Neutron in a sentence

(1) The neutron is a subatomic particle.

(2) The biloculate neutron had no charge.

(3) Americiums are used in neutron sources.

(4) Deuterium has one proton and one neutron.

(5) Neutron radiation can cause damage to DNA.

(6) Neutron radiation is invisible and odorless.

(7) Betatrons are used to produce neutron beams.

(8) Neutrinos are not affected by neutron stars.

(9) The neutron bomb is a type of nuclear weapon.

(10) The radius of the neutron is 0.8 femtometers.

Neutron sentence

(11) The neutron is slightly heavier than a proton.

(12) Neutron radiation can cause mutations in cells.

(13) The neutron bomb has never been used in combat.

(14) The energy of a neutron can be measured in MeV.

(15) The proton and neutron are examples of baryons.

(16) Thorium has a low neutron capture cross-section.

(17) The radioelement is used in neutron radiography.

(18) The coronas of neutron stars are extremely dense.

(19) The anti particle of a neutron is an antineutron.

(20) A neutron is a tiny particle that makes up atoms.

Neutron make sentence

(21) Neutron radiation is a type of ionizing radiation.

(22) A neutron star is a highly dense celestial object.

(23) Neutron stars are remnants of supernova explosions.

(24) Beryllias is sometimes used as a neutron moderator.

(25) The antiparticle of the neutron is the antineutron.

(26) The antineutron is the antiparticle of the neutron.

(27) The anti-particle of the neutron is the antineutron.

(28) Neutron radiation is often used in cancer treatment.

(29) Neutron radiation is a concern in nuclear accidents.

(30) The occurrence of a neutron star can be fascinating.

Sentence of neutron

(31) The neutron was discovered by James Chadwick in 1932.

(32) A deuteron is composed of one proton and one neutron.

(33) A neutron is a subatomic particle that has no charge.

(34) Neutron radiation is commonly used in medical imaging.

(35) Fast neutrons are used in neutron activation analysis.

(36) Fast neutron sources are used for scientific research.

(37) The weight of the neutron star was measured in pounds.

(38) Neutron radiation is produced during nuclear reactions.

(39) Neutron radiation can be harmful to electronic devices.

(40) Neutron radiation can be generated by nuclear reactors.

Neutron meaningful sentence

(41) Neutron stars are often referred to as stellar corpses.

(42) The gyromagnetic ratio of a neutron is approximately 0.

(43) Neutron radiation is commonly used in cancer treatment.

(44) The antiparticle of a neutron is called an antineutron.

(45) Americium is used in the production of neutron sources.

(46) Hyperons play a role in the formation of neutron stars.

(47) Neutron radiation can be harmful to astronauts in space.

(48) Astrophysically calculate the density of a neutron star.

(49) Americium is used in the detection of neutron radiation.

(50) Deuterium has one proton and one neutron in its nucleus.

Neutron sentence examples

(51) The mass of the neutron is about the same as the proton.

(52) Erbium is used in nuclear reactors as a neutron absorber.

(53) Borons are used in nuclear reactors as neutron absorbers.

(54) Fast neutron detectors are used for radiation monitoring.

(55) Neutron capture can result in the emission of gamma rays.

(56) Deuterium is used in the production of neutron detectors.

(57) Neutron capture can lead to the transmutation of elements.

(58) Neutron radiation can be used to detect hidden explosives.

(59) Neutron stars can have a mass up to twice that of our Sun.

(60) The fast neutron flux in the core is carefully controlled.

Sentence with neutron

(61) Neutron radiation can be used to induce nuclear reactions.

(62) Beta decay occurs when a neutron transforms into a proton.

(63) Beryllias is used in the production of neutron moderators.

(64) Deuterium is used in the production of neutron generators.

(65) Neutron capture can lead to the release of gamma radiation.

(66) Neutron radiation can be measured in units called sieverts.

(67) Neutron stars can have a diameter of only a few kilometers.

(68) The gravities of neutron stars are also extremely powerful.

(69) The deuteron is formed when a proton and a neutron combine.

(70) Neutron radiation can cause structural damage to buildings.

Use neutron in a sentence

(71) The antineutron is the antiparticle of the neutral neutron.

(72) Europium is used in nuclear reactors as a neutron absorber.

(73) Neutron stars are formed from the remnants of massive stars.

(74) The neutron bomb is classified as a tactical nuclear weapon.

(75) The neutron bomb is considered a weapon of mass destruction.

(76) Fast neutron flux is a critical parameter in reactor design.

(77) James Chadwick is known as the co-discoverer of the neutron.

(78) Neutron capture is a fundamental process in nuclear physics.

(79) The radius of the neutron determines its mass and stability.

(80) Neutron radiation can be used to sterilize medical equipment.

Sentence using neutron

(81) Neutron radiation can be used to study the behavior of atoms.

(82) Polonium can be used as a neutron source in nuclear reactors.

(83) The temperature inside a neutron star is astronomically high.

(84) Fast neutron dosimetry is important for radiation protection.

(85) The production of fast neutrons requires a high neutron flux.

(86) Neutron capture can occur in materials exposed to cosmic rays.

(87) Neutron radiation can be detected using specialized equipment.

(88) The gravitational pull of a neutron star is incredibly strong.

(89) Protoactinium is used in nuclear reactors as a neutron source.

(90) Actiniums are used in neutron sources for scientific research.

Neutron example sentence

(91) Holmium is used in nuclear reactors and as a neutron absorber.

(92) The mass of the proton and neutron are approximately the same.

(93) Neutron radiation can be used to treat certain types of tumors.

(94) Neutron capture cross-sections are typically measured in barns.

(95) Neutron capture can occur in both fission and fusion reactions.

(96) Neutron radiation is produced during nuclear fission reactions.

(97) Hyperons play a crucial role in the formation of neutron stars.

(98) Fast neutrons are used in neutron therapy for cancer treatment.

(99) Neutrinos can be used to study the properties of neutron stars.

(100) Erbium is often used in nuclear reactors as a neutron absorber.

Sentence with word neutron

(101) The gravitational field of a neutron star is incredibly intense.

(102) The deuteron is heavier than a proton or a neutron individually.

(103) Supernovas can produce neutron stars or black holes as remnants.

(104) Fast neutron radiography can detect hidden defects in materials.

(105) James Chadwick is recognized as the codiscoverer of the neutron.

(106) Fast neutron radiography is a non-destructive testing technique.

(107) Neutron radiation can be detected using specialized instruments.

(108) INAA is an acronym for instrumental neutron activation analysis.

(109) Samarium is also used in nuclear reactors as a neutron absorber.

(110) Neutron capture can alter the isotopic composition of a material.

Sentence of neutron

(111) Neutron stars are among the most extreme objects in the universe.

(112) Deuteride can be used as a neutron moderator in nuclear reactors.

(113) Fast neutron reactions are commonly used in nuclear power plants.

(114) Fast neutron therapy is a type of radiation treatment for cancer.

(115) Fast neutron-induced fission is a key process in nuclear weapons.

(116) James Chadwick is recognized as the co-discoverer of the neutron.

(117) The energy of neutron radiation can vary depending on the source.

(118) Neutron radiation can be used to create images of the human body.

(119) The pion's mass is much lighter than that of a proton or neutron.

(120) Neutron capture is a key step in the production of plutonium-239.

Neutron used in a sentence

(121) Beryllium is also used in nuclear reactors as a neutron reflector.

(122) Neutron capture can occur in stars during stellar nucleosynthesis.

(123) Neutron radiation can be used to study the structure of materials.

(124) Neutron radiation can be used to analyze archaeological artifacts.

(125) The actinides have been used in the production of neutron sources.

(126) Astrophysicists study the properties of pulsars and neutron stars.

(127) Neutron radiation is commonly encountered in nuclear power plants.

(128) Neutron capture can occur in both stable and radioactive isotopes.

(129) Neutron capture can lead to the formation of fissionable isotopes.

(130) Gadolinium is also used in nuclear reactors as a neutron absorber.

Neutron sentence in English

(131) Neutrons can be slowed down to create a neutron beam for research.

(132) Tritium can be produced through the neutron bombardment of lithium.

(133) The method of INAA is based on the principle of neutron activation.

(134) Neutron capture can result in the creation of radioactive isotopes.

(135) Neutron capture can occur in materials exposed to a neutron source.

(136) Neutron capture can be a source of neutron activation in materials.

(137) Neutron capture can lead to the production of fissionable isotopes.

(138) Deuterons are particles that consist of one proton and one neutron.

(139) Neutron capture is an important mechanism in nuclear power reactors.

(140) Neutron capture can be used to study the structure of atomic nuclei.

(141) Neutron capture can occur in materials used for radiation shielding.

(142) The effects of neutron radiation can be harmful to living organisms.

(143) Neutron radiation can be used to detect defects in metal structures.

(144) The appulses of neutron stars can generate powerful magnetic fields.

(145) The perigees of neutron stars can result in intense magnetic fields.

(146) Fast neutron activation analysis is a powerful analytical technique.

(147) Neutron capture can result in the formation of radioactive isotopes.

(148) Neutron capture can lead to the production of neutron-rich isotopes.

(149) Neutron capture can occur in both stable and unstable atomic nuclei.

(150) Neutron radiation can be used to measure the thickness of materials.

(151) Neutron radiation can be used to detect defects in metal components.

(152) The energy of a neutron in a nuclear reactor is typically a few MeV.

(153) Tritium is produced in nuclear reactors through neutron bombardment.

(154) Fast neutrons are used in neutron imaging for imaging dense objects.

(155) The neutron detector measures backscatters from the nuclear reactor.

(156) The mass of the electron is much smaller than the proton or neutron.

(157) Neutron capture can result in the formation of neutron-rich isotopes.

(158) Neutron capture can be used to measure the neutron flux in a reactor.

(159) Neutron radiation can be used to create new elements in a laboratory.

(160) The study of neutron stars helps us understand the limits of physics.

(161) The deuteron is a stable particle composed of a proton and a neutron.

(162) Heavy hydrogen is a stable isotope of hydrogen with an extra neutron.

(163) Neutron capture can occur spontaneously or through induced reactions.

(164) Neutron capture can be used to study the properties of exotic nuclei.

(165) The flux of fast neutrons can be controlled using neutron moderators.

(166) The neutron detector measures backscatters from the nuclear material.

(167) Neutron capture can occur in both natural and artificial environments.

(168) Neutrons can be used to irradiate cancerous tumors in neutron therapy.

(169) Neutron radiation can be emitted during nuclear power plant accidents.

(170) Neutron radiation can be used to determine the age of certain objects.

(171) Neutron stars are believed to be the source of short gamma-ray bursts.

(172) The intense gravity of a neutron star can cause time dilation effects.

(173) Hadronic interactions are important in the formation of neutron stars.

(174) Fast neutron scattering is an important phenomenon in nuclear physics.

(175) The discovery of the neutron was a major advancement in atomic theory.

(176) Neutron capture is a key process in the production of medical isotopes.

(177) Neutron capture can be a source of energy release in nuclear reactions.

(178) The borated solution is used as a neutron absorber in nuclear reactors.

(179) The neutron bomb was first developed by the United States in the 1950s.

(180) The neutron capture process can release a significant amount of energy.

(181) Neptunium-237 can be used as a neutron source in research and industry.

(182) The vibrations of a neutron star could rattle up and down the universe.

(183) The reactor's neutron flux is carefully controlled for stable operation.

(184) The surface temperature of a neutron star can reach millions of degrees.

(185) The collapse of a massive star leads to the formation of a neutron star.

(186) The collapse of a collapsar can lead to the formation of a neutron star.

(187) The ultradense neutron star had an incredibly strong gravitational pull.

(188) Fast neutron capture can lead to the production of radioactive isotopes.

(189) Fast neutron-induced fission reactions release a large amount of energy.

(190) The fast neutron spectrum is important for certain nuclear applications.

(191) Neutron capture can alter the stability and properties of atomic nuclei.

(192) The deuterated material was used in the production of neutron detectors.

(193) The backscatter of neutron radiation can be used in scientific research.

(194) The pulsar's discovery revolutionized our understanding of neutron stars.

(195) Deuterons can be used to generate neutron beams for various applications.

(196) The energy of a neutron in a nuclear reaction can be in the order of MeV.

(197) The flux of fast neutrons can be increased by using a neutron multiplier.

(198) Neutron capture is a phenomenon that occurs in various nuclear processes.

(199) Neutron capture can cause changes in the physical properties of materials.

(200) The strong magnetic fields of neutron stars can distort nearby space-time.

(201) The neutron bomb is sometimes referred to as an enhanced radiation weapon.

(202) Fast neutron detectors are used to measure the intensity of neutron beams.

(203) Fast neutron activation analysis is a technique used in materials science.

(204) The collapse of a collapsar can result in the formation of a neutron star.

(205) The fuel assembly is carefully positioned to achieve optimal neutron flux.

(206) The high mass of the neutron star results in extreme gravitational forces.

(207) Neutron capture is a key process in the nucleosynthesis of heavy elements.

(208) The collimated neutron source was used for neutron scattering experiments.

(209) Fast neutrons are used in neutron radiography for non-destructive testing.

(210) Neutron capture is a process that occurs in the core of a nuclear reactor.

(211) The force of a stellar explosion can create black holes and neutron stars.

(212) The backscatter of neutrons can be used in neutron scattering experiments.

(213) The crystal's crystalline structure was studied using neutron diffraction.

(214) Neutrons are an important tool in the field of neutron activation analysis.

(215) The discovery of pulsars revolutionized our understanding of neutron stars.

(216) The collapse of a neutron star can result in the formation of a black hole.

(217) The neutron bomb is a weapon that has been stockpiled by several countries.

(218) The accretionary disk around a neutron star is where matter gets pulled in.

(219) Neutron capture reactions are important in understanding stellar evolution.

(220) The intensity of neutron radiation decreases with distance from the source.

(221) Neutron radiation can be used to detect the presence of illicit substances.

(222) The phenomenon of neutron capture plays a crucial role in nuclear reactors.

(223) Neutron capture can alter the stability and radioactive decay of a nucleus.

(224) The neutron detector measures backscatters from the material being scanned.

(225) The deuteride ion is larger than the hydrogen ion due to the extra neutron.

(226) The borated material was used as a neutron absorber in the nuclear reactor.

(227) The weak force is responsible for the conversion of a neutron into a proton.

(228) Neutrons are used in medical imaging techniques such as neutron radiography.

(229) Neutron radiation can be shielded using materials such as water or concrete.

(230) The neutron bomb is a weapon that has been banned by international treaties.

(231) Neutron capture can result in the transmutation of one element into another.

(232) The study of hyperons can help us understand the formation of neutron stars.

(233) Neutron capture is responsible for the formation of heavy isotopes in stars.

(234) Neutron capture is a process that occurs in the outer layers of a supernova.

(235) Absolute-zero is the temperature at which all matter becomes a neutron star.

(236) Deuterons can be used in cancer treatment techniques such as neutron therapy.

(237) The unpolarized neutron beam interacted differently with different materials.

(238) Magnetars are a type of neutron star with an extremely strong magnetic field.

(239) The neutron bomb is designed to be delivered by artillery or missile systems.

(240) The rate of neutron capture influences the neutron flux in a nuclear reactor.

(241) Neutron capture reactions are essential in the study of nuclear astrophysics.

(242) Hyperons can only exist in extreme conditions, such as inside a neutron star.

(243) Fast neutrons are used in neutron activation analysis for elemental analysis.

(244) Neutron capture reactions are important in the study of nuclear astrophysics.

(245) The spherical shape of a neutron star is due to its high density and gravity.

(246) Neutron radiation can be used to generate electricity in nuclear power plants.

(247) Neutron stars emit X-rays and gamma rays due to their intense magnetic fields.

(248) Fast neutron radiography is a non-destructive testing method used in industry.

(249) The backscatterings of the neutron beam revealed the structure of the crystal.

(250) The deuteron is a nucleus of an atom that contains one proton and one neutron.

(251) The diffractions of neutron beams are used in neutron diffraction experiments.

(252) The rate of neutron capture depends on the cross-section of the target nucleus.

(253) Neutron capture can be a limiting factor in the efficiency of nuclear reactors.

(254) Neutron radiation can penetrate materials that other types of radiation cannot.

(255) Neutron radiation can be used to create images of the inside of the human body.

(256) The intense gravity of a neutron star can cause matter to be pulled towards it.

(257) The stability of unnilquadium isotopes varies depending on their neutron count.

(258) Californium-252 is a strong neutron emitter and is used in neutron radiography.

(259) Polonium has been used in the past as a neutron source for scientific research.

(260) The laboratory uses a neutron source to irradiate samples for nuclear research.

(261) Fast neutron activation detectors are used to monitor neutron flux in reactors.

(262) Fast neutron radiobiology research aims to improve cancer treatment techniques.

(263) Neutron capture can lead to the formation of isotopes with odd neutron numbers.

(264) The atomic mass unit is approximately equal to the mass of a proton or neutron.

(265) When a neutron collides with an atom, it can cause the atom to become unstable.

(266) The acronym INAA is often used interchangeably with neutron activation analysis.

(267) Neutron capture can be a source of background radiation in certain environments.

(268) Deuterons can be used in medical imaging techniques such as neutron radiography.

(269) The study of neutron stars provides valuable insights into the nature of matter.

(270) The study of neutron stars is crucial for understanding the life cycle of stars.

(271) The deuteron is used in the production of neutron beams for scientific research.

(272) Californium is used in neutron moisture gauges to measure soil moisture content.

(273) The surface temperature of a neutron star can reach millions of degrees Celsius.

(274) Fast neutron radiography is a valuable tool for inspecting aerospace components.

(275) The Crab Nebula is powered by a rapidly rotating neutron star known as a pulsar.

(276) Neutron capture is an important mechanism in the transmutation of nuclear waste.

(277) The neutronic flux in the neutron beam was measured using specialized detectors.

(278) The allanitic content of the rock was determined by neutron activation analysis.

(279) The Pontecorvo limit is a theoretical upper bound on the mass of a neutron star.

(280) The process of beta decay involves the transformation of a neutron into a proton.

(281) The discovery of the neutron further expanded our understanding of atomic theory.

(282) Neutron radiation can be used to determine the composition of unknown substances.

(283) Neutron stars are incredibly small and have a mass comparable to that of our Sun.

(284) The fissioning of heavy elements can release a large amount of neutron radiation.

(285) Fast neutron-induced radioactivity poses challenges for nuclear waste management.

(286) Fast neutron dosimetry techniques are used to assess radiation risks for workers.

(287) Neutron capture plays a crucial role in the formation of heavy elements in stars.

(288) An antiferromagnet's magnetic structure can be studied using neutron diffraction.

(289) Curium has been used in the production of neutron sources for scientific research.

(290) The astronomer's research helped us better understand the nature of neutron stars.

(291) Deuterium is heavier than regular hydrogen due to the presence of an extra neutron.

(292) Neutron capture can result in the production of isotopes with medical applications.

(293) The neutron bomb is designed to release a large number of neutrons upon detonation.

(294) Fast neutron radiobiology studies the biological effects of fast neutron radiation.

(295) Fast neutron scattering experiments provide data for validating theoretical models.

(296) The maximum density of a neutron star is incredibly high due to its collapsed core.

(297) The process of neutron capture occurs when a free neutron is absorbed by a nucleus.

(298) If the mass of a neutron star were increased, its density would become even higher.

(299) The spallation process is commonly used in neutron sources for scientific research.

(300) The discovery of the first pulsar helped us understand the nature of neutron stars.

(301) The collimator is used to align the neutron beam in neutron scattering experiments.

(302) Neutron capture cross-sections vary depending on the energy of the incident neutron.

(303) The escape velocity of a neutron star is incredibly high due to its extreme density.

(304) The intense magnetic fields of neutron stars can cause powerful bursts of radiation.

(305) Fast neutron scattering experiments provide valuable insights into atomic structure.

(306) Fast neutron-induced damage can affect the structural integrity of nuclear reactors.

(307) Fast neutron scattering cross-sections are crucial for accurate reactor simulations.

(308) The neutron capture reaction occurs when a neutron is absorbed by an atomic nucleus.

(309) Neutron radiation can penetrate materials more deeply than other forms of radiation.

(310) Neutron capture cross-sections are measured experimentally using various techniques.

(311) The neutronic scattering of the neutron by the atomic nucleus was studied in detail.

(312) The unpolarized neutron beam was used to study the magnetic properties of materials.

(313) The study of black holes has led to new insights into the behavior of neutron stars.

(314) Neptunium has been used in the production of neutron sources for scientific research.

(315) Neutron capture can be used to study the behavior of neutrons in different materials.

(316) The discovery of neutron stars has opened up new avenues of research in astrophysics.

(317) Nonfissionable substances like boron are used in the production of neutron absorbers.

(318) The neutronic model accurately predicts the neutron flux distribution in the reactor.

(319) Heavy hydrogen can be used as a source of neutrons in neutron scattering experiments.

(320) The energy released during neutron capture can be harnessed for various applications.

(321) The probability of neutron capture depends on the energy and velocity of the neutron.

(322) The neutron bomb's deployment requires thorough planning to minimize unintended harm.

(323) Nonfissionable materials are often used as neutron absorbers in nuclear power plants.

(324) The experiments conducted by Ernest Rutherford confirmed the existence of the neutron.

(325) Pulsars can provide valuable information about the dynamics of neutron star interiors.

(326) The extreme conditions on a neutron star make it an inhospitable environment for life.

(327) The deuteron is used in the production of neutron sources for industrial applications.

(328) Fast neutron cross-section data is essential for accurate nuclear reactor simulations.

(329) Fast neutron activation analysis can determine the elemental composition of materials.

(330) Fast neutron transport codes are used to model neutron behavior in complex geometries.

(331) Neutron capture reactions are often accompanied by the emission of secondary particles.

(332) Neutron radiation can be used to study the properties of materials at the atomic level.

(333) Fast neutron radiobiology studies aim to understand the mechanisms of radiation damage.

(334) Neutron capture reactions are important in understanding the behavior of neutron stars.

(335) Neutrons can be used to study the behavior of glasses in neutron scattering experiments.

(336) The deuteron is used in the production of neutron-rich isotopes for scientific research.

(337) The neutron bomb emits a burst of radiation that is highly lethal to humans and animals.

(338) The periastron shift of a neutron star can provide insights into its internal structure.

(339) Fast neutron transport calculations are used to design shielding for nuclear facilities.

(340) The magnetic structure of an antiferromagnet can be visualized using neutron scattering.

(341) The collimated neutron beam allowed for accurate measurements in scientific experiments.

(342) The nucleonic density of the neutron star was estimated using astronomical observations.

(343) Californium is used in nuclear reactors and as a neutron source for scientific research.

(344) Neutrons can be used to study the behavior of polymers in neutron scattering experiments.

(345) Neutrons can be used to study the properties of alloys in neutron scattering experiments.

(346) The properties of bosonic systems can be probed using techniques like neutron scattering.

(347) The operation of a fast reactor involves precise control of neutron flux and temperature.

(348) Betelgeuse is a star that will eventually leave behind a remnant known as a neutron star.

(349) If hyperons are included in calculations, it can explain the properties of neutron stars.

(350) The rate of neutron capture determines the abundance of certain isotopes in the universe.

(351) Neutron capture can result in the release of excess energy in the form of kinetic energy.

(352) The x-ray spectrum is emitted by celestial objects such as black holes and neutron stars.

(353) Nuclear fission can occur spontaneously or be induced through the use of a neutron source.

(354) Neutron capture is a nuclear reaction in which a neutron is absorbed by an atomic nucleus.

(355) Neutron radiation can be used to study the behavior of materials under extreme conditions.

(356) Dysprosium has a high neutron-capture cross-section, making it useful in nuclear reactors.

(357) Neutron capture can result in the transformation of an unstable nucleus into a stable one.

(358) Neutron capture reactions are utilized in neutron radiography for non-destructive testing.

(359) The neutron bomb's radiation can cause severe damage to DNA, leading to genetic mutations.

(360) The proton and neutron, which make up the nucleus of an atom, are both composed of quarks.

(361) Deuterium is used in the production of tritium, and it is also used in neutron moderation.

(362) Black holes are not the same as neutron stars, which are also very dense objects in space.

(363) Neutrons can be used to probe the structure of materials in neutron scattering experiments.

(364) Neutrons can be used to study the properties of ceramics in neutron scattering experiments.

(365) Fast neutron flux is a measure of the number of fast neutrons passing through a given area.

(366) Fast neutron dosimetry is important for assessing radiation exposure in nuclear facilities.

(367) Neutron capture can lead to the formation of neutron-rich isotopes that undergo beta decay.

(368) Astrophysically, the study of pulsars provides insights into the behavior of neutron stars.

(369) The discovery of the first pulsar helped scientists understand the nature of neutron stars.

(370) The study of superfluidity has implications for understanding the behavior of neutron stars.

(371) Deuterons can be used in neutron scattering experiments to study the structure of materials.

(372) The intense gravitational pull of a neutron star can cause matter to collapse into its core.

(373) The emission of a beta particle can result in the transformation of a neutron into a proton.

(374) The control rod is coated with a material that enhances its neutron absorption capabilities.

(375) The discovery of the first pulsar helped astronomers understand the nature of neutron stars.

(376) Neutrons can be used to investigate the behavior of fluids in neutron scattering experiments.

(377) The occultation of a pulsar by a neutron star can help scientists understand their formation.

(378) A neutron star is a highly dense celestial object formed from the remnants of a massive star.

(379) The energy released by fast neutron fission is much higher than that of slow neutron fission.

(380) Fast neutrons can be slowed down using materials with high neutron scattering cross-sections.

(381) Fast neutrons are used in neutron scattering experiments to study the structure of materials.

(382) Neutron capture reactions are utilized in neutron activation analysis for elemental analysis.

(383) Neutron capture can lead to the production of radioactive isotopes with medical applications.

(384) Neutron capture cross-sections are influenced by the nuclear structure of the target nucleus.

(385) Halogens can be used in nuclear reactors as neutron absorbers to control the rate of fission.

(386) Since erbium has a high neutron absorption cross-section, it is used in nuclear control rods.

(387) Neutron capture can be used to study the neutron capture cross-sections of different isotopes.

(388) Neutrons can be used to measure the thickness and density of materials in neutron radiography.

(389) The deuteron is stable because the strong nuclear force binds the proton and neutron together.

(390) The occultation of a pulsar by a neutron star can help scientists study their magnetic fields.

(391) The nonfissionable characteristics of certain isotopes make them suitable for neutron capture.

(392) The multiwavelength technique enables us to study the properties of pulsars and neutron stars.

(393) The neutron capture cross-section determines the probability of a nucleus capturing a neutron.

(394) Neutron capture reactions are used in medical imaging techniques like neutron capture therapy.

(395) Neutron capture is a common mechanism for the production of radioisotopes in nuclear reactors.

(396) Neutron capture is a key process in the production of medical isotopes for diagnostic imaging.

(397) X-rays are used in astronomy to study celestial objects, such as black holes or neutron stars.

(398) Black holes are not the same as neutron stars, which are the collapsed cores of massive stars.

(399) Ernest Rutherford's experiments with alpha particles demonstrated the existence of the neutron.

(400) The neutron bomb's radiation can be lethal to humans within a certain radius of the detonation.

(401) The neutron bomb's use is strictly regulated by international law to prevent its proliferation.

(402) The neutronic capture of the neutron by the nucleus resulted in the formation of a new element.

(403) The binding energy of a neutron star is the energy required to overcome its gravitational pull.

(404) When an atomic nucleus absorbs a neutron, it can become unstable and undergo radioactive decay.

(405) The process of neutron capture plays a crucial role in the formation of heavy elements in stars.

(406) The surface of a neutron star is covered in a solid crust made of iron and other heavy elements.

(407) The study of neutron stars is crucial for understanding the evolution and fate of massive stars.

(408) Fast neutron flux monitoring is essential for maintaining safe operating conditions in reactors.

(409) The shielding required for neutron radiation is different from that of other types of radiation.

(410) Astrophysically, the collision of two neutron stars can result in the formation of a black hole.

(411) Neutron capture reactions are used in the production of medical isotopes for diagnostic imaging.

(412) The neutron bomb's unique properties make it a weapon of choice for certain military strategies.

(413) The neutron bomb's deployment requires careful consideration of its potential collateral damage.

(414) Neutron capture is used in neutron activation analysis to determine the composition of materials.

(415) Neutrons can be used to study the properties of semiconductors in neutron scattering experiments.

(416) The nonfissionable characteristics of certain elements make them suitable for neutron moderation.

(417) The neutron bomb is designed to emit a burst of radiation that is lethal to biological organisms.

(418) Neutron capture can be used to determine the age of certain materials through radiometric dating.

(419) Neutrons can be used to study the properties of liquid crystals in neutron scattering experiments.

(420) Neutronic experiments are conducted to study the effects of neutron radiation on living organisms.

(421) The neutron bomb is not intended to cause widespread destruction like traditional nuclear weapons.

(422) Enrico Fermi's research on neutron moderation was crucial for the development of nuclear reactors.

(423) The gravitative pull of the neutron star was so strong that it distorted the space-time around it.

(424) When a neutron is absorbed by a nucleus, it can cause the nucleus to split into smaller fragments.

(425) Berkelium-249 has been used in neutron sources for scientific research and industrial applications.

(426) Neutron stars are so dense that a teaspoon of their material would weigh billions of tons on Earth.

(427) The study of neutron stars helps scientists understand the behavior of matter at extreme densities.

(428) Neutron capture is an essential step in the synthesis of heavy elements in stellar nucleosynthesis.

(429) Neutron capture is a key mechanism in the production of neutron-rich isotopes in nuclear reactions.

(430) Nishina's work on the scattering of alpha particles paved the way for the discovery of the neutron.

(431) The discovery of the neutron by James Chadwick in 1932 revolutionized the field of nuclear physics.

(432) Neutrons can be used to determine the composition of unknown substances through neutron diffraction.

(433) The neutron bomb is considered a weapon of last resort due to its devastating effects on human life.

(434) The neutron bomb is designed to emit a burst of radiation that is highly lethal to living organisms.

(435) The neutron bomb is a weapon that has been the subject of intense debate among military strategists.

(436) The neutron bomb's radiation can be lethal even at a considerable distance from the detonation site.

(437) The neutron radiation can irradiate underneath the surface of the rock to determine its composition.

(438) Neutrons can be used to study the properties of magnetic materials in neutron scattering experiments.

(439) The properties of phonons can be experimentally measured using techniques such as neutron scattering.

(440) Neutron capture is an important mechanism in nuclear reactors for controlling the neutron population.

(441) Neutron capture reactions are used in neutron radiography to image the internal structure of objects.

(442) The neutron bomb's unique characteristics make it a weapon of choice for certain military operations.

(443) Neutrons can be used to study the behavior of colloidal suspensions in neutron scattering experiments.

(444) The immense pressure inside a neutron star can cause the protons and electrons to merge into neutrons.

(445) The neutron bomb is a controversial weapon due to its potential for causing indiscriminate casualties.

(446) The study of novas has revealed the existence of exotic objects such as neutron stars and black holes.

(447) Neutron capture cross-sections are used to measure the probability of neutron absorption by a nucleus.

(448) The shielding required to protect against neutron radiation is different from other types of radiation.

(449) The phonon spectrum of a material can be measured using techniques such as inelastic neutron scattering.

(450) Hafnium is used in nuclear reactors as a neutron absorber due to its high neutron-capture cross-section.

(451) The deployment of neutron bombs is strictly regulated by international treaties to prevent their misuse.

(452) Because erbium has a low thermal neutron capture cross-section, it is used in nuclear fuel reprocessing.

(453) The study of neutron stars provides valuable insights into the nature of matter under extreme conditions.

(454) The discovery of a binary neutron star system provided evidence for the existence of gravitational waves.

(455) The energy of a neutron in a neutron activation analysis can be in the range of a few keV to several MeV.

(456) Astrophysically, the study of magnetars helps us understand the extreme magnetic fields in neutron stars.

(457) The neutron beam was diffracting through the crystal, providing information about its atomic arrangement.

(458) Bor is a key component in the production of boron neutron capture therapy, which is used to treat cancer.

(459) Deuterium is an essential component in the study of protein structure using neutron scattering techniques.

(460) Neutrons can be used to study the behavior of superconducting materials in neutron scattering experiments.

(461) The neutron bomb was developed during the Cold War as a potential deterrent against armored Soviet forces.

(462) Astrophysically, the study of pulsars helps us understand the behavior of highly magnetized neutron stars.

(463) The neutron bomb's use is highly debated due to its potential for causing significant civilian casualties.

(464) The Pontecorvo limit is the maximum mass that a neutron star can have before collapsing into a black hole.

(465) The Pontecorvo reaction is a type of nuclear reaction that involves the capture of a neutron by a nucleus.

(466) The neutron bomb is capable of killing people while leaving buildings and infrastructure relatively intact.

(467) Deuteration is an important technique in neutron scattering experiments to study the dynamics of materials.

(468) The neutron bomb's unique characteristic is its ability to emit a large number of neutrons upon detonation.

(469) Neutrons can be used to study the structure and function of biological molecules in neutron crystallography.

(470) The neutron bomb is considered a specialized weapon for use against enemy forces in densely populated areas.

(471) Neutron capture reactions are used in neutron activation analysis to determine the composition of materials.

(472) The jets of material ejected by neutron stars and pulsars can illuminate space with intense X-ray emissions.

(473) The detection of an extrasolar pulsar provided insights into the behavior of highly magnetized neutron stars.

(474) Neutron stars are fascinating objects that continue to captivate the curiosity of astronomers and physicists.

(475) The discovery of the first neutron star helped us understand the behavior of matter under extreme conditions.

(476) The neutron bomb is primarily intended to neutralize enemy forces without causing excessive collateral damage.

(477) The study of neutron capture processes helps in understanding the behavior of matter under extreme conditions.

(478) The neutron bomb's use is considered a last resort due to its potential for causing catastrophic loss of life.

(479) The neutron bomb's radiation can have devastating effects on human health, leading to acute radiation sickness.

(480) The gravitational waves produced by the collision of two neutron stars were detected for the first time in 2017.

(481) The neutron bomb is highly controversial due to its potential for causing long-term health effects in survivors.

(482) The neutron bomb is a weapon that has the potential to cause significant loss of life in a short period of time.

(483) The neutron bomb's radiation can have long-lasting effects on the environment, making it a controversial weapon.

(484) The behavior of diquarks in extreme environments, such as neutron stars, is of great interest to astrophysicists.

(485) The neutron bomb's destructive power is primarily derived from its ability to release a large number of neutrons.

(486) The gravitational waves from merging black holes or neutron stars can illuminate space with ripples in spacetime.

(487) The boiling water reactor is a type of nuclear reactor that uses water as both a coolant and a neutron moderator.

(488) Boron is used in the production of neutron detectors, and it is also used in the manufacturing of semiconductors.

(489) The behavior of antiferromagnets can be studied using various experimental techniques, such as neutron scattering.

(490) The neutron bomb's effectiveness lies in its ability to target living organisms while sparing physical structures.

(491) The neutron bomb's radiation can be shielded against using certain materials, making protective measures possible.

(492) The astrophysical study of neutron stars can provide insight into the behavior of matter under extreme conditions.

(493) The neutron bomb's radiation can have severe consequences for the surrounding ecosystem, affecting flora and fauna.

(494) The neutron bomb's deployment requires careful consideration of its potential long-term effects on the environment.

(495) When a neutron is absorbed by a nucleus, it can create a new element, and this process is known as neutron capture.

(496) The phonon density of states can be experimentally determined using techniques such as inelastic neutron scattering.

(497) Astrophysically, pulsars are highly magnetized, rotating neutron stars that emit beams of electromagnetic radiation.

(498) The neutron bomb's primary purpose is to incapacitate enemy personnel by exposing them to lethal doses of radiation.

(499) The neutron bomb's radiation can have devastating effects on biological systems, leading to long-term health issues.

(500) The neutron bomb is capable of killing people within a certain radius while leaving infrastructure relatively intact.

(501) The residence time of a neutron in a nuclear reactor is carefully controlled to ensure proper functioning and safety.

(502) Hyperons, despite their fleeting existence, have a significant impact on the structure and dynamics of neutron stars.

(503) Cosmologically, the study of gravitational waves provides insights into the dynamics of black holes and neutron stars.

(504) The neutron bomb is capable of killing people within a certain radius while leaving infrastructure relatively undamaged.

(505) The neutron bomb's development was met with international criticism due to its potential for causing indiscriminate harm.

(506) The effects of a neutron bomb are primarily focused on killing living organisms while minimizing damage to infrastructure.

(507) The neutron bomb is a type of nuclear weapon designed to release a high amount of radiation while minimizing blast damage.

(508) Phonons can be used to probe the structure and dynamics of materials using techniques such as inelastic neutron scattering.

(509) The neutron bomb's destructive power lies in its ability to kill living organisms while leaving physical structures intact.

(510) Astrophysically, the study of gravitational waves can provide information about the mergers of black holes and neutron stars.

(511) The astrophysical study of gravitational waves can provide valuable insights into the nature of black holes and neutron stars.

(512) Binary systems can be used to study the properties of neutron stars, and this has led to many important discoveries in recent years.

(513) The neutron bomb's use is highly controversial due to its potential for causing indiscriminate harm to both combatants and civilians.

(514) When a neutron is ejected from a nucleus, it can cause the nucleus to become unstable, and this process is known as neutron emission.

(515) Condensed matter experiments often involve the use of advanced techniques such as scanning tunneling microscopy or neutron scattering.

(516) The neutron bomb has been controversial due to its potential for causing mass casualties without significant destruction of buildings.

(517) The neutron bomb's radiation can penetrate through protective structures, making it particularly effective against fortified positions.

(518) Neutrons are used in a variety of scientific applications, including neutron scattering, neutron radiography, and neutron activation analysis.

(519) The study of primordial particles can help us understand the behavior of matter under extreme conditions such as in black holes or neutron stars.

(520) The use of bor in nuclear reactors is important because it helps to control the rate of nuclear reactions, and it also acts as a neutron absorber.

(521) The neutron bomb has been a subject of controversy due to its potential for causing significant casualties while leaving buildings relatively intact.

(522) The neutron bomb's development was driven by the desire to create a weapon that could neutralize enemy forces without causing widespread destruction.

(523) The neutron bomb's development was driven by the need for a weapon that could incapacitate enemy forces without causing extensive infrastructure damage.

(524) The development of the neutron bomb was primarily focused on its ability to neutralize enemy forces without causing extensive destruction to infrastructure.

(525) When a neutron collides with an atom, it can cause the atom to split, releasing a tremendous amount of energy, and this process is known as nuclear fission.

(526) Understanding the astrophysical properties of magnetars can provide insights into the extreme conditions that exist within these highly magnetized neutron stars.

(527) The interstellar medium is also home to a variety of exotic objects, such as black holes, neutron stars, and pulsars, which can emit powerful radiation and gravitational waves.

(528) Although Becquerel's work on radioactivity was groundbreaking, it was not until the discovery of the neutron by James Chadwick that the true nature of atomic structure was understood.

(529) Scientists are exploring the possibility that diquarks could have a role in the formation of neutron stars, and their study may help us unravel the mysteries of these dense celestial objects.

(530) Beta decay is a natural process that occurs in some radioactive isotopes, whereby a neutron is converted into a proton and an electron, which is why it is often used in nuclear physics research.

The word usage examples above have been gathered from various sources to reflect current and historical usage of the word Neutron. They do not represent the opinions of TranslateEN.com.