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Scientists develop wearable lithium-ion fiber battery
Source: Xinhua| 2021-09-04 16:33:29|Editor: huaxia

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Photo provided by Fudan University shows the conceptual model of wearable lithium-ion fiber batteries on Sept. 2, 2021. (Xinhua)

SHANGHAI, Sept. 4 (Xinhua) -- Chinese scientists have realized the scalable production of high-performing woven lithium-ion fiber batteries, bringing wirelessly charging electronics via clothes one step closer to reality.

Researchers from Fudan University have recently published their relevant study in Nature journal, suggesting how the internal resistance of such fibers changes with their lengths, theoretical support for developing secure lithium-ion fiber batteries.

The one-meter-long fiber developed by the research team is proven to be capable of powering wearable electronics including smartphones, smart bracelets and heart rate monitors continuously for a long period of time.

Its capacity retention remains about 90.5 percent after 500 charge-discharge cycles and over 80 percent of capacity can be maintained after bending the fiber for 100,000 cycles, according to the paper.

Previously, the length of such batteries remained in the centimeter scale, making weaving the fibers into textiles impossible.

Based on the new discovery, the researchers have managed to make high-performing woven lithium-ion fiber batteries. After being integrated with wireless charging launchers, the textiles can become flexible and stable power solutions for smartphones, said the team.

 
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Chinese Scientists Report Starch Synthesis from CO2
Editor: ZHANG Nannan | Sep 24, 2021

Chinese scientists recently reported a de novo route for artificial starch synthesis from carbon dioxide (CO2) for the first time. Relevant results were published in Science on Sept. 24.

The new route makes it possible to shift the mode of starch production from traditional agricultural planting to industrial manufacturing, and opens up a new technical route for synthesizing complex molecules from CO2.

Starch is the major component of grain as well as an important industrial raw material. At present, it is mainly produced by crops such as maize by fixing CO2 through photosynthesis. This process involves about 60 biochemical reactions as well as complex physiological regulation. The theoretical energy conversion efficiency of this process is only about 2%.

Strategies for the sustainable supply of starch and use of CO2 are urgently needed to overcome major challenges of mankind, such as the food crisis and climate change. Designing novel routes other than plant photosynthesis for converting CO2 to starch is an important and innovative S&T mission and will be a significant disruptive technology in today's world.

To address this issue, scientists at the Tianjin Institute of Industrial Biotechnology (TIB) of the Chinese Academy of Sciences (CAS) designed a chemoenzymatic system as well as an artificial starch anabolic route consisting of only 11 core reactions to convert CO2 into starch.

This route was established by a "building block" strategy, in which the researchers integrated chemical and biological catalytic modules to utilize high-density energy and high-concentration CO2 in a biotechnologically innovative way.

The researchers systematically optimized this hybrid system using spatial and temporal segregation by addressing issues such as substrate competition, product inhibition, and thermodynamical adaptation.

The artificial route can produce starch from CO2 with an efficiency 8.5-fold higher than starch biosynthesis in maize, suggesting a big step towards going beyond nature. It provides a new scientific basis for creating biological systems with unprecedented functions.

"According to the current technical parameters, the annual production of starch in a one-cubic-meter bioreactor theoretically equates with the starch annual yield from growing 1/3 hectare of maize without considering the energy input," said CAI Tao, lead author of the study.

This work would open a window for industrial manufacturing of starch from CO2.

"If the overall cost of the process can be reduced to a level economically comparable with agricultural planting in the future, it is expected to save more than 90% of cultivated land and freshwater resources," said MA Yanhe, corresponding author of the study.

In addition, it would also help to avoid the negative environmental impact of using pesticides and fertilizers, improve human food security, facilitate a carbon-neutral bioeconomy, and eventually promote the formation of a sustainable bio-based society,

TIB has focused on artificial starch biosynthesis and CO2 utilization since 2015. To carry out such demand-oriented S&T research, all kinds of resources for innovation have been gathered together and the integration of "discipline, task and platform" has been strengthened to achieve efficient coordination of research efforts.

This study was supported by the Key Research Program of CAS and the Tianjin Synthetic Biotechnology Innovation Capacity Improvement Project.​

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Starch synthesis via artificial starch anabolic pathway (ASAP) from CO2. ( Image by TIBCAS)

 
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A New Electric Jet Engine Actually Works Inside the Atmosphere
Editor Team October 20, 2021


While the thrust output remains to be fairly puny when in comparison with typical atmospheric engines, as soon as scaled, this new sort of engine might show revolutionary for the aerospace trade.
But earlier than we check out this new design, let’s get the down-low on how plasma jet engines work.

What is a plasma propulsion engine?
Plasma-based thrusters are normally regarded as a possible type of spacecraft propulsion. Such engines differ from ion thruster engines, which generate thrust by extracting an ion present from its plasma supply. These ions are then accelerated to excessive velocities utilizing grids or anodes.

Plasma engines do not usually require excessive voltage grids or anodes/cathodes to speed up charged particles in the plasma supply however use the currents and potentials which might be generated internally, in the type of a high-current electrical arc between the two electrodes, to speed up the ions. This tends to end in a decrease exhaust velocity as there’s a restricted voltage used for acceleration.

However, with little to no air friction in space, the thrust of those engines would not must be that prime. If a continuing acceleration could be pumped out for months or years at a time, it may very well be potential to ultimately attain a really excessive velocity.
Such engines have numerous benefits over different types of electrical propulsion. For instance, the lack of excessive voltage grids of anodes reduces the threat of grid ion erosion.
Another benefit is that the plasma exhaust is what’s termed “quasi-neutral”. This implies that the optimistic ions and electrons exist in equal numbers, which suggests easy ion-electron recombination in the exhaust can be used to extinguish the exhaust plume, eradicating the want for an electron gun.

Typical examples of those engines are likely to generate the supply plasma utilizing a wide range of strategies, together with radiofrequency or microwave power utilizing an exterior antenna. Because of the nature of the design of those engines a variety of propellants can be utilized in them together with argon, carbon dioxide, and even human urine.
As you’d count on, there are additionally some inherent drawbacks to this technology. Chief amongst them is the excessive power demand required to energy them.

For instance, the Variable Specific Impulse Magnetoplasma Rocke (VASIMR) VX-200 engine requires 200 kW electrical energy to supply 1.12 kilos (5 N) of thrust or 40 kW/N. In concept, such an power demand may very well be met utilizing fission reactors on spacecraft, however the added weight may show prohibitive for launching the craft in the first place.

Another problem is plasma erosion. While in operation, the plasma can thermally ablate the partitions of the thruster cavity and help structure, which might ultimately result in system failure.

Such engines, thus far, are solely actually helpful as soon as the spacecraft is in space. This is due to the comparatively low thrust that prohibits them from realistically getting used to launch the craft into orbit. On common, these rockets present about 2 kilos (4.45 N) of thrust. Plasma thrusters are extremely environment friendly as soon as in space, however do nothing to offset the orbit expense of chemical rockets.

Most space businesses have developed some type of plasma propulsion methods, together with, however not restricted to, the European Space Agency, Iranian Space Agency, and, in fact, NASA.

Various real-life examples have been developed and used on some space missions. For instance, in 2011 NASA partnered with Busek to launch the first Hall-effect thruster onboard the Tacsat-2 satellite tv for pc. They are additionally in use on the NASA Dawn space probe.

Another instance is the aforementioned Variable Specific Impulse Magnetoplasma Rocket presently below improvement by the Ad Astra Rocket Company.

VASIMR works through the use of an electrical energy supply to ionize a propellant right into a plasma. Electric fields warmth and speed up the plasma whereas the magnetic fields direct the plasma in the correct route as it’s ejected from the engine, creating thrust for the spacecraft. Theoretically, a 200-megawatt VASIMR engine might scale back the time to journey from Earth to Jupiter or Saturn from six years to 14 months, and from Earth to Mars from 6 months to 39 days.
Not too shabby.

What’s so particular about this new Chinese plasma engine?

A team of Chinese engineers revealed final year a working prototype of a microwave thruster. The engine, the researchers say, ought to have the ability to work in Earth’s ambiance with comparable effectivity and thrust to that of typical jet engines.

Normally utilizing noble gasoline, like, xenon, plasma engines haven’t been proven to be sensible in Earth’s ambiance as generated ions are likely to lose thrust power due to friction with the air. Another compounding downside is that present examples produce pretty low thrust, which is okay in space however can be pathetically small on Earth.

The new design, created by researchers at the Institute of Technical Sciences at Wuhan University, makes use of air and electrical energy as a substitute of gases like xenon. Testing has proven that the engine is able to producing a formidable quantity of thrust that will, sooner or later, discover purposes in trendy plane.

This new plasma engine works a bit of much like a combustion engine, whereby plasma is generated from a supply gasoline which is then, in flip, heated quickly and allowed to develop to generate thrust. In the new engine, the ionized air is used to supply a low-temperature plasma that’s then fed right into a tube utilizing an air compressor. As the air travels up the tube it’s bombarded with microwaves, which violently shake the ions, inflicting them to impression different non-ionized atoms.
This course of drastically elevated the temperature and strain of the plasma, thereby producing important quantities of thrust additional down the tube.

This wonderful feat is achieved, partially, by way of the use of a flattened waveguide (an oblong steel tube) by way of which the microwaves are focussed. Generated by a specifically designed 1KW, 2.45-Gh magnetron, the microwaves are despatched down the information that tapers right down to half its preliminary measurement because it approaches the plasma, after which expands once more. This course of boosts the electrical discipline energy and impacts as a lot warmth and strain to the plasma as potential.

A quartz tube can also be positioned in a gap in the waveguide at its narrowest level. Air is compelled by way of this tube, then passes by way of a small part of the waveguide, after which exits the different finish of the quartz tube.

As air enters the tube, it passes over electrodes which might be topic to a really excessive discipline. This therapy strips electrons off a few of the air/gasoline atoms (largely nitrogen and oxygen), which creates a low-temperature and low-pressure plasma. Air strain from the gadget’s blower at the entry to the tube then ushes the plasma additional up the tube till it enters the waveguide.

Once the plasma is in the waveguide, the charged particles begin to oscillate inside the microwave discipline — inflicting speedy heating. In doing so, the soup of atoms, ions, and electrons collide with each other regularly, spreading the power from the ions and electrons to the impartial atoms, heating the plasma quickly.

As a outcome, the researchers declare that the plasma quickly heats to properly over 1,000°C. The exhausted sizzling plasma creates a torch-like flame as the sizzling gasoline exits the waveguide, thus producing thrust.

How highly effective is the new plasma engine?

If the airflow in the compressor is saved finely tuned, the flame jet produced in the tube, the researchers seen, appeared to elongate in response to a rise in microwave energy. Based on this commentary, the researchers tried to quantify how a lot thrust was being produced.

While this sounds comparatively easy on the floor, it got here with one severe catch. The thousand-degree plasma jet produced by the engine would destroy a daily barometer.

To overcome this, the group determined to suppose a bit of outdoors the field. They devised a technique to steadiness a hole metal ball on high of the tube. This ball was stuffed with smaller metal beads to vary its weight as and when required. At a sure weight, the thrust can be such that it might counteract the gravitational forces appearing on the ball downwards on the exhaust finish of the tube, permitting it to be elevated at a sure top above the tube.

new plasma engine
Schematic of the newly designed plasma jet thruster. Source: Dan Ye et al 2020.

You can try the actual footage of the engine in action here.


more @ https://thehackposts.com/a-new-electric-jet-engine-actually-works-inside-the-atmosphere/
 
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Across China: Chinese medical researchers develop AI hand to aid disabled
Source: Xinhua| 2021-10-21 14:05:09|Editor: huaxia

by Xinhua writers Lyu Qiuping and Xia Ke

BEIJING, Oct. 21 (Xinhua) -- An artificial intelligent hand has been developed by a Beijing-based medical team, which can help disabled people in simple jobs like unbuttoning clothes and lifting a cup.

Unlike traditional artificial limbs, the wearable bionic hand, with signal sensors tracking morphological skin changes, can collect signals of finger movement intention transmitted through muscles. These signals are then sent via skin to the bionic fingers, especially the thumb, to realize the movement intention of the fingers, said Yang Yong, a senior surgeon from Beijing Jishuitan Hospital who is the team leader of this project.

To better control the "fingers," the patient wearing the artificial hand needs to undergo a surgery named the muscle redistribution technique (MRT) to redistribute the key muscles of the remaining part of the patient's disabled arm, said Yang.

The key muscles will be sutured into the skin so that the finger movement signals of the muscles can make morphological skin changes, which are then collected by the sensors on the skin surface. The bionic fingers, combined with the electromyographic signals of the forearm, can then make corresponding movements, Yang added.

According to the hospital, two patients have undergone MRT surgery on the distal forearm level.

Zhou Ping (pseudonym), from Xiongxian County in north China's Hebei Province, lost his right forearm two years ago in an accident. Since receiving the MRT operation and being equipped with a bionic hand two weeks ago, he has begun to feel the changes in his life.

"I now can grab a glass of water, unbutton shirts and pick up small things like marbles using the bionic hand," Zhou said, adding that he puts it on every morning, and takes it off before going to bed.

This is not the first time for Chinese doctors and researchers to develop intelligent bionic hands.
In July last year, a Shanghai-based tech firm, OHand, donated 24 self-developed bionic hands to people with disabilities.

Through the aggregate movements of its 280-plus parts, the artificial hand can make more than 20 gestures, such as grabbing and pinching, and even control chopsticks.

There are 85 million disabled people in China, of which nearly 25 million have disabilities related to limbs, showed data released by the China Disabled Persons' Federation.

The country will facilitate scientific and technological innovation and talent development for better care and support for people with disabilities from 2021 to 2025, stated a plan on stepping up the protection of the rights and interests of people with disabilities issued in July by the State Council, China's cabinet.

Yang believes that with further improvement of the MRT as well as the sensors and smart hand functions based on the feedback of patients, the technology will benefit more people with physical disabilities and improve their quality of life.
 
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Chinese researchers develop new approach to lower cost of hydrogen fuel cells
Source: Xinhua| 2021-10-22 13:29:37|Editor: huaxia

HEFEI, Oct. 22 (Xinhua) -- Hydrogen energy is an efficient and clean new energy, but the high cost of producing hydrogen fuel makes its wider application difficult. Chinese scientists have recently developed a new approach to produce a series of high-performance platinum alloy catalysts, which is expected to lower the cost of hydrogen fuel cells significantly and promote their industrialization.

With platinum-based catalysts, hydrogen fuel cells can convert chemical energy into electricity through a chemical reaction between hydrogen and oxygen. Platinum, a precious metal that serves as a key element in this chemical reaction, makes hydrogen fuel cells very expensive.

Liang Haiwei, a professor at the University of Science and Technology of China who led the research, has developed a sulfur-anchoring approach for the synthesis of platinum-based alloy catalysts that can reduce the use of platinum to one-tenth of its amount of commercial platinum-carbon catalyst to achieve a similar fuel cell performance. It took Liang and his team members five years of research to obtain this outcome.

"Platinum accounts for about 40 percent of the production cost of hydrogen fuel cells. We aim to reduce the price of hydrogen fuel cells by reducing the use of platinum," said Liang, adding that this new approach has laid a solid foundation for achieving the goal.

The research result was published in the journal Science on Friday.

"This work is one of the most comprehensive and systematic studies of intermetallic nanoparticle formation and their resulting catalytic properties. This accomplishment is quite impressive. In that regard, the manuscript will be read and cited broadly," one of the journal's reviewers commented.

Liang said there are still many challenges before putting the approach in real-life application, and his team has forged cooperation with relevant companies for further development of the technology.

 
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