly' | Berkeley Lab

 

[JSCh]

Public Release: 5-Apr-2017
Seaweed: From superfood to superconductor
American Chemical Society

Scientists have created porous 'egg-box' structured nanofibers using seaweed extract.
Credit: American Chemical Society

SAN FRANCISCO, April 5, 2017 -- Seaweed, the edible algae with a long history in some Asian cuisines, and which has also become part of the Western foodie culture, could turn out to be an essential ingredient in another trend: the development of more sustainable ways to power our devices. Researchers have made a seaweed-derived material to help boost the performance of superconductors, lithium-ion batteries and fuel cells.

The team will present the work today at the 253rd National Meeting & Exposition of the American Chemical Society (ACS). ACS, the world's largest scientific society, is holding the meeting here through Thursday. It features more than 14,000 presentations on a wide range of science topics.

"Carbon-based materials are the most versatile materials used in the field of energy storage and conversion," Dongjiang Yang, Ph.D., says. "We wanted to produce carbon-based materials via a really 'green' pathway. Given the renewability of seaweed, we chose seaweed extract as a precursor and template to synthesize hierarchical porous carbon materials." He explains that the project opens a new way to use earth-abundant materials to develop future high-performance, multifunctional carbon nanomaterials for energy storage and catalysis on a large scale.

Traditional carbon materials, such as graphite, have been essential to creating the current energy landscape. But to make the leap to the next generation of lithium-ion batteries and other storage devices, an even better material is needed, preferably one that can be sustainably sourced, Yang says.

With these factors in mind, Yang, who is currently at Qingdao University (China), turned to the ocean. Seaweed is an abundant algae that grows easily in salt water. While Yang was at Griffith University in Australia, he worked with colleagues at Qingdao University and at Los Alamos National Laboratory in the U.S. to make porous carbon nanofibers from seaweed extract. Chelating, or binding, metal ions such as cobalt to the alginate molecules resulted in nanofibers with an "egg-box" structure, with alginate units enveloping the metal ions. This architecture is key to the material's stability and controllable synthesis, Yang says.

Testing showed that the seaweed-derived material had a large reversible capacity of 625 milliampere hours per gram (mAhg-1), which is considerably more than the 372 mAhg-1 capacity of traditional graphite anodes for lithium-ion batteries. This could help double the range of electric cars if the cathode material is of equal quality. The egg-box fibers also performed as well as commercial platinum-based catalysts used in fuel-cell technologies and with much better long-term stability. They also showed high capacitance as a superconductor material at 197 Farads per gram, which could be applied in zinc-air batteries and supercapacitors. The researchers published their initial results in ACS Central Science in 2015 and have since developed the materials further.

For example, building on the same egg-box structure, the researchers say they have suppressed defects in seaweed-based, lithium-ion battery cathodes that can block the movement of lithium ions and hinder battery performance. And recently, they have developed an approach using red algae-derived carrageenan and iron to make a porous sulfur-doped carbon aerogel with an ultra-high surface area. The structure could be a good candidate to use in lithium-sulfur batteries and supercapacitors.

More work is needed to commercialize the seaweed-based materials, however. Yang says currently more than 20,000 tons of alginate precursor can be extracted from seaweed per year for industrial use. But much more will be required to scale up production.


Seaweed: From superfood to superconductor | EurekAlert! Science News

 

[JSCh]

China develops hot water drill to facilitate Antarctic expedition
Source: Xinhua| 2017-04-06 16:59:12|Editor: Xiang Bo

CHANGCHUN, April 6 (Xinhua) -- China on Wednesday announced it had completed controlled tests on its first hot-water drill, which is capable of drilling through 1,500 meters of ice and will be used for Antarctic research.

This is the fourth test on the drill, it was conducted at Jilin University in northeast China's Jilin Province.

The drill, which uses pressurized hot water to melt and bore into the ice, is capable of drilling 1,500 meters into the Amery Ice Shelf in Antarctica, the assessment panel announced after an on-site review.

"The drill will be invaluable to China's Antarctic scientific exploration," said Zhao Yue, head of the review panel and a researcher with the Chinese Academy of Geological Sciences.

The panel agreed to further testing and said the equipment should be used during China's upcoming 34th Antarctic expedition in November, he said.

Once it passes the Antarctic test, China will be the third country to have mastered hot water drilling deeper than 1,000 meters after the United States and Australia.

Our drill can go deeper than the Australian one, and has more functions than the American one, said Li Yuansheng, head of the research team and a researcher with Polar Research Institute of China.

Li said that drilling helps with the detection of ice shelves.

Ice shelves are floating ice platforms between glaciers and the ocean surface. According to Li, the freeze-thaw underneath ice shelves has an important effect on the continental ice sheets, and water masses and ocean currents.

Scientists worldwide know little about how ice shelves affect the ocean, especially given global warming, Li said. Hot water drilling may help.

The aim is to install detectors in the drilled holes, and link them to a central monitoring system.

It will help Chinese arcticologists capture more data on not only ice shelves but also global warming, said the expert.

 

[JSCh]

All rGO-on-PVDF-nanofibers Based Self-powered Electronic Skins Manufactured
Apr 06, 2017

As bionics science and robotics science developing, electronic skins, which can mimic human skins and organs to sense physical environment, monitor human activity and personal healthy, are drawing extensive attentions and boosting rapidly in recent years. To mimic the comprehensive properties of human skins, the artificial electronic skins (E-skins) are required to integrate diverse sensing modules that can simultaneously differentiate among various physical stimuli including strain, twist, temperature, light, humidity and the environmental gases.

Besides, the power units are also required to be integrated into the multifunctional E-skins to form into self-powered systems, which are especially favorable for next-generation multifunctional E-skins.

Recently, Prof. SHEN Guozhen's Group in Institute of Semiconductors, Chinese Academy of Sciences, with their collaborators in University of Electronic Science and Technology of China, Chinese PLA General Hospital and University of Science and Technology Beijing, have manufactured an All rGO-on-PVDF-nanofibers based self-powered electronic skins.

Based on their previous studies on physical and chemical properties of graphene and advanced engineering of composite graphene materials, four kinds of planar devices namely micro-supercapacitors, pressure sensor, photodetector and gas sensor were modularly manufactured, all with graphene oxide encapsulated PVDF nanofibers as the functional materials.

They were integrated into a single pixel to form a self-powered multifunctional electronic skin system, to detect the environmental conditions and physiological signs of health.

They also found that the flexible supercapacitor modules, with an energy density of 0.071 mWh/cm3, could provide stable current output for the system; the pressure sensor could sense external touch, wrist pulse, throat sound and heartbeat; the photodetector could sense the brightness of the environment; and the gas sensor can detect the concentration of certain toxic organic gases.

The technology developed in this work is quite simple and efficient, which can in principle be scaled-up to fabricate more compact and higher performance e-skins for applications in wearable electronics or bionics field.

This work entitled “All rGO-on-PVDF-nanofibers based self-powered electronic skins" was recently published in Nano Energy.

It was supported by the National Natural Science Foundation of China, Beijing Natural Science Foundation and the Key Research Program of Frontier Sciences, CAS.

​

Figure 1. All rGO-on-PVDF-nanofibers based self-powered electronic skins (Image by Prof. SHEN Guozhen)


All rGO-on-PVDF-nanofibers Based Self-powered Electronic Skins Manufactured---Chinese Academy of Sciences

 

[JSCh]

A flexible faster swimming manta-ray like robot
April 6, 2017 by Bob Yirka

Something’s fishy about this manta-ray-like robot. Perhaps it’s the fact that it uses water as a conductor for dangerously high-voltage electrical energy? This system safely bent the robot’s flexible layer and helped it flap its fins. Credit: Li et al. 2017;3:e1602045

(Phys.org)—A team of researchers at Zhejiang University in China has created a small, soft-bodied robot able to swim twice as fast as others of its kind. In their paper published in the journal Science Advances, the team describes how they came up with a unique way to power the robot, how well it works, and likely applications for it.


--> A flexible faster swimming manta-ray like robot | Tech Xplore

Tiefeng Li et al. Fast-moving soft electronic fish, Science Advances (2017). DOI: 10.1126/sciadv.1602045

Abstract
Soft robots driven by stimuli-responsive materials have unique advantages over conventional rigid robots, especially in their high adaptability for field exploration and seamless interaction with humans. The grand challenge lies in achieving self-powered soft robots with high mobility, environmental tolerance, and long endurance. We are able to advance a soft electronic fish with a fully integrated onboard system for power and remote control. Without any motor, the fish is driven solely by a soft electroactive structure made of dielectric elastomer and ionically conductive hydrogel. The electronic fish can swim at a speed of 6.4 cm/s (0.69 body length per second), which is much faster than previously reported untethered soft robotic fish driven by soft responsive materials. The fish shows consistent performance in a wide temperature range and permits stealth sailing due to its nearly transparent nature. Furthermore, the fish is robust, as it uses the surrounding water as the electric ground and can operate for 3 hours with one single charge. The design principle can be potentially extended to a variety of flexible devices and soft robots.​

 

[JSCh]

April 6, 2017
Salk scientists expand ability of stem cells to regrow any tissue type

The new technique, which allows scientists to generate both embryonic and non-embryonic tissues from cultured stem cells, is a step toward growing donor organs and replacement tissues to combat aging and diseases

LA JOLLA—When scientists talk about laboratory stem cells being totipotent or pluripotent, they mean that the cells have the potential, like an embryo, to develop into any type of tissue in the body. What totipotent stem cells can do that pluripotent ones can’t do, however, is develop into tissues that support the embryo, like the placenta. These are called extra-embryonic tissues, and are vital in development and healthy growth.

Human EPS cells (green) can be detected in both the embryonic part (left) and extra-embryonic parts (placenta and yolk sac, right) of a mouse embryo.
Credit: Salk Institute

Now, scientists at the Salk Institute, in collaboration with researchers from Peking University, in China, are reporting their discovery of a chemical cocktail that enables cultured mouse and human stem cells to do just that: generate both embryonic and extra-embryonic tissues. Their technique, described in the journal Cell on April 6, 2017, could yield new insights into mammalian development that lead to better disease modeling, drug discovery and even tissue regeneration. This new technique is expected to be particularly useful for modeling early developmental processes and diseases affecting embryo implantation and placental function, possibly paving the way for improved in vitro fertilization techniques.

“During embryonic development, both the fertilized egg and its initial cells are considered totipotent, as they can give rise to all embryonic and extra-embryonic lineages. However, the capture of stem cells with such developmental potential in vitro has been a major challenge in stem cell biology,” says Salk Professor Juan Carlos Izpisua Bemonte, co–senior author of the paper and holder of Salk’s Roger Guillemin Chair. “This is the first study reporting the derivation of a stable stem cell type that shows totipotent-like bi-developmental potential towards both embryonic and extra-embryonic lineages.”

Once a mammalian egg is fertilized and begins dividing, the new cells segregate into two groups: those that will develop into the embryo and those that will develop into supportive tissues like the placenta and amniotic sac. Because this division of labor happens relatively early, researchers often can’t maintain cultured cell lines stably until cells have already passed the point where they could still become either type. The newly discovered cocktail gives stem cells the ability to stably become either type, leading the Salk team to dub them extended pluripotent stem (EPS) cells.

“The discovery of EPS cells provides a potential opportunity for developing a universal method to establish stem cells that have extended developmental potency in mammals,” says Jun Wu, a senior scientist at Salk and one of the paper’s first authors. “Importantly, the superior interspecies chimeric competency of EPS cells makes them especially valuable for studying development, evolution and human organ generation using a host animal species.”

To develop their cocktail, the Salk team, together with the team from Peking University, first screened for chemical compounds that support pluripotency. They discovered that a simple combination of four chemicals and a growth factor could stabilize the human pluripotent stem cells at a developmentally less mature state, thereby allowing them to more efficiently contribute to chimera (a mix of cells from two different species) formation in a developing mouse embryo. They also applied the same factors to mouse cells and found, surprisingly, that the newly derived mouse stem cells could not only give rise to embryonic tissue types but also differentiate into cells from the extra-embryonic lineages. Moreover, the team found that the new mouse stem cells have a superior ability to form chimeras and a single cell could give rise to an entire adult mouse, which is unprecedented in the field, according to the team.

“The superior chimeric competency of both human and mouse EPS cells is advantageous in applications such as the generation of transgenic animal models and the production of replacement organs,” adds Wu. “We are now testing to see whether human EPS cells are more efficient in chimeric contribution to pigs, whose organ size and physiology are closer to humans.” Human EPS cells, combined with the interspecies blastocyst complementation platform as reported by the same Salk team in Cell in January 2017, hold great potential for the generation of human organs in pigs to meet the rising demand for donor organs.

“We believe that the derivation of a stable stem cell line with totipotent-like features will have a broad and resounding impact on the stem cell field,” says Izpisua Belmonte.

Other authors included: Takayoshi Yamauchi, Atsushi Sugawara and Zhongwei Li of Salk; Yang Yang, Bei Liu, Jun Xu, Jinlin Wang, Cheng Shi, Yaxing Xu, Jiebin Dong, Chengyan Wang, Weifeng Lai, Jialiang Zhu, Liang Xiong, Dicong Zhu, Xiang Li, Chen Li, Aibin He, Yaqin Du, Ting Wang, Chaoran Zhao, Haibo Li, Hongquan Zhang, Xiaochun Chi, and Huan Shen of Peking University; Weifeng Yang and Ming Yin of Beijing Vitalstar Biotechnology; Fangyuan Sun and Xiangyun Li of Hebei University; Yifang Liu of Tsinghua University; Cheng Li of Peking-Tsinghua Center for Life Sciences; Shuguang Duo of the Chinese Academy of Sciences.

The work was funded by: the National Key Research and Development Program of China (2016YFA0100100), the National Natural Science Foundation of China (31521004), the Guangdong Innovative and Entrepreneurial Research Team Program (2014ZT05S216), the Science and Technology Planning Project of Guangdong Province, China (2014B020226001), the Science and Technology Program of Guangzhou, China (2016B030232001), the Ministry of Education of China (111 Project), the BeiHao Stem Cell and Q9 Regenerative Medicine Translational Research Institute, the Joint Institute of Peking University Health Science Center, University of Michigan Health System, Peking-Tsinghua Center for Life Sciences, the National Science and Technology Support Project (2014BAI02B01), the CAS Key Technology Talent Program, the G. Harold and Leila Y. Mathers Charitable Foundation, and The Moxie Foundation.


PUBLICATION INFORMATION

JOURNAL
Cell

TITLE
Derivation of pluripotent stem cells with in vivo embryonic and extraembryonic potency

AUTHORS
Yang Yang, Bei Liu, Jun Xu, Jinlin Wang, Jun Wu, Cheng Shi, Yaxing Xu, Jiebin Dong, Chengyan Wang, Weifeng Lai, Jialiang Zhu, Liang Xiong, Dicong Zhu, Xiang Li, Weifeng Yang, Takayoshi Yamauchi, Atsushi Sugawara, Zhongwei Li, Fangyuan Sun, Xiangyun Li, Chen Li, Aibin He, Yaqin Du, Ting Wang, Chaoran Zhao, Haibo Li, Xiaochun Chi, Hongquan Zhang, Yifang Liu, Cheng Li, Shuguang Duo, Ming Yin, Huan Shen, Juan Carlos Izpisua Belmonte, and Hongkui Deng


Salk scientists expand ability of stem cells to regrow any tissue type - Salk Institute for Biological Studies

 

[JSCh]

Chinese science academy invests in deep learning processor
Source: Xinhua| 2017-04-09 13:04:57|Editor: ZD

BEIJING, April 9 (Xinhua) -- The Chinese Academy of Sciences (CAS) has earmarked 10 million yuan (1.4 million U.S. dollars) for the research and development of an advanced AI processor.

The deep learning processor chip, the "Cambrian," is expected to be the world's first processor that simulates human nerve cells and synapses to conduct deep learning, according to a statement issued by CAS.

The program is named after the Cambrian Period, which marked a rapid diversification of lifeforms on earth. Scientists are expecting the processor to spearhead a new era in AI.

The statement said that the investment would be used in basic research areas to explore the structure and algorithm for the next generation of AI, which will lay the foundations for China's ambition in the global chip market.

The funds will also be used to promote the Cambrian.

The Cambrian research team is led by Chen Yunji and Chen Tianshi from the CAS Institute of Computing Technology.

Google's AI program AlphaGo needs huge power and large servers to operate, but the Cambrian aims to perform at the same level and use just one watt of power and be the size of a smartphone or a watch, according to Chen Yunji.

AlphaGo scored a 4-1 victory over Korean Go master Lee Se-dol last year.

 

[JSCh]

Chinese scientists discover compound to tackle obesity
Source: Xinhua| 2017-04-09 17:41:18|Editor: Tian Shaohui

XIAMEN, April 9 (Xinhua) -- Chinese scientists have extracted a medicinal compound from the natural herb, thunder god vine, which targets cell metabolism and could help tackle obesity.

Celastrol, extracted from thunder god vine, and artemisinin, developed from sweet wormwood, are among five herbal compounds listed by the scientific journal Cell to have the most potential to treat illnesses where no cure has been discovered, such as cancer.

The discovery of artemisinin won Chinese scientist Tu Youyou a Nobel Prize in 2015.

The research team led by Zhang Xiaokun, professor with the College of Medicine at Xiamen University, found that celastrol from the thunder god vine could clear inflamed mitochondria from cells to alleviate inflammation.

Mitochondria plays an integral role in cell death, immunity and inflammation. By affecting inflamed mitochondria, celastrol can help control cell metabolism.

The team carried out the research on mice, and found that celastrol could effectively control weight increases in mice feeding on high fat food.

The research paper was published in science journal Molecular Cell on April 6.

Zhang said his team would continue to research how celastrol regulates metabolism to explore new drugs, with low toxicity and high efficiency, to help people lose weight.

His research has been supported by the National Nature and Science Foundation and Xiamen South Sea Center.

Like sweet wormwood, thunder god vine is native to China though it also grows in other East Asian countries. The herb has been used in traditional Chinese medicine for treating arthritis and autoimmune diseases.

However, the whole plant is extremely toxic. It must undergo a lot of processing to reduce toxicity before being used in traditional medicine. In modern research, the plant has been used in clinical trials on AIDS treatment. Its compounds have been found to have the potential to treat joint pain and rheumatoid arthritis.

 

[JSCh]

Chinese scientists pioneer new method to absorb oil spills
Source: Xinhua| 2017-04-07 15:03:19|Editor: ying

HEFEI, April 7 (Xinhua) -- Chinese scientists have found that graphene-wrapped sponges provide an effective and fast way to absorb spilled crude oil when heated with an applied electric current.

A research team led by Yu Shuhong, a professor at the University of Science and Technology of China, published the study in Nature Nanotechnology on April 3, according to an article released on the university's website.

The team wrapped porous material with a thin, waterproof graphene layer, put the coated sponge in water mixed with crude oil, and applied an electric current to the graphene to warm it up. The process reduces the viscosity of crude oil, thus speeding up the oil-absorption time, the website said.

Crude oil spills in oceans have been frequent in recent years, damaging the environment and affecting the economy. The spilled oil is hard to collect and clean up via traditional technology. It is believed that the new study may be widely used to treat oil spills in the future.

 

[JSCh]

Chinese underwater rescue robot reaches 3,000 meters
By Gao Yun
2017-04-10 15:33 GMT+8

China successfully completed its five-day sea trial of the remote operated vehicle (ROV) undertaken by China's Yantai Salvage of Ministry of Transport on Sunday, marking China’s capability of deep-water salvage at 3,000 meters.

The offshore supply ship De Mei, which carried this ROV, set sail for the scheduled place in the South China Sea on April 5. The ROV was launched twice on April 6-7 with a maximum depth of 1,180 and 2,951 meters. The resistance to pressure and stability had also been tested.

The ROV is being launching into the water. /Photo from Ministry of Transport

The ROV had the third sea trial on Saturday and successfully reached the seabed with the depth of 2,735 meters. It then flied 600 meters underwater as scheduled.

At the same time, technicians operated the high precision manipulator to put the sign of “China Rescue and Salvage” at the bottom of South China Sea. Main sensors, auxiliary equipment, mechanical hydraulic system, telecommunication transmission system, and automatic control system had all been examined and showed normal performance and parameters.

The sign of “China Rescue and Salvage” is put at the bottom of South China Sea /Photo from Ministry of Transport

The ROV of Yantai Salvage is one of the country’s key investments in equipment. Its spindle power reaches 200 horsepower and has an operating depth 3,000 meters. Equipped with advanced facilities, it is capable of various deep-water salvage and search work as well as ocean engineering assignments.

It will be put into service later, according to technicians from China Yantai Salvage.

The successful completion of this underwater trial has created a new diving record of Yantai Salvage, and set a new step Yantai Salvage makes for enhancing China’s marine power.

 

[JSCh]

Would Solid State Lithium Battery Work at Bottom of Mariana Trench?
Apr 11, 2017

Human never stop nature exploration especially under extreme conditions. The Mariana Trench is the deepest part (10,994 m) of the world's oceans, located in the western Pacific Ocean. The development of full ocean depth expedition equipments requires high energy density power sources. In recent years, China has made remarkable achievements in the field of deep-sea power batteries. The silver-zinc battery with oil-filled pressure system has been successfully demonstrated in the manned submersible Jiaolong for sustainable period of six hours under depth of 7,000 m. However, the silver-zinc battery has a relatively low energy density (less than 60 Wh/kg) and a short cycling life (50 times), which cannot meet the requirements of long endurance and full ocean depth applications (11,000 m).

Compared with the silver-zinc batteries, lithium batteries show a significant advantages in energy density (180 Wh/kg), cycling life (500-1,000 times) and safety. However, the volatile flammable organic electrolyte in traditional lithium batteries may lead to thermal runaway or even explosion, due to being overcharged or internal short circuit. These issues are more prominent in the 3,000 meters under the sea. The solid state electrolytes with enhanced safety can be compatible to lithium metal as the anode of the battery, increasing the battery energy density up to 400 Wh/kg (double that of the commercial lithium-ion battery, and six times that of silver-zinc battery). Such solid state electrolyte based batteries can provide adequate power output for deep-sea space station and deep-sea robot.

A research team headed by Prof. CUI Guanglei from the Qingdao Institute of Bioenergy and Bioprocess Technology (QIBEBT) of the Chinese Academy of Sciences, has been focusing on high-performance and high-safety lithium batteries by using "Rigid-flexible Coupling" type of solid electrolyte system. The optimum coupling of ion transport mechanism and pressure has been realized through finely tuning the molecular structure of electrolytes and ionic conductivity. This system possesses several features, such as high safety, long cycling life, and improved working depth. The team also innovated the lithium metal interface modification technology and in-situ interface repair technology for the solid state lithium batteries tested in the Mariana Trench recently.

From Jan 15 to Mar 23, 2017, the solid state battery system (namely QIBEBT-I) as the only power supply was assembled on the lander Wanquan (Figure 1) and brought to the Mariana Trench by the CAS deep-sea expedition team. The lander realized nine times of successful dives, of which six times down to 10,000 m depth (maximum dive depth of 10,901 m). The cumulative working time and the longest continuous running time of QIBEBT-I were 134 hours and 20 hours, respectively.

Nowadays, the team at QIBEBT is moving forward to solid state lithium battery with better performance for deep-sea expedition.

​

Figure 1. The solid state battery system (namely QIBEBT-I) assembled on the lander Wanquan (Image by QIBEBT)

 

[JSCh]

China to start pilot-scale production of graphene-copper composite film
New China TV
Published on Apr 12, 2017

Pilot-scale production of graphene-copper composite film to start in #Shanghai in July, which will be used for cooling smartphones.

#####
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Beijing sets up innovation center to accelerate graphene industrialization
Source: Xinhua| 2017-04-11 23:01:02|Editor: An

BEIJING, April 11 (Xinhua) -- A graphene industry innovation center was established Tuesday in Beijing, aiming to become a world-class graphene composite technology research and industrial incubator hub.

Graphene is a flat sheet of one-atom-thick carbon with the carbon atoms arranged in a honeycomb lattice. Since it was first successfully isolated in 2004, it has been lauded for its outstanding potential in fields such as energy, high-tech materials, sensors, and optoelectronic devices.

Beijing Graphene Industry Innovation Center will take the advantage of Beijing's innovative resources to research and develop cutting-edge new materials. It hopes to speed up the transformation of scientific research achievements and enhance the graphene industry.

In China, which has substantial graphite deposits, more than 500 companies already specialize in graphene products.

China expects to establish a comprehensive graphene industry system by 2020, according to a plan drafted by the Ministry of Industry and Information Technology, the National Development and Reform Commission, and the Ministry of Science and Technology in 2015.

 

[JSCh]

A flexible faster swimming manta-ray like robot
April 6, 2017 by Bob Yirka

Something’s fishy about this manta-ray-like robot. Perhaps it’s the fact that it uses water as a conductor for dangerously high-voltage electrical energy? This system safely bent the robot’s flexible layer and helped it flap its fins. Credit: Li et al. 2017;3:e1602045

(Phys.org)—A team of researchers at Zhejiang University in China has created a small, soft-bodied robot able to swim twice as fast as others of its kind. In their paper published in the journal Science Advances, the team describes how they came up with a unique way to power the robot, how well it works, and likely applications for it.


--> A flexible faster swimming manta-ray like robot | Tech Xplore

Tiefeng Li et al. Fast-moving soft electronic fish, Science Advances (2017). DOI: 10.1126/sciadv.1602045

Abstract
Soft robots driven by stimuli-responsive materials have unique advantages over conventional rigid robots, especially in their high adaptability for field exploration and seamless interaction with humans. The grand challenge lies in achieving self-powered soft robots with high mobility, environmental tolerance, and long endurance. We are able to advance a soft electronic fish with a fully integrated onboard system for power and remote control. Without any motor, the fish is driven solely by a soft electroactive structure made of dielectric elastomer and ionically conductive hydrogel. The electronic fish can swim at a speed of 6.4 cm/s (0.69 body length per second), which is much faster than previously reported untethered soft robotic fish driven by soft responsive materials. The fish shows consistent performance in a wide temperature range and permits stealth sailing due to its nearly transparent nature. Furthermore, the fish is robust, as it uses the surrounding water as the electric ground and can operate for 3 hours with one single charge. The design principle can be potentially extended to a variety of flexible devices and soft robots.​

Fish-like soft robot "swims" faster
New China TV
Published on Apr 12, 2017

A soft and transparent robot that resembles ray fish! Without motors but swimming faster, it can record temperature and salinity of the sea, or detect pollutants.

 

[cirr]

13 APRIL 2017

Paper-powered generator for portable devices

A lightweight cut-paper lattice uses your body movements to recharge a battery, writes Andrew Masterson.

The need to plug in to charge may one day be a thing of the past.
MURIEL DE SEZE / GETTY

Many everyday electronic devices, such as remote controls and watches, require only tiny amounts of energy to operate, so the notion of powering them through rechargeable batteries that ultimately draw down from the electricity grid seems decidedly inelegant.
Now, however, researchers led by Hengyo Guo from the Beijing Institute of Nanoenergy and Nanosystems in China have developed a proof-of-concept portable structure that can power low-demand devices using the energy generated simply by quotidian body movements.

The charger, described in the journal ACS Nano, is inspired by the venerable Chinese and Japanese art of precision paper cutting.

It takes the form of a wallet-sized paper-based lattice, coated with gold, graphite and fluorinated ethylene propylene film to create what the researchers call a “triboelectric nanogenerator” (or TENG).

A researcher shows the paper lattice at the heart of the new device.
AMERICAN CHEMICAL SOCIETY

Pressing and releasing the TENG for just a couple of minutes – in the same way that would occur if it was, say, stashed in a coat pocket while the wearer was walking – accumulates a charge of one volt.

This, write the scientists, makes it “a sustainable power source for driving wearable and portable electronic devices such as a wireless remote control, electric watch, or temperature sensor”.

Guo’s team has been active in developing TENGs for several years, but the paper-based design represents a significant improvement in both construction and materials. Previous models have been made of acrylic, which makes them heavy, and required to several hours of motion and pressure to build up sufficient charge to operate a low-energy device.

The new version, dubbed, unromantically, “a cut-paper-based self-charging power unit”, has evident and obvious commercial application.

“The development of lightweight, super-portable, and sustainable power sources has become an urgent need for most modern personal electronics,” the researchers note.

https://cosmosmagazine.com/technology/paper-powered-generator-for-portable-devices

 

[JSCh]

Ten superconducting qubits entangled by physicists in China
Apr 13, 2017

A group of physicists in China has taken the lead in the race to couple together increasing numbers of superconducting qubits. The researchers have shown that they can entangle 10 qubits connected to one another via a central resonator – so beating the previous record by one qubit – and say that their result paves the way to quantum simulators that can calculate the behaviour of small molecules and other quantum-mechanical systems much more efficiently than even the most powerful conventional computers.


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