radioactive isotopes - traduzione in greco
Diclib.com
Dizionario ChatGPT
Inserisci una parola o una frase in qualsiasi lingua 👆
Lingua:

Traduzione e analisi delle parole tramite l'intelligenza artificiale ChatGPT

In questa pagina puoi ottenere un'analisi dettagliata di una parola o frase, prodotta utilizzando la migliore tecnologia di intelligenza artificiale fino ad oggi:

  • come viene usata la parola
  • frequenza di utilizzo
  • è usato più spesso nel discorso orale o scritto
  • opzioni di traduzione delle parole
  • esempi di utilizzo (varie frasi con traduzione)
  • etimologia

radioactive isotopes - traduzione in greco

ATOM THAT HAS EXCESS NUCLEAR ENERGY, MAKING IT UNSTABLE
Radioisotope; Radioactive isotopes; Radioisotopes; Radionuclides; Unstable isotope; Radioactive isotope; Radioactive material; Radio-isotope; Radionucleide; Commercially available radioisotopes; Radio isotopes; Radio isotope; Radioactive materials; Radioactive element; Radioisotope production; Radioactive nucleus; Radio-nuclide; Radioactive nuclide; Unstable nucleus; Neutron deficient; Proton deficient; Radioactive nuclei; Unstable nuclei
  • Americium-241 container in a smoke detector.
  • Americium-241 capsule as found in smoke detector. The circle of darker metal in the center is americium-241; the surrounding casing is aluminium.
  • [[Artificial]] [[nuclide]] [[americium-241]] emitting [[alpha particle]]s inserted into a [[cloud chamber]] for visualisation

radioactive isotopes         
ραδιομετάδοση
radioactive waste         
  • U-233]] for three fuel types. In the case of MOX, the U-233 increases for the first 650 thousand years as it is produced by the decay of [[Np-237]] which was created in the reactor by absorption of neutrons by U-235.
  • Total activity for three fuel types. In region 1, there is radiation from short-lived nuclides, in region 2, from [[Sr-90]] and [[Cs-137]], and on the far right, the decay of Np-237 and U-233.
  • Removal of very low-level waste
  • nuclear waste disposal centre]] at [[Gorleben]] in northern Germany
  • Diagram of an underground low-level radioactive waste disposal site
  • Modern medium to high-level transport container for nuclear waste
  • abbr=on}} thick solid steel and weighs in excess of 50 t
  • The current locations across the United States where nuclear waste is stored
  • access-date=2020-11-13}}</ref> near the [[Olkiluoto Nuclear Power Plant]] in [[Eurajoki]], on the west coast of [[Finland]]. Picture of a pilot cave at final depth in Onkalo.
  • The Waste Vitrification Plant at [[Sellafield]]
  • archive-date=February 5, 2007}}</ref>
  • date=2016-07-11 }}, ''Nature'', 13 January 2016.</ref>
WASTE THAT CONTAINS RADIOACTIVE MATERIAL AND THUS EMITS IONIZING RADIATION
Atomic waste; Nuclear waste; Radioactive Waste; NUCLEAR POLLUTION; Radioactive pollution; Radioactive waste treatment; Radwaste; Nuclear Waste; Nuclear dumping; Radioactive pollutants; Radioactive gases; Nuclear waste disposal; Nuclear residue; Chemistry of radioactive waste; Waste, radioactive; Nuclear waste dump; Nuclear waste storage; Radioactive dump; Nuclear waste management; Classifications of nuclear waste; Classification of radioactive waste; Classification of nuclear waste; Low and intermediate level waste; Intermediate-level waste; Low and intermediate-level waste; Intermediate-level nuclear waste; Radioactive wastes; Reuse of radioactive waste; Illegal dumping of radioactive waste
πυρηνικά απόβλητα
nuclear waste         
  • U-233]] for three fuel types. In the case of MOX, the U-233 increases for the first 650 thousand years as it is produced by the decay of [[Np-237]] which was created in the reactor by absorption of neutrons by U-235.
  • Total activity for three fuel types. In region 1, there is radiation from short-lived nuclides, in region 2, from [[Sr-90]] and [[Cs-137]], and on the far right, the decay of Np-237 and U-233.
  • Removal of very low-level waste
  • nuclear waste disposal centre]] at [[Gorleben]] in northern Germany
  • Diagram of an underground low-level radioactive waste disposal site
  • Modern medium to high-level transport container for nuclear waste
  • abbr=on}} thick solid steel and weighs in excess of 50 t
  • The current locations across the United States where nuclear waste is stored
  • access-date=2020-11-13}}</ref> near the [[Olkiluoto Nuclear Power Plant]] in [[Eurajoki]], on the west coast of [[Finland]]. Picture of a pilot cave at final depth in Onkalo.
  • The Waste Vitrification Plant at [[Sellafield]]
  • archive-date=February 5, 2007}}</ref>
  • date=2016-07-11 }}, ''Nature'', 13 January 2016.</ref>
WASTE THAT CONTAINS RADIOACTIVE MATERIAL AND THUS EMITS IONIZING RADIATION
Atomic waste; Nuclear waste; Radioactive Waste; NUCLEAR POLLUTION; Radioactive pollution; Radioactive waste treatment; Radwaste; Nuclear Waste; Nuclear dumping; Radioactive pollutants; Radioactive gases; Nuclear waste disposal; Nuclear residue; Chemistry of radioactive waste; Waste, radioactive; Nuclear waste dump; Nuclear waste storage; Radioactive dump; Nuclear waste management; Classifications of nuclear waste; Classification of radioactive waste; Classification of nuclear waste; Low and intermediate level waste; Intermediate-level waste; Low and intermediate-level waste; Intermediate-level nuclear waste; Radioactive wastes; Reuse of radioactive waste; Illegal dumping of radioactive waste
πυρηνικά απόβλητα

Definizione

radioisotope
¦ noun Chemistry a radioactive isotope.
Derivatives
radioisotopic adjective

Wikipedia

Radionuclide

A radionuclide (radioactive nuclide, radioisotope or radioactive isotope) is a nuclide that has excess nuclear energy, making it unstable. This excess energy can be used in one of three ways: emitted from the nucleus as gamma radiation; transferred to one of its electrons to release it as a conversion electron; or used to create and emit a new particle (alpha particle or beta particle) from the nucleus. During those processes, the radionuclide is said to undergo radioactive decay. These emissions are considered ionizing radiation because they are energetic enough to liberate an electron from another atom. The radioactive decay can produce a stable nuclide or will sometimes produce a new unstable radionuclide which may undergo further decay. Radioactive decay is a random process at the level of single atoms: it is impossible to predict when one particular atom will decay. However, for a collection of atoms of a single nuclide the decay rate, and thus the half-life (t1/2) for that collection, can be calculated from their measured decay constants. The range of the half-lives of radioactive atoms has no known limits and spans a time range of over 55 orders of magnitude.

Radionuclides occur naturally or are artificially produced in nuclear reactors, cyclotrons, particle accelerators or radionuclide generators. There are about 730 radionuclides with half-lives longer than 60 minutes (see list of nuclides). Thirty-two of those are primordial radionuclides that were created before the earth was formed. At least another 60 radionuclides are detectable in nature, either as daughters of primordial radionuclides or as radionuclides produced through natural production on Earth by cosmic radiation. More than 2400 radionuclides have half-lives less than 60 minutes. Most of those are only produced artificially, and have very short half-lives. For comparison, there are about 251 stable nuclides. (In theory, only 146 of them are stable, and the other 105 are believed to decay via alpha decay, beta decay, double beta decay, electron capture, or double electron capture.)

All chemical elements can exist as radionuclides. Even the lightest element, hydrogen, has a well-known radionuclide, tritium. Elements heavier than lead, and the elements technetium and promethium, exist only as radionuclides. (In theory, elements heavier than dysprosium exist only as radionuclides, but some such elements, like gold and platinum, are observationally stable and their half-lives have not been determined).

Unplanned exposure to radionuclides generally has a harmful effect on living organisms including humans, although low levels of exposure occur naturally without harm. The degree of harm will depend on the nature and extent of the radiation produced, the amount and nature of exposure (close contact, inhalation or ingestion), and the biochemical properties of the element; with increased risk of cancer the most usual consequence. However, radionuclides with suitable properties are used in nuclear medicine for both diagnosis and treatment. An imaging tracer made with radionuclides is called a radioactive tracer. A pharmaceutical drug made with radionuclides is called a radiopharmaceutical.

Esempi dal corpus di testo per radioactive isotopes
1. Iran says it wants Arak to produce radioactive isotopes for diagnosing and treating cancer.
2. The devices contain such radioactive isotopes as cobalt–60, cesium–137 and strontium–'0 in encapsulated or sealed small amounts.
3. Medical use The diplomat said Saudi Arabia had only a cyclotron for making radioactive isotopes for medical use.
4. Iran denies such intentions, saying it needs the heavy water reactor to produce radioactive isotopes for medical and other peaceful purposes and enrichment to generate energy.
5. "It would be much more difficult to mimic the radioactive isotopes you get from a nuclear blast" than to conduct an actual nuclear test, said Charles D.