opposition. to privacy matters where every word and move could be reported possibly used against human rights activists in britain fight a rising number of surveillance cameras there now to be installed in every taxi in oxford authorities insist that the risk of intrusion is acceptable compared to the public safety benefit. more news and half hours time but first latest edition of technology update stay with us here on r.t. . hello and welcome to technology update as you can see from the decorations at this department store in central moscow it's that time of year again now this artificial tree there's hardly any resemblance to the aromatic conifers of my childhood new materials are replacing natural and traditional ones left and right and that's

especially true with carbon fibers what are increasingly finding their way into our latest gadgets and playthings. from carbon fiber have actually been around for decades recreation like golf and boating or everyday things like cell phones watches in cars carbon fiber products are all around us. and here at muscovy each a refurbished car plant russia is certainly not one to be left out of the push to develop the latest generation of carbon fiber materials just this past month a european aerospace delegation came to moscow to check out the opening of compazine new production complex the plant is expected to become the country's largest carbon fiber based textile maker. in the overall global tendency and the forecasts by many analysts are both indicative of the fact that in the near future possibly in a matter of a few years the demand for these materials can skyrocket and this may bring about

changes to the entire global economic system we are talking about millions of tons as soon as this breakthrough that is to say quantum leap occurs it will mean a revolution in technology a new world and russia must be prepared for it. before we can get to the carbon in products it's a rather long process first we have to make polymer resin which looks like honey or maple syrup there are several ways to go about it but basically polymers are mixed with a diluting agent there he didn't stir which causes the molecules to arrange into a long chain and that's what gives the fiber its strength as the so-called hand fiber is spun thousands of individual filament are woven together. at this stage the fiber is still rather fragile as it stretched by a series of rollers it passes through to remove the excess elements additionally certain tubs and give the forming fiber desired properties like resistance to static dry further to continue orientating depends on the stretching helps align

the molecules within the fiber and provides the basis for the formation of the tightly bonded carbon crystals. the next stage involves producing carbon fiber from spun fiber. that consist of two sub stages oxidation. there are two types of carbon fiber high strength and high modulus fiber. strength fiber is produced with the help of carbon ization . last fiber is obtained through a process called. it is. at this stage our threads are made more thermally stable by picking up oxygen molecules from the air we are by their atomic bonding pattern is rearranged from here they're put through to furnace is where they lose most of their non carbon atoms depending on their intended use they're

either carbonized or graphic tightest carbon is ation involves slightly lower temperatures and as a result a lower carbon content after drying each fiber is now comprised of more than ninety percent carbon atoms. before the carbon fibers could become a thing like this tennis racket there's a few more steps to go and that takes us back to the production facilities here and must reach this state of the art plant the carbonized fibers or they will run into whole fabrics the new production line is outfitted with three looms number one will be able to turn out six hundred kilograms of textile a day which will supply strong with your real for construction and repair projects the second and third looms will produce an additional one hundred thirty kilos a day by two thousand and fifteen this factory could produce two thousand tonnes a year. we run a wide range of material tests for our customers the so-called qualifying.

these materials are designed to be used subject to extremely high loads they require a very thorough testing. for example the world standard for materials is to pass sixty to seventy thousand tests successfully. that means we have sixty to seventy thousand various samples for different kinds of tests designed to check a full range of the materials properties. for those textiles can find their way to some of the latest technology there's still one more step in the process the fabrics are turned into what are called which stands for impregnated material they're basically the last intermediate phase before they're ready to be used in a whole host of things in this so-called pre pregnant stage specialized equipment precisely introduces the proper amount of resin on to the fibers after being properly positioned the fibers are. coated with resin to the right thickness the

sandwich of backing materials resin and fibers is then compacted by several sets of rollers and he did to a precise temperature for a specific amount of time that causes the resin to slightly here and solidify through cross-linking after it comes off the press it's now ready to be shipped to clients which can then be molded into sheets of whatever they need. china are no doubt attractive markets but nonetheless we mainly focus on russia because we monitor external markets for benchmarking purposes such as to work out the pricing or to compare technologies in order to be able to produce a competitive product customers. the advantages offered by their lightweight and super strength uptake in airplane manufacturing the. fifty jet that. air show in august is made from the cutting edge of carbon composite but amidst all the hustle and bustle of holiday shopping keeping your sanity and health ought to

be on your mind as well. tell you. early most important factor in overcoming serious. one of the most exciting branches. radioisotopes. of the twentieth century. doctors all over the world have greatly increased the amount of. help. they can be. attached. from the target.

behavior. isn't as easy as one would hope for decades if you wanted to. he had to come here. a physical chemistry and. here's the key parent radioisotope produced. to produce. the resulting fission reaction. approximately six percent of the. the institute manufactures its own uranium targets and irritates them in the w w r t s reactor the facilities here and have been turning out molybdenum for over a quarter of a century supplying to just about all of the isotopes that the countries needed up

until very recently the institute has produced ninety nine percent of the molybdenum used in the russian markets given the fact that we're essentially dealing with highly enriched uranium there are extremely limited number of places where molybdenum can be produced. we started producing molybdenum in 1980's. a while after that in the institute of physics in. the same production process. but it's reactor was shut down in two thousand and two. as it reached the end of its service term. but. to date we remain russia's biggest commercial molybdenum producers his impressive idea came. from. looking at current molybdenum supply production is dominated by just

a handful of reactors the two largest account for over sixty percent of global demand those two reactors are both over fifty years old and well beyond their intended service life when they're eventually decommissioned new suppliers will have to be found several alternatives are being explored including one in russia that's been recertified especially for isotopes. that takes us to dimitrov grad where a new look production site has been set up late last year a company called isotopes began pumping out the radio nuclei at the research institute of atomic reactors well it's not yet up to full capacity is already started deliveries to clients like one of the world's leading isotope provide. norty and ensuring reliable deliveries of molybdenum is so important because it accounts for over eighty percent of all nuclear medicine operations worldwide and here in the meter of grad such a vital issue required a new solution. this technology has not only been reworked in the chemical sense

but also in terms of the equipment and in this regard it's a new technology not available anywhere else as far as i'm aware and at the moment we're currently at the production startup stage. after the targets are cooled there transported to hot cells for processing that involves dissolving the whole target in a chemical solution solid residues are filtered out and the molybdenum is extracted using sailing or ammonium hydroxide here new technology saves time which is important because every hour after a year addition about one percent of the isotope is lost to radioactive decay it. would move our production target is eight hundred units today we produced one hundred sixty there was a shipment yesterday that's the first phase of our production at the same time we continue working on the second stage and expected to reach its design capacity in two thousand and twelve. the output target here is very high about two thousand

four hundred juries per week. overall demand is estimated at one hundred or. so once production ramps up doctors should have all the isotopes they need to perform lifesaving diagnostics. but in addition to giving doctors a leg up on spotting disease radioisotopes can also be used in medical centers like this to cure what ails us. for some medical conditions the radiation let off by these isotopes can be harnessed to destroy weaken malfunctioning cells just like in diagnosis by choosing the appropriate isotope radiation can be localized in a specific organ or tissue for example another isotope produced alongside molybdenum iodine one thirty one can be taken orally to fight fire with cancer with christmas and new year come presence and with presence comes trash in many

countries much of it just ends up in municipal landfills but as the rubbish piles up people are increasingly looking for alternatives to simple study dumps. in countries with no shortage of extra space landfills have been a common way to dispose of trash according to some estimates about thirty five million tons of municipal waste is generated every year in russia and more than ninety five percent of it ends up at landfills but there weren't enough of an eyesore they also emit harmful greenhouse gases every year russian landfills release an estimated one billion cubic meters of the stuff into the air. waste management is one of the most pressing issues in moscow and. to a large population producing large amounts of waste. that's something we all do and it can't be helped. as of today reachin has eighty eight officials and.

ten of them have been shut down due to having reached their allowed service. some of them have been reclaimed. waste incineration has been an alternative to city dumps but they also haven't been without their problems while less mess. it is emitted cancer causing dioxins are created over the latest generation to energy plants like the one in russia developed by green light energy solutions seems to have solved that it can process just over three hundred tons of. every day including recyclable materials. filtered out at the preprocessing. sorting trash passes through a shredder and dryer. is taken down to twenty. minutes into the specially designed chamber thanks to unique technology greenlight. is confident that it's much better

for our environment than any other way. technology is unique as it allows energy to be produced from waste in an environmentally friendly way without any toxic fumes discharged into the air without any toxic residue at the end of the process and this technology is also cost effective it produces much more energy than it consumes to keep running. unlike typical trash burning facilities this one currently located in. which means the trash isn't actually burned despite temperatures reaching up to eight hundred fifty degrees celsius the waste isn't because there's no oxygen in the reactor since the trash is heated. the waste materials. and the carbon residue which is between two percent of the original trash that entered the chamber and

thanks to its combustion free methodology there's no residual and pollute the area around the plant but in order to do that a different kind of chamber has to be developed so. the main difficulty we faced was to produce a proper cast reactor required for incinerating the waste needed to be made of material. which would be both. and he proof and such materials hardly exist we developed a special formula of cast iron that has never been produced before i simply know one could do it. but after a good amount of searching. stepped up to the plate to create the specific type of green light energy needed induction tons of. into the liquid mass and aluminum or added something which has never been done before the whole process has to be done pretty quickly because aluminum dregs can stick to the walls of the

furnace. reactor. the metal. and other affiliated parts the result is a new type of extremely resistant. keeping track of everything going on at the plant could be extremely complicated a state of the art computer system allows the workers to control just about everything with a simple click of the mouse from the control room on site safety indicators can be monitored and all actions can be easily regulated safety controls are especially important since the oxidation chamber burns a result at one thousand two hundred degrees celsius for two and a half seconds these extreme temperatures are needed to destroy all harmful toxins . from here. is converted into high temp steam which is used to spin turbines and create a renewable source of energy. to go out five seven megawatts is a lot of energy. is able to produce about forty five thousand megawatts

per year. that's going to help us to provide about ten to twenty thousand homes with electricity and heating depending on consumption rates and. electricity. another economically viable by product carbon charge because it doesn't contain those. other toxins they can be sold on as an environmentally clean product for making things like fuel. technology significantly reduces the emission of greenhouse gases it could also be used to generate up to one million carbon credits under the kyoto protocol. the first to be placed in check of another one. and then. they plan to have thirty plans. over. the end of the year is always

a good time to reflect on what we've done in the past twelve months as well as what we hope to accomplish in the next and for some that's easier than most like those that recently took part in the fourth russian innovation convention. the digital. brought together the nation's top innovators highlighting the latest ideas from russia up and coming entrepreneurs was attended by some of the biggest names in innovation from all over the world plenty of presentations and demonstrations the most important part of the gathering announcing the winners of the coveted prize more than eight hundred innovators aged under thirty took part in the competition but in the end only eight could walk away with something in hand and one of those alexander was recognized by the judging committee for its second year in a row. thank you very much. so with that in mind we

decided to pay the innovator a visit and see what he's been working on first we checked out his project from which is already blossomed into a full fledged startup called. production facility in moscow they showed off their unique technology developed by alexander. thanks to high powered water and the right mix of abrasives industrial. to weigh in. a matter of mere minutes. dirt and grime is nothing new typically things like rotor blades in aircraft engines are using sand blasting techniques given the potential to damage these important parts past technologies and try to strike the right balance between removing the build up and not harming the structural integrity of the underlying surface but as you can see here the previously rusted in series the dirty tools have now become as good as new. in the west to use abrasive agents. or dry ice which are less harsh than methods involving physical impact. all these

methods have several major downsides such as high material costs production costs and difficulties in complex cleaning tasks. we have managed to develop solutions for all of these issues. domestic materials which can be easily produced in any of russia's regions only traditional blasting methods spence's multi blast mixes water with the abrasive at the very beginning this is to take advantage of something called the rev. back in one thousand twenty eight the soviet scientists. showed it can be broken down more easily when they come into contact with an absorption active liquid like water and with this compressed air is used to accelerate the mixture to the speed of sound and it's fired at the buildup we want to get rid of however with. the abrasive is completely encased by a small water bubble the size of the abrasive granules depends on what we want to get rid of the unique thing here is that on contact the water works its way into

the pores of the buildup that has the dual benefit of penetrating and weakening the structure of the target as were particularly harmful effect the abrasive has on the underlying surface of the invention as well as production units have gone through the complete process from an idea to the product we started with design. then produced prototypes we went through the process then we produced a pilot batch of three units we made the manually. by the time we go to. commercial production our solution has evolved into an innovative product. and there's apparently no shortage of interested customers especially in the energy sector thermal electric power plants like these serious build up an important parts can eat into the energy efficiency and profit as well as increase the chance of an accident but moving from cleaning power plants to what we do with electricity is the topic of alexander's most recent creation. this is

a wireless charging unit for any portable devices such as mobile phones tablets laptops it can be used on travel on trains planes in hotels cafes restaurants and users will no longer have to depend on having an electric socket around remembering to take the relevant cord with them it will be in the past i think a major potential clients are the mobile phone manufacturer is. nokia apple possibly motorola because switching to producing phones with wireless charging is a big competitive advantage on the market. and that's not something that's been lost on many of the world's top mobile makers a good number of them have teamed up to form. there are already a decent number of so-called wireless charges on the market however at present all of them still require you to place your mobile device on

a charging pad and with some you need a separate charger for each device they give you a bit more freedom but our phones are still tied directly to some kind of plugged in charger which to us there is a number of issues around this solution among them the impact on human health or performance impacts on other electronic devices in the vicinity the most important thing here is that we've succeed. bringing these devices efficiency up to a very high level about eighty five percent and that's not the only thing alexander thinks his why with charger offers over the competition it can theoretically work with any mobile device but most importantly this russian prototype can top up your battery anywhere around the charger not just on a pad unlike with the others why roll works effectively up to thirty centimeters away from the base of this device uses the principle of the tesla coil as the energy producing coral installed inside the mobile device in turn is equipped with a receiver designed as a stick and stick it we have developed

a special feed circuits for the coil which use a very high efficiency facts about eighty five percent and this is achieved through the use of a switch mode power supply unit for the coil in other words while any inductive system goes through the oscillation build up phase in order to build up the energy production in our device but there is no buildup as such we sense of the process just once and it exonerates through induction we only given hansing impulses once in a while. and your device is still in the project stage what more do you need to do to bring it to the market. to start commercial production of this device we need to meet three requirements first we need to complete the prototype and run it through all the necessary tests then make all necessary improvements in changes and produce a pilot batch. or store

a second we need to have all the patients registered and third we need to set up a technology company in accordance with international standards. with any luck that wireless charger could hit the market sometime soon and we hope that it and the other developments we've showed you today make the future seem well just a little brighter so we'll see you next time and until then enjoy the ride. culture is that so much of an oldish each musician can find in the market with the american occupation of iraq officially coming to a close this week it's time to take stock was the war in occupation worth it for the.

this is. history making. testimony. ten stories that shapes two thousand and eleven.

dozens killed in syria's capital in the first bombing since the uprising began his arab league observers got down to business in an effort to mediate a peace deal there. leaving the nation in despair tensions are running high in iraq as the government plunges deeper into crisis after a bombing atrocity claimed more than seventy lives just days after the pullout of u.s. troops. every breath you take every move you make could be more corded human rights activists in britain fighting a surge of surveillance cameras now to be installed in every taxi in oxford.