DO SCIENTISTS KNOW THIS MACHINE is USED to TRY TO GET REPTILIANS and DRACONIANS to invade our PLANET? If YOU know SOMEONE who WORKS there THEN these CIA CONTROLLED [DATABASE] HIDDEN underground at CERN AS well. They NEED TO BE INFORMED, AND CERN NEEDS TO GO, PERIOD BEFORE THEY DESTROY OUR PLANET! LET’S HOPE THEY REALLY DID, BLOW-UP, THERE IS ANOTHER ONE, listed below.
LET’S SEE what CERN is up to THESE DAYS. FROM ONE OF THEIR SITES.
http://home.cern/about/updates/2015/11/new-knowledge-transfer-website-grow-cerns-industry-links
CERN’s Knowledge Transfer Group has just launched a new tool to encourage CERN researchers and businesses to share their technologies, ideas and expertise.
It’s hoped that by facilitating these exchanges the tool will inspire new ways to apply CERN technologies commercially, to help benefit industry and society.
Interested organizations including small-to-medium sized businesses specially, research centres, large industrial organizations and universities, can subscribe to the website here, and download a KT newsletter.
The newsletter will include up to date information on the technologies generated at CERN and their potential uses and benefits in the subscribers’ business sector.
In turn, organizations will then be able to share their particular interests related to CERN technologies and expertise.
There are already many successful enterprises which exist due to CERN’s Knowledge Exchange network.
For example, data generated by the CERN-developed software Fluka, is now integrated into the patient cancer treatment planning system implemented by Ray Search Laboratories in Sweden(link is external). There are also several start-ups including Terabee(link is external) in France, which uses co-developed sensor technology from CERN for indoor drone navigation. And TIND(link is external) in Norway, which develops software solutions around CERN Invenio technology, and counts among its customers CalTech, the Max Planck Institute and the United Nations.
More like this
- CERN supports new business incubation network in Spain
- Welcome to .cern
- New partnership encourages businesses to develop CERN tech
- Business Incubation Centre of CERN tech opens in Norway
- CERN technology that could help out in space
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CERN WEBSITE IS MOVING? WE HEARD they have THEY own INTERNET!
LOOKS LIKE the ENEMIES of MAN WANTS TO EXPAND CERN!
CERN’s core website is moving to a new address, http://home.cern, with the launch of the brand new top-level domain .cern.
The suffix at the end of an internet address, such as .fr, .com or .org, is called the top-level domain (TLD), and was originally intended to signify its country of origin or type.
Until now, all CERN webpages have ended cern.ch.
CERN is an intergovernmental organization with 21 member states, and its name is recognized globally as the leading laboratory for high-energy physics. More than 10,000 visiting scientists from over 113 countries – half of the world’s particle physicists – come to CERN for their research. The organization has two main sites in Switzerland and France and the LHC runs through both countries with experiments on both sides of the border.
As such, a domain that limits CERN to one country doesn’t acknowledge the international, and increasingly global, nature of the organization, nor that its science and values transcend geographical and political boundaries.
With its history as the birthplace of the web, and as an early adopter of the internet, CERN has always been at the forefront of computer networking. So in 2008 when the Internet Corporation for Assigned Names and Numbers (ICANN) opened up applications for TLDs to new generic names and brands, CERN registered for its own.
The .cern address is one of over 1300 new top-level domains that will launch over the coming months and years.
The transition to the .cern address has already taken place behind-the-scenes so visitors to the CERN website will not have to change their habits. Visitors to some cern.ch addresses will be automatically redirected to .cern ones, and any existing links and URLs that you may have bookmarked will remain valid. Current CERN personnel will be eligible to apply fordomains soon, for more information please refer tothe registration policy.
After the successful restart of the Large Hadron Collider (LHC) and its first months of data taking with proton collisions at a new energy frontier, the LHC is moving to a new phase, with the first lead-ion collisions of season 2 at an energy about twice as high as that of any previous collider experiment. Following a period of intense activity to re-configure the LHC and its chain of accelerators for heavy-ion beams, CERN’s accelerator specialists put the beams into collision for the first time in the early morning of 17 November 2015 and ‘stable beams’ were declared at 10.59am today, marking the start of a one-month run with positively charged lead ions: lead atoms stripped of electrons. The four large LHC experiments will all take data over this campaign, including LHCb, which will record this kind of collision for the first time. Colliding lead ions allows the LHC experiments to study a state of matter that existed shortly after the big bang, reaching a temperature of several trillion degrees.
“It is a tradition to collide ions over one month every year as part of our diverse research programme at the LHC,” said CERN Director-General Rolf Heuer. “This year however is special as we reach a new energy and will explore matter at an even earlier stage of our universe.”
Early in the life of our universe, for a few millionths of a second, matter was a very hot and very dense medium – a kind of primordial ‘soup’ of particles, mainly composed of fundamental particles known as quarks and gluons. In today’s cold Universe, the gluons “glue” quarks together into the protons and neutrons that form bulk matter, including us, as well as other kinds of particles.
“There are many very dense and very hot questions to be addressed with the ion run for which our experiment was specifically designed and further improved during the shutdown,” said ALICE collaboration spokesperson Paolo Giubellino. “For instance, we are eager to learn how the increase in energy will affect charmonium production, and to probe heavy flavour and jet quenching with higher statistics. The whole collaboration is enthusiastically preparing for a new journey of discovery.”
Increasing the energy of collisions will increase the volume and the temperature of the quark and gluon plasma, allowing for significant advances in understanding the strongly-interacting medium formed in lead-ion collisions at the LHC. As an example, in season 1 the LHC experiments confirmed the perfect liquid nature of the quark-gluon plasma and the existence of “jet quenching” in ion collisions, a phenomenon in which generated particles lose energy through the quark-gluon plasma. The high abundance of such phenomena will provide the experiments with tools to characterize the behaviour of this quark-gluon plasma. Measurements to higher jet energies will thus allow new and more detailed characterization of this very interesting state of matter.
“The heavy-ion run will provide a great complement to the proton-proton data we’ve taken this year,” said ATLAS collaboration spokesperson Dave Charlton. “We are looking forward to extending ATLAS’ studies of how energetic objects such as jets and W and Z bosons behave in the quark gluon plasma.”
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