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Gamma rays, X-rays, and the higher energy ultraviolet part of the electromagnetic spectrum are ionizing radiation, whereas the lower energy ultraviolet, visible light, nearly all types of laser light, infrared, microwaves, and radio waves are non-ionizing radiation.
Ionizing radiation. Some types of radiation have enough energy that they can knock electrons out of their orbits around atoms, upsetting the electron/proton balance and giving the atom a positive charge.
- Overview
- Sources and types of ionizing radiation
ionizing radiation, flow of energy in the form of atomic and subatomic particles or electromagnetic waves that is capable of freeing electrons from an atom, causing the atom to become charged (or ionized). Ionizing radiation includes the more energetic end of the electromagnetic spectrum (X-rays and gamma rays) and subatomic particles, such as electrons, neutrons, and alpha particles (helium nuclei each comprising two protons and two neutrons).
Through the displacement of electrons (ionization), ionizing radiation effectively disrupts molecular bonds. In living organisms, such disruption can cause extensive damage to cells and their genetic material. A characteristic type of DNA damage produced by ionizing radiation, even by a single radiation track through a cell, involves closely spaced, multiple lesions that compromise cellular DNA repair mechanisms. Although most of the cells sustaining such radiation-induced damage may be eliminated by damage response pathways, some cells are capable of escaping these pathways, propagating, and eventually undergoing malignant transformation, a crucial step in cancer development.
Ionizing radiation is an established risk factor for cancer. Studies involving the irradiation of cells and experimental animals and epidemiological studies of populations that have experienced unusually high levels of radiation exposure for medical or occupational reasons have demonstrated clear links between ionizing radiation and cancer. Examples of the latter include the 1986 Chernobyl disaster and the 1945 atomic bombings of Hiroshima and Nagasaki, Japan. In the years following those catastrophic events, thousands of people suffered radiation-induced illness and cancer.
Cancer risk is increased roughly in proportion to the amount of energy deposited in tissue (radiation dose, usually quantified in units of gray [Gy] or milligray [mGy], where 1 Gy corresponds to 1 joule of energy per kilogram of tissue). However, organs and tissues differ in their sensitivity to radiation carcinogenesis (cancer-causing ability). Cancer risk further varies by type of ionizing radiation, by gender, by age at exposure, by age and time following exposure, and by lifestyle factors, such as reproductive history and exposure to other carcinogens (e.g., tobacco smoke). On average, the bulk of radiation dose to individuals comes from natural background sources that have changed little over the span of human existence.
Ionizing radiation is produced by the radioactive decay of unstable isotopes of elements in rocks, soil, and body tissues and by nuclear reactions occurring in the Sun and distant stars. A major part of all exposure to such background radiation exposure is attributable to the inhalation of radon gas, which is produced by the radioactive decay of radium in rocks and soil and that, as it seeps out into the atmosphere, can become trapped and concentrated in poorly ventilated environments such as dwellings and underground mines. Radiation from radon and its radioactive decay products consists of mainly alpha particles, which have very limited ability to penetrate tissue but can damage cellular DNA in the lung if the radioactive source is inhaled and deposited in the airways. Gamma rays and X-rays, in contrast, are highly penetrating and can affect cells even when the radiation source is outside the body. Although electrons are only somewhat more penetrating than alpha particles, the immediate cause of most radiation-related damage to DNA is thought to stem from interactions with secondary electrons energized by transfer from electromagnetic or particle radiation originating outside the cell.
Different types of radiation differ somewhat in biological effectiveness per unit of dose. For example, alpha particle radiation absorbed in tissue is considered to be about 20 times more effective as a carcinogen than the same dose of gamma rays. The concept of equivalent dose, expressed in units of Sievert (Sv), was introduced for purposes of radiation protection. For gamma radiation, 1 mGy dose corresponds to 1 mSv dose equivalent, whereas for alpha radiation, 1 mGy dose corresponds to 20 mSv dose equivalent. Worldwide, the average annual human exposure to natural background radiation is 2.4 mSv per year.
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Following the discovery of X-rays in 1895 by German physicist Wilhelm Conrad Röntgen and of radioactivity the following year by French physicist Henri Becquerel, medical, industrial, and military uses of radiation technology were developed that eventually led to a marked increase in human population exposure to ionizing radiation. By the early 21st century in the United States, such human-made radiation contributed about 18 percent of the total annual radiation exposure to the human population. However, radiation doses to individuals can vary widely.
As reference points, unusually high doses of ionizing radiation include dose equivalents in excess of 100 mSv. Whole-body exposures in excess of 4 Sv (4,000 mSv) are usually fatal in the absence of medical intervention, whereas much higher doses, limited to single organs or restricted parts of the body, are often used safely for treatment of cancer.
Feb 19, 2024 · Ionizing radiation is a powerful form of energy with medical applications such as diagnostic testing. At high enough doses, it can alter your body's cells and DNA. Unlike some non-ionizing radiation, it can cause serious harm or cancer with enough exposure.
May 18, 2017 · Ionizing radiation gives off energy by knocking electrons off atoms, which causes the atoms to have a charge. Another term for a charged particle is an ion. The charges on the atomic particles make ionizing radiation unstable and reactive.
Apr 14, 2021 · Ionizing radiation includes subatomic particles and the high energy, short-wavelength portion of the electromagnetic spectrum. Non-ionizing radiation include the visible spectrum and the low energy, long-wavelength part of the spectrum beyond visible light.
Mar 19, 2020 · In earlier Science 101s, we talked about what makes up atoms, chemicals, matter and ionizing radiation. Now, let's look at the different kinds of radiation. There are four major types of radiation: alpha, beta, neutrons, and electromagnetic waves such as gamma rays.
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