Dosimetry

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Radiation dosimetry is the calculation of absorbed dose in matter and tissue resulting from the exposure to ionizing radiations. It is a scientific subspecialty in the fields of health physics and medical physics that is focused on the calculation of internal and external doses from ionizing radiation.

Dose is reported in grays (Gy) for matter or sieverts (Sv) for biological tissue, where 1 Gy or Sv = 1 joule per kilogram. Non-SI units are still prevalent as well, where dose is often reported in rads and dose equivalent in rems. By definition, 1 Gy = 100 rad and 1 Sv = 100 rem.

The distinction between absorbed dose (Gy) and dose equivalent (Sv) is based upon the biological effects of the radiation in question. For different types of radiation, the same absorbed dose (measured in Gy) may have very different biological consequences. Therefore, a radiation weighting factor (denoted w_{r_{) has been established, which compares the relative biological effects of various types of radiation. By definition, x-rays and gamma rays are unity, such that 1 Gy = 1 Sv. Values of w_{r _{are as high as 20 for alpha particles, i.e. for the same absorbed dose, alpha particles are 20 times as biologically potent as x or gamma rays. Dose equivalent is further explored with tissue weighting factors (w _{t_{), which account for sensitivities of various organs exposed to a given dose of radiation; after all, not all organs are equally radiosensitive.}}}}}}

_{Radiation dose refers to the amount of energy deposited in matter and/or biological effects of radiation, and should not be confused with the unit of radioactive activity (becquerel, Bq). Doses can be measured in places other than where the radioactive decay occurred.}

_{The worldwide average background dose for a human being is about 3.5 mSv per year [1], mostly from cosmic radiation and natural isotopes in the earth. The largest single source of radiation exposure to the general public is naturally-occurring radon gas, which comprises approximately 55% of the annual background dose. It is estimated that radon is responsible for 10% of lung cancers in the United States. There are several ways of measuring doses from ionizing radiation. Workers who come in contact with radioactive substances or may be exposed to radiation routinely carry personal dosimeters. In the United States, these dosimeters usually contain materials that can be used in thermoluminescent dosimetry (TLD) or optically stimulated luminescence (OSL). Outside the United States, the most widely-used type of personal dosimeter is the film badge dosimeter, which uses photographic emulsions that are sensitive to ionizing radiation. The equipment used in radiotherapy (linear particle accelerator in external beam therapy) is routinely calibrated using ionization chambers.}