Papa Franjo : Bog nas sve još uvijek voli , čak i one najgore među nama

imamo u umjetnosti bečke dječake, zadnji kastrat je nedavno umro.
muški imaju veći raspon glasa od žena. došli smo do toga da nema više muškog soprana.
žene ne mogu biti tenori, a muški soprani.
kastrati su mogli odpjevati kao tenor sa sopranom.

pa bi recimo za sve koji se bave vjerom trebalo uvesti i kastraciju i sterilizaciju.
pa neka pjevaju.

Unimatrix_Zero wrote:Francuska raketa Arijana vrh tehnologije,amerima ni dan danas nije jasno kako sa manjim motorima i manje utrosenog goriva Arijana moze ponijeti istu kolicinu korisnog tereta kao i ove americke mrcine sa dva puta jacim motorima

dobar smjer Medo..kao i butalne nujove glave,koje su triput manje od jemerickih,a triput jace...sVE gdje se zatreba u svemirskoj tehnologiji,sam vrh rjesenja,tu uskacu francuzi..

RayMabus wrote:Ako mislite kupit nekretninu u Francuskoj moj savjet vam je nemojte. Tamo će počet nekakvi građanski rat. Previše su se oni demografski natrpali da mogu tek tako potirat Arape. To je tamo đumbus a svake godine je sve veći i veći.

Oni su...to je zbrka tamo.

ono cujem..Nostradamus nesh prorekao 2020 gori cijela Europa...sad ne znam preneseno ili doslovno..

T. wrote:Ovo govno triba skratit za glavu i ponovno ustoličit hitlerjugenda...

 ...puste zelje Ti... nekad hitlerjugend,danas metroseksualcici koji Turcadiji sluze za triskanje po usima..

pismejker wrote:

Unimatrix_Zero wrote:Francuska raketa Arijana vrh tehnologije,amerima ni dan danas nije jasno kako sa manjim motorima i manje utrosenog goriva Arijana moze ponijeti istu kolicinu korisnog tereta kao i ove americke mrcine sa dva puta jacim motorima

dobar smjer Medo..kao i butalne nujove glave,koje su triput manje od jemerickih,a triput jace...sVE gdje se zatreba u svemirskoj tehnologiji,sam vrh rjesenja,tu uskacu francuzi..

ti si fakat, a ono. glup. vi srblje i bosilje ste onako glupi po defaultu ili se tako češljate?
daj navedi neku firmu iz francuske koja radi na projektu ariane. i vodstvo istog projekta.
renault je japanski. grupaciju peugeot drži bmw. jedino dessault koji je nastao u kanadi u firmi bombanier je izvorno francuski. kupili su solid, a na kraju sve ih kupio siemens.

ti kao menadžer, daj nas prosvjetli.

pismejker wrote:

Unimatrix_Zero wrote:Francuska raketa Arijana vrh tehnologije,amerima ni dan danas nije jasno kako sa manjim motorima i manje utrosenog goriva Arijana moze ponijeti istu kolicinu korisnog tereta kao i ove americke mrcine sa dva puta jacim motorima

dobar smjer Medo..kao i butalne nujove glave,koje su triput manje od jemerickih,a triput jace...sVE gdje se zatreba u svemirskoj tehnologiji,sam vrh rjesenja,tu uskacu francuzi..

unikatne su to tehnologije

i ovaj pvo sistem Mistral je impresivan,brz i efikasan,bolji i od ruskih pvo sistema kratkog dometa,jebiga kad je bio izraelsko arapski rat izraelci su koristili francuske avione sa razlogom,ne americke,samo jebiga skupi su ko otrov

Unimatrix_Zero wrote:

pismejker wrote:

Unimatrix_Zero wrote:Francuska raketa Arijana vrh tehnologije,amerima ni dan danas nije jasno kako sa manjim motorima i manje utrosenog goriva Arijana moze ponijeti istu kolicinu korisnog tereta kao i ove americke mrcine sa dva puta jacim motorima

dobar smjer Medo..kao i butalne nujove glave,koje su triput manje od jemerickih,a triput jace...sVE gdje se zatreba u svemirskoj tehnologiji,sam vrh rjesenja,tu uskacu francuzi..

unikatne su to tehnologije

tako je..francuzi nisu za masovnost,ali profinjene tehnologije,medicinu,tu razvaljuju

Unimatrix_Zero wrote:i ovaj pvo sistem Mistral je impresivan,brz i efikasan,bolji i od ruskih pvo sistema kratkog dometa,jebiga kad je bio izraelsko arapski rat izraelci su koristili francuske avione sa razlogom,ne americke,samo jebiga skupi su ko otrov

tako je..francuski RAFALEiako vec vremesan,daleko je mocniji i savrseniji nego bilo sto su svabi napravili,opet ne sami nego neki fuckin konzorcij..

jesi citao ovo u vezi ovog Hydron Colider-a

The world's biggest and most expensive scientific experiment is ready to re-start
ALOK JHA FORMER SCIENCE CORRESPONDENT
Collider
The Large Hadron Collider will be switched back on tomorrow morning
Photo: ITV
Underneath some nondescript farmland near Geneva, on the border of France and Switzerland, the world's biggest and most expensive scientific experiment is ready to re-start.

The Large Hadron Collider (LHC) at Cern will help scientists investigate some of the biggest mysteries in the universe.

Play Video
In 2012, after the first run of the machine, the scientists here made headlines when they discovered the Higgs boson - a fundamental particle that has a role in giving other particles mass and which had been predicted to exist by theoretical physicists Peter Higgs,François Englert and Robert Brout almost 50 years earlier.

Higgs and Englert would go on to share the Nobel Prize in physics in 2013 (Brout was left off the list because he died in 2011 and the prize cannot be awarded posthumously).

For the past two years, the collider has been shut down and engineers have been upgrading every element of the accelerator and its detectors. When it starts again, it'll be able to reach twice the energy as it could before, allowing it to reach further into unknown areas of physics.

It will accelerate protons around a 27-kilometre ring underground to nearly the speed of light and then collide them in the centre of one of four huge detectors - Atlas, CMS, LHCb and Alice. Whenever the protons smash together, they explode into a shower of new particles. Sifting through that debris can give scientists a window into new, as-yet-undiscovered, areas of nature.

In Run 2, as the next phase of operation is known, the scientists want to go into the complete unknown. During the first phase of operation, many scientists were almost certain they would find the Higgs boson. That particle filled in the last piece of the Standard Model of particle physics, which describes all the particles and forces in the universe - including electrons, quarks and photons.

But, as successful as it has been, scientists know that the Standard Model is not a complete picture of the universe. It doesn't include a description of the force of gravity, for example, and can only account for around 4% of the mass of the universe. The remaining 96% of our cosmos is dark matter and dark energy and no-one knows what any of those things might be.

Collider
The Large Hadron Collider (LHC) at Cern will help scientists investigate some of the biggest mysteries in the universe Credit: ITV
The Standard Model also cannot explain why we don't see antimatter in the universe.

Antimatter is the same as normal matter except it has the opposite electrical charge. A positively-charged electron is known as a positron, for example, and when it comes into contact with an electron, the two particles annihilate into pure energy. At the beginning of the universe, a fractional amount more matter than antimatter seems to have come into existence from the big bang.

All the antimatter and most of the matter came together and annihilated - we and everything we see today is made from the matter that remained.

Scientists at the LHCb experiment at Cern will investigate why that might have happened.

Professor Tara Shears of the University of Liverpool explains what the LHCb experiment is designed to do:

Play Video
"We can't explain the difference we need to in order to explain how the universe evolved so we have a really big mystery to solve here," says Professor Tara Shears of the University of Liverpool, who works on the LHCb experiment. "And we are hoping in the next run we will see something that illuminates that difference for us and shows us what the deep underlying explanation is."

One of the leading candidates to plug some of these holes in the Standard Model is called "supersymmetry". An idea that was first formulated in the early 1970s, it suggests that all the fundamental particles we know about so far have heavier, as-yet-undiscovered "superpartner" particles. Some of these heavier particles could be candidates for dark matter, for example. If the LHC can find evidence for these superpertner particles in its collisions, scientists would be well on their way to proving that supersymmetry was real.

Sudan Paramesvaran of Bristol University, who works on the CMS experimentat Cern, and Professor Tara Shears told me what their experiments could mean for the public:

Play Video
"We don’t know what we are going to find," says Sudan Paramesvaran of Bristol University, who works on the CMS experimentat Cern. "If we did find supersymmetry or dark matter it would have such wide ranging implications not just for particle physics but for the universe in its entirety and astrophysics - it would be one of the most seminal moments of the 21st century."

Particle beams will soon start to circulate regularly once again around the LHC, for the first time in years. They'll be more powerful than ever and they'll give us a window onto a whole new era of physics.

pismejker wrote:

Unimatrix_Zero wrote:

pismejker wrote:

Unimatrix_Zero wrote:Francuska raketa Arijana vrh tehnologije,amerima ni dan danas nije jasno kako sa manjim motorima i manje utrosenog goriva Arijana moze ponijeti istu kolicinu korisnog tereta kao i ove americke mrcine sa dva puta jacim motorima

dobar smjer Medo..kao i butalne nujove glave,koje su triput manje od jemerickih,a triput jace...sVE gdje se zatreba u svemirskoj tehnologiji,sam vrh rjesenja,tu uskacu francuzi..

unikatne su to tehnologije

tako je..francuzi nisu za masovnost,ali profinjene tehnologije,medicinu,tu razvaljuju

je, vrancuzi razvaljuju.
tebi nisu svi doma?

Unimatrix_Zero wrote:jesi citao ovo u vezi ovog Hydron Colider-a

The world's biggest and most expensive scientific experiment is ready to re-start
ALOK JHA FORMER SCIENCE CORRESPONDENT
Collider
The Large Hadron Collider will be switched back on tomorrow morning
Photo: ITV
Underneath some nondescript farmland near Geneva, on the border of France and Switzerland, the world's biggest and most expensive scientific experiment is ready to re-start.

The Large Hadron Collider (LHC) at Cern will help scientists investigate some of the biggest mysteries in the universe.

Play Video
In 2012, after the first run of the machine, the scientists here made headlines when they discovered the Higgs boson - a fundamental particle that has a role in giving other particles mass and which had been predicted to exist by theoretical physicists Peter Higgs,François Englert and Robert Brout almost 50 years earlier.

Higgs and Englert would go on to share the Nobel Prize in physics in 2013 (Brout was left off the list because he died in 2011 and the prize cannot be awarded posthumously).

For the past two years, the collider has been shut down and engineers have been upgrading every element of the accelerator and its detectors. When it starts again, it'll be able to reach twice the energy as it could before, allowing it to reach further into unknown areas of physics.

It will accelerate protons around a 27-kilometre ring underground to nearly the speed of light and then collide them in the centre of one of four huge detectors - Atlas, CMS, LHCb and Alice. Whenever the protons smash together, they explode into a shower of new particles. Sifting through that debris can give scientists a window into new, as-yet-undiscovered, areas of nature.

In Run 2, as the next phase of operation is known, the scientists want to go into the complete unknown. During the first phase of operation, many scientists were almost certain they would find the Higgs boson. That particle filled in the last piece of the Standard Model of particle physics, which describes all the particles and forces in the universe - including electrons, quarks and photons.

But, as successful as it has been, scientists know that the Standard Model is not a complete picture of the universe. It doesn't include a description of the force of gravity, for example, and can only account for around 4% of the mass of the universe. The remaining 96% of our cosmos is dark matter and dark energy and no-one knows what any of those things might be.

Collider
The Large Hadron Collider (LHC) at Cern will help scientists investigate some of the biggest mysteries in the universe Credit: ITV
The Standard Model also cannot explain why we don't see antimatter in the universe.

Antimatter is the same as normal matter except it has the opposite electrical charge. A positively-charged electron is known as a positron, for example, and when it comes into contact with an electron, the two particles annihilate into pure energy. At the beginning of the universe, a fractional amount more matter than antimatter seems to have come into existence from the big bang.

All the antimatter and most of the matter came together and annihilated - we and everything we see today is made from the matter that remained.

Scientists at the LHCb experiment at Cern will investigate why that might have happened.

Professor Tara Shears of the University of Liverpool explains what the LHCb experiment is designed to do:

Play Video
"We can't explain the difference we need to in order to explain how the universe evolved so we have a really big mystery to solve here," says Professor Tara Shears of the University of Liverpool, who works on the LHCb experiment. "And we are hoping in the next run we will see something that illuminates that difference for us and shows us what the deep underlying explanation is."

One of the leading candidates to plug some of these holes in the Standard Model is called "supersymmetry". An idea that was first formulated in the early 1970s, it suggests that all the fundamental particles we know about so far have heavier, as-yet-undiscovered "superpartner" particles. Some of these heavier particles could be candidates for dark matter, for example. If the LHC can find evidence for these superpertner particles in its collisions, scientists would be well on their way to proving that supersymmetry was real.

Sudan Paramesvaran of Bristol University, who works on the CMS experimentat Cern, and Professor Tara Shears told me what their experiments could mean for the public:

Play Video
"We don’t know what we are going to find," says Sudan Paramesvaran of Bristol University, who works on the CMS experimentat Cern. "If we did find supersymmetry or dark matter it would have such wide ranging implications not just for particle physics but for the universe in its entirety and astrophysics - it would be one of the most seminal moments of the 21st century."

Particle beams will soon start to circulate regularly once again around the LHC, for the first time in years. They'll be more powerful than ever and they'll give us a window onto a whole new era of physics.

prostudiram malo kasnije..

ajd Weberu,odo ja,da ti previse ne dizem zivac..zakljucih poslije podrobna analiziranja,da ipak ti ne jebes tu svabicu,nego ona tebe...kad si ti vidio da sluga jebe svog gospodara...???
ajd ne se ljutiti,ali neke cinjenice moramo razjasniti...kupit ce tebi tvoja sefica buragov model X5,onai 1:47...