Examples of 'antihydrogen' in a sentence
Meaning of "antihydrogen"
antihydrogen (noun) - an antimatter counterpart of hydrogen, composed of an antiproton and a positron
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- The antimatter equivalent of hydrogen, consisting of an antiproton and an positron (antielectron).
- An atom of the antimatter equivalent of hydrogen.
How to use "antihydrogen" in a sentence
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antihydrogen
Antihydrogen atoms consist of antiprotons and positrons.
The line has also been measured in antihydrogen.
Antihydrogen is the only atom of antimatter to be produced in the laboratory.
First observation of the hyperfine splitting in antihydrogen.
The antihydrogen atom is the antimatter counterpart of the hydrogen atom.
Produced the first beam of antihydrogen.
The first experiments on antihydrogen atoms were just performed last year.
Recycling antimatter pertains to recycling antiprotons and antihydrogen atoms.
The antihydrogen atom and ion production takes place in a cavity.
The antiprotons were combined with positrons to produce antihydrogen atoms.
Some hundreds of millions of antihydrogen atoms have been made in this fashion.
Antiprotons can then combine with positrons to form antihydrogen.
The points where the antihydrogen annihilates are measured with a precise detector.
The positron cloud is then ready to be used for antihydrogen production.
The antihydrogen atoms are created by neutralising antihydrogen ions using laser pulses.
See also
A study shows that it has successfully produced and trapped atoms of antihydrogen.
The ultimate goal of antihydrogen experiments is to compare its properties to those of hydrogen.
We find a particularly high quantum reflection for an antihydrogen atom on a surface of liquid helium.
Colder antihydrogen atoms could also be used to measure the gravitational property of antimatter.
Experimental principles for making antihydrogen and for the materials science applications.
Description and first application of a new technique to measure the gravitational mass of antihydrogen.
The discovery reveals the spectral structure of the antihydrogen atom in unprecedented colour.
The antihydrogen atoms were produced in flight and moved at nearly the speed of light.
Now physicists face the more daunting challenge of capturing neutral antihydrogen atoms.
ALPHA experiment shows antihydrogen charge is neutral.
CERN experiment makes spectroscopic measurement of antihydrogen.
Trajectories of antihydrogen atoms from the ALPHA experiment.
CERN makes first precise measurements of antihydrogen.
That 's why neutral antihydrogen is so important.
ASACUSA is also developing complementary techniques for studying antihydrogen.
The paper reports that the transition frequency of antihydrogen is consistent with that of hydrogen.
ATRAP members also pioneered accurate hydrogen spectroscopy and first observed hot antihydrogen atoms.
If antihydrogen atoms were suspended in a perfect vacuum, they should survive indefinitely.
The ALPHA experiment at CERN has successfully made and trapped hundreds of antihydrogen atoms.
That provides the nucleus of the antihydrogen atom, the antiprotons.
Right now, what we are doing is we are routinely trapping antihydrogen.
If antigravity exists, antihydrogen will rise, and that will be easy to observe.
Nevertheless, it is possible to produce significant amounts of antihydrogen in.
Within the precision of this first measurement, antihydrogen is found to behave as hydrogen would.
In a pion rocket, antimatter is stored inside electromagnetic bottles in the form of frozen antihydrogen.
Observation of Antihydrogen.
For example, excited antihydrogen atoms are expected to glow the same color as regular hydrogen.
The standard symbol for antihydrogen is '.
When antihydrogen comes into contact with ordinary matter, its constituents quickly annihilate.
Lyman-alpha transition observed in antihydrogen.
While antihydrogen atoms are electrically neutral, the spins of their component particles produce a magnetic moment.
This is possible because the magnetic moment of antihydrogen is non-zero.
Antihydrogen atoms are produced in a vacuum at CERN, but are nevertheless surrounded by normal matter.
Theoretically as mirrors of the same element, hydrogen and antihydrogen should share this pattern.
This caused the antihydrogen atoms to undergo something called the Lyman-alpha transition.
