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Nuclear Power02:36

Nuclear Power

8.3K
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.
Nuclear Fuels
Nuclear fuel consists of a fissile isotope, such as uranium-235, which must be present in sufficient quantity to provide a...
8.3K
Nuclear Fusion02:45

Nuclear Fusion

31.6K
The process of converting very light nuclei into heavier nuclei is also accompanied by the conversion of mass into large amounts of energy, a process called fusion. The principal source of energy in the sun is a net fusion reaction in which four hydrogen nuclei fuse and ultimately produce one helium nucleus and two positrons.
A helium nucleus has a mass that is 0.7% less than that of four hydrogen nuclei; this lost mass is converted into energy during the fusion. This reaction produces about...
31.6K
Nuclear Transmutation03:20

Nuclear Transmutation

18.4K
Nuclear transmutation is the conversion of one nuclide into another. It can occur by the radioactive decay of a nucleus, or the reaction of a nucleus with another particle. The first manmade nucleus was produced in Ernest Rutherford’s laboratory in 1919 by a transmutation reaction, the bombardment of one type of nuclei with other nuclei or with neutrons. Rutherford bombarded nitrogen-14 atoms with high-speed α particles from a natural radioactive isotope of radium and observed...
18.4K
Nuclear Fission02:50

Nuclear Fission

10.5K
Many heavier elements with smaller binding energies per nucleon can decompose into more stable elements that have intermediate mass numbers and larger binding energies per nucleon—that is, mass numbers and binding energies per nucleon that are closer to the “peak” of the binding energy graph near 56. Sometimes neutrons are also produced. This decomposition of a large nucleus into smaller pieces is called fission. The breaking is rather random with the formation of a large...
10.5K
Nuclear Stability03:18

Nuclear Stability

20.3K
Protons and neutrons, collectively called nucleons, are packed together tightly in a nucleus. With a radius of about 10−15 meters, a nucleus is quite small compared to the radius of the entire atom, which is about 10−10 meters. Nuclei are extremely dense compared to bulk matter, averaging 1.8 × 1014 grams per cubic centimeter. If the earth’s density were equal to the average nuclear density, the earth’s radius would be only about 200 meters.
To hold positively charged protons together...
20.3K
Nuclear Export01:42

Nuclear Export

3.8K
The nucleus restricts several proteins within and allows others to pass. The restricted proteins possess a nuclear retention sequence or NRS, anchoring them to the nuclear lamins and preventing their transport to the cytosol. The non-restricted proteins, after their synthesis, are transported to their site of action, such as the cytosol or other organelles, with the help of nuclear export signals or NES.
NES are of three types- the canonical 10-residue long leucine-rich signal and other...
3.8K

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Related Experiment Video

Updated: Sep 21, 2025

Laser-heating and Radiance Spectrometry for the Study of Nuclear Materials in Conditions Simulating a Nuclear Power Plant Accident
09:18

Laser-heating and Radiance Spectrometry for the Study of Nuclear Materials in Conditions Simulating a Nuclear Power Plant Accident

Published on: December 14, 2017

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Nuclear waste from small modular reactors.

Lindsay M Krall1, Allison M Macfarlane2, Rodney C Ewing1

  • 1Center for International Security and Cooperation, Stanford University, Stanford, CA 94305.

Proceedings of the National Academy of Sciences of the United States of America
|May 31, 2022
PubMed
Summary
This summary is machine-generated.

Small modular reactors (SMRs) may generate more waste than traditional reactors. This nuclear waste is more voluminous and reactive, posing challenges for future management and disposal.

Keywords:
energynuclearnuclear wastesmall modular reactorswaste

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Laser-heating and Radiance Spectrometry for the Study of Nuclear Materials in Conditions Simulating a Nuclear Power Plant Accident
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Area of Science:

  • Nuclear Engineering
  • Materials Science
  • Environmental Science

Background:

  • Small modular reactors (SMRs) are proposed as a next-generation nuclear energy solution, often cited for potential cost and safety benefits over gigawatt-scale light water reactors (LWRs).
  • The back end of the nuclear fuel cycle, encompassing waste management and disposal, is a critical consideration for the long-term viability of any nuclear technology.
  • Limited research has comprehensively evaluated the waste stream characteristics and disposal implications specific to SMR designs.

Purpose of the Study:

  • To characterize the low-, intermediate-, and high-level waste streams produced by selected Small Modular Reactor designs.
  • To compare the waste characteristics of SMRs against those of existing Light Water Reactors (LWRs).
  • To assess the implications of SMR waste properties for future waste management and disposal strategies.

Main Methods:

  • Analysis of waste stream composition (low-, intermediate-, and high-level) for three distinct SMR designs.
  • Comparative assessment of waste volume and chemical/physical reactivity between SMRs and LWRs.
  • Evaluation of neutron leakage characteristics inherent to SMR designs and their impact on radionuclide generation.

Main Results:

  • Small modular reactors are projected to produce more voluminous waste streams compared to traditional LWRs.
  • The waste generated by SMRs exhibits increased chemical and physical reactivity, complicating management and disposal.
  • Higher neutron leakage in typical SMR designs can lead to less favorable conditions for managing key radionuclides in nuclear waste.

Conclusions:

  • SMRs present distinct waste management challenges due to increased waste volume and reactivity.
  • The inherent design of most SMRs, characterized by higher neutron leakage, may be less advantageous than LWRs for the long-term disposal of nuclear waste.
  • Further research and development are necessary to address the unique back-end fuel cycle implications of SMR deployment.