The Clocks

Agatha Christie's classic "watch" is awkward in time as Hercule Poirot investigates the strange case of the body surrounded by countless clocks at the blind female house.

Hilla Weber wants to find a worthy blind woman waiting for her in the new moon of 19-year-old Will Bram - not a middle-aged man walking on the floor of the living room. However, they obviously needed a very good detective when Miss Pessimas denied that they first give her to her or have all the watches around her body.

"This crime is very complicated and it must be very simple," Poirot said. But the murderer is loose, as time goes on

In the case of a watch, the time it conveys and the energy necessary to move it form a Heisenberg pair. The more accurate the clock reading, the less accurate the amount of energy involved. As a result, the energy of the watch is in a state called quantum superposition. The energy discussed can be big or small at the same time - as Schrodinger's cat lives and dies. At this point, quantum mechanics and relativity collide with each other. One result of Einstein's theory is that energy and quality are equivalent. This means that energy is as gravity as mass. The second result is that gravity changes the flow of time. Expansion of this gravitational time is a mature phenomenon. For example, atomic clocks at various heights on the earth are not synchronized with each other because of different gravity.

Dr. Bruckner and his colleagues observed in their own hypothetical clock that the quantum superposition of their energy states implies that the gravitational effects of these energy states also exist in the quantum superposition. Therefore, the expansion of time caused by these gravity effects also overlaps. To make matters worse, the second quantum effect entanglement signifies that the first quantum effect is also influenced by the superposition due to the influence of the gravity of the first quantum effect, and instead, similar to the original timepiece Influence. Regardless of the specific details of the mechanism, the clock is the only way to measure time, so the entire concept of time itself becomes blurred.

As of the 2010s, atomic clocks are the most accurate watch available. They are more accurate than quartz watches as they can be accurate to a few seconds in thousands of years. Sir Kelvin theorized the atomic clock first in 1879. In the 1930's, the development of magnetic resonance created a practical approach to achieving this goal. The prototype ammonia maser was built in 1949 by the American National Standards Bureau (NBS, now NIST). It is not as accurate as the existing quartz clock, but it helps to demonstrate this concept. The first precise atomic clock, the standard based on the atomic phase transition, was built by Luis Essen in 1955 at the National Physical Laboratory in the UK. Calibration of standard atomic clock using astronomical time ephemeris time (ET)