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Biological Effects of Radiation02:59

Biological Effects of Radiation

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All radioactive nuclides emit high-energy particles or electromagnetic waves. When this radiation encounters living cells, it can cause heating, break chemical bonds, or ionize molecules. The most serious biological damage results when these radioactive emissions fragment or ionize molecules. For example, α and β particles emitted from nuclear decay reactions possess much higher energies than ordinary chemical bond energies. When these particles strike and penetrate matter, they...
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Radiation Pressure: Problem Solving01:09

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The radiation pressure applied by an electromagnetic wave on a perfectly absorbing surface equals the energy density of the wave. The wave's momentum also gets transferred to the surface when an electromagnetic wave is entirely absorbed by it. The rate at which momentum is transmitted to an absorbing surface perpendicular to the propagation direction equals the force on the surface.
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Radiation: Applications01:17

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The average temperature of Earth is the subject of much current discussion. Earth is in radiative contact with both the Sun and dark space; it receives almost all its energy from the radiation of the Sun and reflects some of it into outer space. Dark space is very cold, about 3 K, so Earth radiates energy into it. For instance, heat transfer occurs from soil and grasses, the rate of which can be so rapid that frost can occur on clear summer evenings, even in warm latitudes.
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Isotopes and Radioisotopes01:28

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In the early 1900s, English chemist Frederick Soddy realized that an element could have atoms with different masses that were chemically indistinguishable. These different types are called isotopes — atoms of the same element that differ in mass. Isotopes differ in mass because they have different numbers of neutrons but are chemically identical because they have the same number of protons. Soddy was awarded the Nobel Prize in Chemistry in 1921 for this discovery.
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Dual Nature of Electromagnetic (EM) Radiation01:10

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Electromagnetic (EM) radiation consists of electric and magnetic field components oscillating in planes perpendicular to each other and mutually perpendicular to radiation propagation through space. EM radiation can be classified as a wave, characterized by the properties of waves such as wavelength (denoted as λ) and frequency (represented by ν).
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Nuclear Power02:36

Nuclear Power

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Controlled nuclear fission reactions are used to generate electricity. Any nuclear reactor that produces power via the fission of uranium or plutonium by bombardment with neutrons has six components: nuclear fuel consisting of fissionable material, a nuclear moderator, a neutron source, control rods, reactor coolant, and a shield and containment system.
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Updated: Nov 16, 2025

Establishment of a Robust and Reproducible Model of Radiation-Induced Skin and Muscle Fibrosis
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Embracing Mystery: Radiation Risks and Popular Science Writing in the Early Cold War.

David K Hecht1

  • 1Bowdoin College, Brunswick, USA. dhecht@bowdoin.edu.

Journal of the History of Biology
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PubMed
Summary
This summary is machine-generated.

Popular science communication uses narrative to explain complex topics like radiation. Examining Cold War texts reveals how literary genres shaped public understanding of radiation risks, sometimes limiting radical messages.

Keywords:
NarrativeNuclearPopular cultureRadiationRisk

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Area of Science:

  • Science communication
  • Public understanding of science
  • Radiation risks

Background:

  • Understanding complex scientific topics like radiation is challenging for the public.
  • Radiation risks were a significant concern during the Cold War.
  • Popular culture plays a key role in disseminating scientific information.

Purpose of the Study:

  • To examine narrative strategies in popular texts about radiation risks.
  • To analyze how literary genres influenced the communication of scientific information.
  • To understand the impact of narrative choices on public perception of radiation during the Cold War.

Main Methods:

  • Content analysis of three prominent Cold War texts on radiation: Hiroshima, No Place to Hide, and The Voyage of the Lucky Dragon.
  • Examination of narrative choices and genre conventions employed by the authors.
  • Assessment of how these choices affected the coherence and impact of the messages.

Main Results:

  • Authors utilized established literary genres to present information on radiation.
  • Genre borrowing enhanced the coherence and effectiveness of scientific messaging.
  • Familiar narrative forms may have reduced the radical implications of the scientific information presented.

Conclusions:

  • Narrative form is essential for public understanding of complex scientific subjects like radiation.
  • The use of literary genres in popular science writing can effectively convey information but may also moderate its impact.
  • Analyzing narrative strategies provides insight into the historical reception of scientific risks.