The atom of the isotope caesium 133; the definition of second in SI is based on this atom.
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∙ 11y agoAtomic clocks typically use cesium atoms as the element to keep time. The precise frequency at which cesium atoms oscillate between two energy levels is used to define the second in these clocks.
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∙ 7y agoCaesium is used for atomic clocks.
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∙ 13y agoCesium
Cesium is the element commonly used in both photoelectric cells (for converting light into electricity) and atomic clocks (for measuring precise time intervals). Its high sensitivity to light and stable atomic properties make it ideal for these applications.
The metal described is likely to be Cesium. Cesium is known for its distinctive sky-blue spectral lines and is used in atomic clocks due to its atomic vibrations which help keep precise time. Atomic clocks utilizing Cesium can be accurate to 5 seconds in 300 years or 1 second in 60 years.
Cesium atoms are commonly used in the making of atomic clocks due to their consistent oscillation frequencies. These clocks measure time by counting the cycles of radiation emitted by cesium atoms, which allows for extremely accurate timekeeping over long periods. Due to cesium's stable and predictable behavior, atomic clocks using cesium technology only lose about 1 second every 300 years.
You are silver (Ag). Silver is commonly used to make photographic film due to its light-sensitive properties.
Uranium
Cesium is used to make very accurate atomic clocks. The oscillation frequency of radiation emitted by cesium-133 atoms is used to define the second in the International System of Units (SI).
Cesium is commonly used in atomic clocks due to its high accuracy in timekeeping. Photocells often use silicon as the element at their core due to its semiconducting properties, which allow it to efficiently convert light into electricity.
Atomic clocks use a specific element called cesium-133 (Cs-133) as the basis for their timekeeping. The atomic clock measures the natural vibration frequency of cesium atoms to accurately keep time.
Cesium is the element commonly used in both photoelectric cells (for converting light into electricity) and atomic clocks (for measuring precise time intervals). Its high sensitivity to light and stable atomic properties make it ideal for these applications.
That element is Cesium, which has a melting point of 28.5°C (83.3°F). It is utilized in atomic clocks due to its high accuracy in measuring time, and in photocells for its efficient photoelectric characteristics.
The atomic number 55 refers to the element caesium. Caesium atomic clocks use the natural resonant frequency of caesium atoms to measure time accurately. By measuring the vibrations of caesium atoms, these clocks can maintain incredibly precise timekeeping.
Cs is the chemical symbol for the element Cesium. Cesium is a soft, silvery-gold alkali metal with atomic number 55. It is used in atomic clocks, as a catalyst in organic synthesis, and in some medical applications.
The metal described is likely to be Cesium. Cesium is known for its distinctive sky-blue spectral lines and is used in atomic clocks due to its atomic vibrations which help keep precise time. Atomic clocks utilizing Cesium can be accurate to 5 seconds in 300 years or 1 second in 60 years.
Cesium is the chemical element used in atomic clocks to measure a second with high accuracy. Atomic clocks use the natural resonance frequency of the cesium atom to define the length of a second. This level of precision allows atomic clocks to keep time accurately to within one second in several million years.
Uranium and plutonium.
An atomic clock uses the vibrations of atoms to measure time, which is extremely precise and accurate. Ordinary clocks, like quartz clocks, use the oscillations of quartz crystals and are generally less accurate than atomic clocks. Atomic clocks are used in scientific research and industries where precise timekeeping is essential.
Both uranium and plutonium were used extensively to make the first two atomic bombs, dropped on Hiroshima and Nagasaki, respectively.