The latest innovation in time crystals can expand the known limits of quantum mechanics.
Scientists have revealed a new kind of time crystal that challenges our traditional understanding of time and movement. You Known limits of quantum mechanics may be extended.
Theoretically, a time crystal is able to travel the same pattern infinitely without needing additional energy – like a clock that never needs to be given rope.
Unlike a traditional crystal, which repeats a pattern through the physical dimension of space, a time crystal repeats a standard of movement, reorganizing its atoms the same way over time. This causes the time crystal to vibrate to a defined frequency.
On the margin of study last week in Physical Review Xthe physicians created a new Time -crystal that may help confirm some fundamental theories about quantum interactions and, according to scientists, challenge our traditional understanding of time and movement.
In addition, although time crystals exist, a team got something unprecedented: they created a new type of time crystal called quasicristal.
As writes, a quasrystal is a solid who, like a normal crystal, has atoms arranged in a specific and not random way, but without a pattern of repetition.
Unlike a normal time crystal that repeats the same pattern times without account, a quasrystal never repeats the way atoms organize.
As there is no repetition, The crystal vibrates at different frequencies.
As those researchers at the University of Washington in St. Louis (Washu) say, cited by Live Science, time quasrystals “are ordered but apparently not periodic,” challenging traditional concepts of time and movement.
Evolution in Quantum Mechanics
As the same magazine explains, to create these new temporal quasrystals, the investigators started with a piece of millimeter diamond.
Then they created spaces inside the diamond structure, bombarding it with powerful nitrogen beams. The nitrogen shifted carbon atoms inside the diamond, leaving behind empty atomic cameras.
Nature abhors the vacuum, so the electrons flowed rapidly into these empty spaces and immediately began to interact with the neighboring particles at the quantum level. Each quasrystal represents a network of more than one million of these empty spaces in the interior of the diamond, although each one measures only one micrometer (the millionth part of one meter).
As Live Science says, time quasicerists can have practical applications in domains such as Precision Timinga quantum computing and the technology of quantum sensors.
