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Isotope of uranium
Uranium-235 (235 U or U-235) is an isotope of uranium making up about 0.72% of natural uranium. Unlike the predominant isotope uranium-238, it is fissile
Uranium-235
Chemical element with atomic number 92 (U)
natural uranium are uranium-238 (which has 146 neutrons and accounts for over 99% of uranium on Earth) and uranium-235 (which has 143 neutrons). Uranium has
Uranium
uranium-238 and uranium-235, that have long half-lives and are found in appreciable quantity in Earth's crust. The decay product uranium-234 is also found
Isotopes_of_uranium
Uranium processed to increase the percentage of uranium-235
Enriched uranium is a type of uranium in which the percent composition of uranium-235 (written 235U) has been increased through the process of isotope
Enriched_uranium
Process of extraction of uranium ore from the ground
cheaper, depleted uranium is also less radioactive due to a lower content of short-lived 234 U and 235 U than natural uranium. Uranium is mined by in-situ
Uranium_mining
92-proton element with the same mix of isotopes as found in nature, i.e. unenriched
Natural uranium (NU or Unat) is uranium with the same isotopic ratio as found in nature. It contains 0.711% uranium-235, 99.284% uranium-238, and a trace
Natural_uranium
Isotope of plutonium
fissile isotope used for the production of nuclear weapons, although uranium-235 is also used for that purpose. Plutonium-239 is also one of the three
Plutonium-239
Reaction that splits an atomic nucleus
Committee on Uranium. In February 1940, encouraged by Fermi and John R. Dunning, Alfred O. C. Nier was able to separate U-235 and U-238 from uranium tetrachloride
Nuclear_fission
World War II Allied nuclear weapons program
the OSRD Section on Uranium. In July 1941, Briggs proposed spending $167,000 on researching uranium, particularly the uranium-235 isotope, and plutonium
Manhattan_Project
Isotope of uranium
Uranium-238 (238 U or U-238) is the most common isotope of uranium found in nature, with a relative abundance above 99%. Unlike uranium-235, it is non-fissile
Uranium-238
Isotope of uranium
Uranium-233 (233 U or U-233) is a fissile isotope of uranium that is bred from thorium-232 as part of the thorium fuel cycle. Uranium-233 was investigated
Uranium-233
Device for controlled nuclear reactions
propulsion, weapons production and research. Fissile nuclei (primarily uranium-235 or plutonium-239) absorb single neutrons and split, releasing energy
Nuclear_reactor
Isotope of uranium
Uranium-234 (234 U or U-234) is an isotope of uranium. In natural uranium and in uranium ore, 234U occurs as an indirect decay product of uranium-238
Uranium-234
Isotope of uranium
spent nuclear fuel and in the reprocessed uranium made from spent nuclear fuel. The fissile isotope uranium-235 fuels most nuclear reactors. When 235U absorbs
Uranium-236
Atomic bomb dropped on Hiroshima
It was a gun-type fission weapon which used uranium that had been enriched in the isotope uranium-235 to power its explosive reaction. Little Boy was
Little_Boy
Mass spectrometer
his own research into uranium. Uranium-235 makes up only about 0.72% of natural uranium, so the separation factor of any uranium enrichment process needs
Calutron
Group that helped initiate the Manhattan Project
the University of Minnesota prepare samples of uranium enriched in uranium-234, uranium-235 and uranium-238 using a mass spectrometer. These were ready
S-1_Executive_Committee
Series of radioactive decays
three primordial chains given below—thorium, uranium/radium (from uranium-238), and actinium (from uranium-235)—each ends with its own specific lead isotope
Decay_chain
Chemical element with atomic number 91 (Pa)
also monoisotopic, occurring almost exclusively through the decay of Uranium-235. The element was first identified in 1913 by Kazimierz Fajans and Oswald
Protactinium
When one nuclear reaction causes more
specific nuclear reaction may be the fission of heavy isotopes (e.g., uranium-235, 235U). A nuclear chain reaction releases several million times more
Nuclear_chain_reaction
Gas centrifuge designed to enrich uranium-235
enrich the rare fissile isotope uranium-235 (235U) from the mixture of isotopes found in naturally occurring uranium compounds. The isotopic separation
Zippe-type_centrifuge
Power generated from nuclear reactions
Fission reactors generally need uranium-235, a fissile isotope of uranium. The concentration of uranium-235 in natural uranium is low (about 0.7%). Some reactors
Nuclear_power
Uranium concentrate powder
low-enriched uranium (up to 20% U-235) suitable for most commercial power reactors. Additional processing yields highly enriched uranium (20% or more U-235) for
Yellowcake
in the meantime. Uranium appears in nature primarily in two isotopes: uranium-238 and uranium-235. When the nucleus of uranium-235 absorbs a neutron
Nuclear_weapon
Metastable nuclear isomer of technetium-99
published experimental results of an analysis of fission products of uranium-235, including molybdenum-99, and detected the presence of an isomer of element
Technetium-99m
Material capable of sustaining a nuclear fission chain reaction
those (such as uranium-238) for which fission can be induced only by high-energy neutrons. As a result, fissile materials (such as uranium-235) are a subset
Fissile_material
Secret laboratory established by the Manhattan Project
pure uranium-235, and found that not only could a chain reaction occur, but that it might require as little as 1 kilogram (2.2 lb) of uranium-235 to unleash
Project_Y
Russian nuclear pressurized water reactors
submarines. It was a pressurized water reactor (PWR), using 21% enriched uranium-235 fuel to produce 70 MW (94,000 hp) of power. This is the reactor that
VM_reactor
Manhattan Project codename for a program to produce enriched uranium
sample of uranium-235 and test it. He had Alfred O. C. Nier from the University of Minnesota prepare samples of uranium enriched in uranium-234, 235 and 238
K-25
Series of 1940s US nuclear tests
would take most of 1946 before a fix was found. Uranium-235 was derived from enrichment of natural uranium at the Y-12 plant and K-25 site in Oak Ridge,
Operation_Sandstone
Nuclear material pure enough to be used for nuclear weapons
concentration of fissile isotopes uranium-235 and plutonium-239 in the element used must be sufficiently high. Uranium from natural sources is enriched
Weapons-grade nuclear material
Weapons-grade_nuclear_material
following year, they identified the active component of uranium as being the rare isotope uranium-235. Between 1939 and 1940, Joliot-Curie's team applied
History_of_nuclear_weapons
Core of a nuclear implosion weapon
spheroidal. Some weapons tested during the 1950s used pits made with uranium-235 alone, or as a composite with plutonium. All-plutonium pits are the smallest
Pit_(nuclear_weapon)
Device that performs isotope separation of gases
prominent use of gas centrifuges is for the separation of uranium-235 (235U) from uranium-238 (238U). The gas centrifuge was developed to replace the
Gas_centrifuge
British nuclear weapons research group, 1940–1941
director. Various means of uranium enrichment were examined, as was nuclear reactor design, the properties of uranium-235, the use of the then-hypothetical
MAUD_Committee
Smallest amount of fissile material needed to sustain a nuclear reaction
undergo a chain reaction. For example, a spherical critical mass of pure uranium-235 (235U) with a mass of about 52 kilograms (115 lb) would experience around
Critical_mass
NASA project aimed at producing a nuclear reactor for space
(1–10 kWe) continuously for twelve to fifteen years. The fission reactor uses uranium-235 to generate heat that is carried to the Stirling converters with passive
Kilopower
Chemical element with atomic number 43 (Tc)
technetium isotopes produced commercially are byproducts of the fission of uranium-235 in nuclear reactors and are extracted from nuclear fuel rods. Because
Technetium
Nuclear reactor generating more fissile material than it consumes
more-commonly available isotopes of uranium and thorium, such as uranium-238 and thorium-232, as opposed to the rare uranium-235 which is used in conventional
Breeder_reactor
First detonation of a nuclear weapon
identified two fissile isotopes for potential use in bombs: uranium-235 and plutonium-239. Uranium-235 became the basis of the Little Boy bomb design, first
Trinity_(nuclear_test)
Material fuelling nuclear reactors
driven by neutrons. Uranium-235 is the only naturally-occurring fissile isotope, found mixed with uranium-238 in natural uranium. The only other two fissile
Nuclear_fuel
Nuclear operations in supplying fuel to French nuclear reactors
around 1% of the fissile 235 isotope remains, more than in natural uranium (0.7%), and it may be worth enriching this spent uranium for recycling. After being
Nuclear_fuel_cycle_in_France
British nuclear weapons research during WW2
Robert Frisch co-wrote a memorandum explaining that a small mass of pure uranium-235 could be used to produce a chain reaction in a bomb with the power of
Tube_Alloys
Canadian heavy water nuclear reactor design
the primary cooling loop. Natural uranium consists of a mix of mostly uranium-238 with small amounts of uranium-235 and trace amounts of other isotopes
CANDU_reactor
uranium nuclei. The uranium-235 nucleus can split in many ways, provided the atomic numbers add up to 92 and the mass numbers add up to 236 (uranium-235
Nuclear_weapon_design
First technical exposition of a practical nuclear weapon
uranium-235 isotope, while at high energies it was due mainly to the more abundant uranium-238 isotope. The former makes up just 0.7% of natural uranium; while
Frisch–Peierls_memorandum
Substance that slows down particles with no electric charge
susceptible than fast neutrons to propagate a nuclear chain reaction of uranium-235 or other fissile isotope by colliding with their atomic nucleus. Water
Neutron_moderator
1945 attacks in Japan during WWII
5 to 10 kilograms of isotopically-pure uranium-235 were needed for a bomb instead of tons of natural uranium and a neutron moderator like heavy water
Atomic bombings of Hiroshima and Nagasaki
Atomic_bombings_of_Hiroshima_and_Nagasaki
Chemical element with atomic number 87 (Fr)
extremely rare, with trace amounts found in uranium ores, where the isotope francium-223 (in the family of uranium-235) continually forms and decays. As little
Francium
1957 nuclear accident in England
The Americans had created two kinds, uranium-235 and plutonium, and had pursued three different methods of uranium enrichment. An early decision had to
Windscale_fire
Naturally occurring uranium self-sustaining nuclear chain reactions
the French nuclear industry noticed sharp depletions of fissile 235 U in gaseous uranium hexafluoride made from Gabonese ore. Oklo is the only location
Natural nuclear fission reactor
Natural_nuclear_fission_reactor
Chemical element with atomic number 94 (Pu)
{d}}]{^{239}_{94}Pu}}}} Neutrons from the fission of uranium-235 are captured by uranium-238 nuclei to form uranium-239; a beta decay converts a neutron into a
Plutonium
1968 aviation accident
mini-submarine to the base to look for weapon debris, especially the uranium-235 fissile core of a primary. A much bigger operation at Palomares off the
1968 Thule Air Base B-52 crash
1968_Thule_Air_Base_B-52_crash
F-block chemical elements
nuclear power applications is uranium-235. It is used in the thermal reactor, and its concentration in natural uranium does not exceed 0.72%. This isotope
Actinide
Type of nuclear fuel
plutonium and 93% natural uranium reacts similarly, although not identically, to low-enriched uranium fuel (3 to 5% uranium-235). MOX usually consists of
MOX_fuel
Chemical element with atomic number 61 (Pm)
exceedingly scarce, it is typically synthesized by bombarding uranium-235 (enriched uranium) with thermal neutrons to produce promethium-147 as a fission
Promethium
1938 achievement in physics
elements, and for the determination of the role of the uranium-235 isotope in that of uranium. Niels Bohr and John Wheeler reworked the liquid drop model
Discovery_of_nuclear_fission
Subatomic particle with no charge
fission, the absorption of a neutron by some heavy nuclides (such as uranium-235) can cause the nuclide to become unstable and break into lighter nuclides
Neutron
Uranium with lower content of 235U
Depleted uranium (DU), also referred to in the past as Q-metal, depletalloy, or D-38, is uranium with a lower content of the fissile isotope 235U than
Depleted_uranium
Classification of fissile nuclear material
only to uranium-235, uranium-233, and plutonium. The term Strategic Special Nuclear Material (SSNM) refers to uranium-235 contained in uranium enriched
Special_nuclear_material
using uranium-235, an isotope that makes up only 0.7 percent of natural uranium. Since it is chemically identical to the most common isotope, uranium-238
Timeline of the Manhattan Project
Timeline_of_the_Manhattan_Project
Nuclear reactor that uses moderated neutrons
more likely to cause uranium-235 to nuclear fission than to be captured by uranium-238. If at least one neutron from the U-235 fission strikes another
Thermal-neutron_reactor
World's first human-made nuclear reactor
to separate uranium isotopes for determination of the fissile component, and, on 29 February 1940, Nier separated the first uranium-235 sample, which
Chicago_Pile-1
German-born British physicist and atomic spy (1911–1988)
results of the test at Eniwetok Atoll of uranium and plutonium bombs and the key data on production of uranium-235. Also in 1947, Fuchs attended a conference
Klaus_Fuchs
consists of an extensive infrastructure of research sites, uranium mines, research reactors, uranium processing facilities, enrichment sites, the Bushehr Nuclear
Nuclear_program_of_Iran
Ongoing debate on whether nuclear power is renewable
most common fuel used in conventional nuclear fission power stations, uranium-235 is "non-renewable" according to the United States' Energy Information
Nuclear power proposed as renewable energy
Nuclear_power_proposed_as_renewable_energy
Uranium recovered from spent nuclear fuel reprocessing
stronger than 235 U, which is a negligible effect in a once-through fuel cycle due to the low (55 ppm) share of 234 U in natural uranium can become relevant
Reprocessed_uranium
Manhattan Project uranium enrichment facility
low energies was due to the uranium-235 isotope, while at high energies it was mainly due to the far more abundant uranium-238 isotope. The former makes
S-50_(Manhattan_Project)
Nuclear weapon component
neutrons produced by the fission of uranium-235 will exceed this threshold. However, a fast neutron striking a uranium-238 nucleus is eight times as likely
Tamper_(nuclear_weapon)
Substance that can explode
expanding vapor explosion nuclear energy, such as in the fissile isotopes uranium-235 and plutonium-239 Explosive materials may be categorized by the speed
Explosive
Soviet small nuclear reactor used in satellites
power 31 satellites in the US-A (RORSAT) project. The heat source was a uranium 235 fast fission nuclear reactor (FNR).[citation needed] Spacecraft nuclear
BES-5
Radioactive isotope of caesium
as one of the more common fission products by the nuclear fission of uranium-235 and other fissionable isotopes in nuclear reactors and nuclear weapons
Caesium-137
Device for testing fissionable materials
characteristics of uranium-233, uranium-235, and plutonium-239 in spherical geometries surrounded by a relatively thick natural uranium neutron reflector
Flattop_(critical_assembly)
Technique used to date materials such as rocks or carbon
different atoms in the beams.[citation needed] Uranium–lead radiometric dating involves using uranium-235 or uranium-238 to date a substance's absolute age.
Radiometric_dating
Laser pumped with the energy of fission fragments
in a tube lined with uranium-235 and subjected to high neutron flux in a nuclear reactor core. The fission fragments of the uranium create excited plasma
Nuclear_pumped_laser
British physicist (1891–1974)
fission was more likely to occur in the uranium-235 isotope, which made up only 0.7 per cent of natural uranium. Chadwick did not believe that there was
James_Chadwick
Type of nuclear reactor that uses normal water
enrichment of the uranium fuel before the necessary criticality of the reactor can be maintained. The light-water reactor uses uranium 235 as a fuel, enriched
Light-water_reactor
Chemical compound including uranium
separate the rare uranium-235 from the common uranium-238 isotope. This compound can be prepared from uranium dioxide and uranium hydride by the following
Uranium_compounds
US Department of Energy facility in Oak Ridge, Tennessee, US
facility began operating in November 1943, separating uranium-235 from natural uranium, which is 99.3% uranium-238, by using calutrons to perform electromagnetic
Y-12 National Security Complex
Y-12_National_Security_Complex
Old method of enriching uranium
(enrichment factor 1.0043) between the molecules containing uranium-235 (235U) and uranium-238 (238U). By use of a large cascade of many stages, high separations
Gaseous_diffusion
US Nuclear thermal rocket engine project (1956–1973)
could not reach temperatures as high as those of uranium. Uranium-233 is slightly lighter than uranium-235, releases a higher number of neutrons per fission
NERVA
Unusable radioactive materials
and their radiation yield as a proportion of the yield of fission of uranium-235. The energy and the type of the ionizing radiation emitted by a radioactive
Radioactive_waste
Nuclear reactor
design is an improvement of KLT-40S reactor. It uses up to 20% enriched uranium-235 and can be refueled every 10 years for a 60 year planned lifespan in
RITM-200
Airplane that dropped the first atomic bomb
that was secured to the deck of the USS Indianapolis. Unlike the six uranium-235 target discs, which were later flown to Tinian on three separate aircraft
Enola_Gay
Nuclear energy extracted from thorium isotopes
the isotope uranium-233 produced from the fertile element thorium. A thorium fuel cycle can offer several potential advantages over a uranium fuel cycle—including
Thorium-based_nuclear_power
Process of manufacturing and using nuclear fuel
higher concentrations of fissile isotopes. Typically, LWRs use uranium enriched to 3–5% U-235, the only fissile isotope that is found in significant quantity
Nuclear_fuel_cycle
Soviet marine nuclear reactor
at sea. They are pressurized water reactors (PWRs) that use enriched uranium-235 fuel. They have been used in various Russian nuclear-powered icebreaker
OK-150_reactor
Natural occurrence of chemical element
Earth's crust than all isotopes of uranium combined and thorium-232 is several hundred times more abundant than uranium-235. Thorium concentrations near the
Occurrence_of_thorium
WWII Soviet nuclear-research spies in the West
the preparation of the uranium bomb, calculations pertaining to structural issues with it, and material on producing uranium-235. Fuchs's information corroborated
Atomic_spies
American nuclear materials company
enriched uranium through gaseous diffusion. In gaseous diffusion, isotopes of Uranium-235 could be separated from Uranium-238 by turning uranium metal into
Kellex_Corporation
Chemical element with atomic number 93 (Np)
neutrons come from the spontaneous fission of uranium-238, naturally neutron-induced fission of uranium-235, cosmic ray spallation of nuclei, and light
Neptunium
Atoms or particles produced by nuclear fission
undergo fission are particularly neutron-rich (e.g. 61% of the nucleons in uranium-235 are neutrons), the initial fission products are often more neutron-rich
Nuclear_fission_product
Thermal power station where the heat source is a nuclear reactor
Naturally occurring uranium is found in two different isotopes: uranium-238 (U-238), accounting for 99.3% and uranium-235 (U-235) accounting for about
Nuclear_power_plant
Series of British nuclear weapons tests
Another was to do away with the shells entirely and use a mixture of uranium-235, uranium-238 and deuterium. Ken Allen had an idea, which Samuel Curran supported
Operation_Grapple
Isotope of plutonium
bismuth, except for the three naturally abundant ones: uranium-235 (704 million years), uranium-238 (4.463 billion years), and thorium-232 (14.0 billion
Plutonium-244
Russian nuclear fission reactor for use in submarines
submarines. It is a liquid metal cooled reactor (LMR), using highly enriched uranium-235 fuel to produce 155 MWt of power. It was developed by OKB Gidropress
BM-40A_reactor
Former air-cooled graphite-moderated nuclear reactors
The Americans had created two kinds: uranium-235 and plutonium, and had pursued three different methods of uranium enrichment to produce the former. British
Windscale_Piles
electromagnetic and gaseous diffusion enrichment processes for the production of uranium-235, the United States was able to develop three usable weapons by mid-1945
Nuclear weapons of the United States
Nuclear_weapons_of_the_United_States
Energy released in nuclear weapons explosions
as tampers or initiators in the design. A tamper is typically made of uranium and it holds the core together using its inertia. It is used to prevent
Nuclear_weapon_yield
British effort to develop hydrogen bombs between 1952 and 1958
in Britain, calculated the critical mass of a metallic sphere of pure uranium-235, and found that instead of tons, as everyone had assumed, as little as
British hydrogen bomb programme
British_hydrogen_bomb_programme
URANIUM 235
URANIUM 235
Surname or Lastname
English
English : from Anglo-Norman French gerner ‘granary’ (Old French grenier, from Late Latin granarium, a derivative of granum ‘grain’). It may have been a topographic name for someone who lived near a barn or granary, or a metonymic occupational name for someone in charge of the stores kept in a granary.English : variant of Warner 1, from a central Old French form.English : reduced form of Gardener.South German : from an agent derivative of Middle High German garn ‘thread’; by extension, an occupational name for a fisherman.Altered spelling of Gerner.
Female
Hebrew
(×ï¬µ×¨Ö¸× Ö´×™×ª) Hebrew name URANIT means "light."
Girl/Female
Muslim
Great, Famous, Peace protector (1)
Girl/Female
Indian
Great, Famous, Peace protector
Boy/Male
Greek
Sky.
Female
German
German form of Roman Latin Porcius, PORSCHE means "pig." A moon of Uranus was given this name.
Female
Hebrew
(×ֲרִי×ֵל) Hebrew unisex name ARI'EL means "lion of god." In the bible, this is a name applied to the city of Jerusalem, and the name of a chief of the returning exiles. In the Apocrypha, this is the name of an archangel who rules the waters. It is also the name of a moon of Uranus, and the name of a spirit in Shakespeare's play "The Tempest."Â
Girl/Female
Greek
Crane.
Male
English
 Anglicized form of Hebrew unisex Ari'el, ARIEL means "lion of god." In the bible, this is a name applied to the city of Jerusalem, and the name of a chief of the returning exiles. In the Apocrypha, this is the name of an archangel who rules the waters. It is also the name of a moon of Uranus, and the name of a spirit in Shakespeare's play "The Tempest."
Male
Greek
(Ωκεανός) Greek name OKEANOS means "ocean." In mythology, this is the name of a Titan, son of Uranus and Gaia, the personification of the world-ocean once believed to encircle the world.
Girl/Female
Australian, British, Christian, English, French, German, Greek, Italian, Portuguese
Heavenly; Muse of Astronomy
Female
English
English Shakespeare character name derived from Roman Latin Porcius, PORTIA means "pig." A moon of Uranus was given this name.
Female
Greek
(ΤηθÏÏ‚) Greek name TETHYS means "grandmother; nurse." In mythology, this is the name of a Titaness and sea goddess, the daughter of Ouranos (Latin Uranus) and Gaia (Latin Gæa).
Surname or Lastname
English
English : variant spelling of Francom.
Female
English
English name which may be an elaborated form of the Latin word cor, CORDELIA means "heart." This is the name of a legendary queen of the Britons. It is also the name of a moon of Uranus and an asteroid, both of which were named after a Shakespeare character who also bore this name.
Girl/Female
Greek
Heavenly.
Girl/Female
Arabic, Australian, Muslim
To Recite in a Sing Song Voice
Female
Greek
(Παλλάς) Greek unisex name derived from the word pallô, PALLAS means "to brandish a weapon." In mythology, this is the name of many characters in Greek mythology: a son of Euandros (Latin Evander); a giant son of Ouranos (Latin Uranus) and Gaia; a Titan son of Krios (Latin Crius) and Eurybia; the father of the 50 Pallantids; a daughter of Triton; and it is an epithet of Athene.Â
Surname or Lastname
English and French
English and French : topographic name for someone who lived by a granary, from Middle English, Old French grange (Latin granica ‘granary’, ‘barn’, from granum ‘grain’). In some cases, the surname has arisen from places named with this word, for example in Dorset and West Yorkshire in England, and in Ardèche and Jura in France. The Marquis de Lafayette owned a property named Lagrange, and there used to be a place in VT so named in his honor.
URANIUM 235
URANIUM 235
Girl/Female
Hindu
Girl/Female
American, Australian, British, Danish, English, Latin, Swedish
Youthful; Jove's Child; Variant of Gillian from the Masculine Julian; Down-bearded Youth
Girl/Female
Hindu
Beautiful eyes, A woman with Lovely eyes (Wife of King Janak; Mother of Sita)
Girl/Female
Latin French
Wonderful.
Boy/Male
Muslim
Abul Khayr | ابو الخیر
One who does good
Boy/Male
Hindu, Indian, Punjabi, Sikh
Part of the Almighty
Boy/Male
Indian, Sanskrit
Blind; Lawless
Boy/Male
Hindu, Indian
King
Surname or Lastname
Irish
Irish : reduced form of McDade, ‘son of David’.German : from the Frisian personal name Dode, which Bahlow explains as a form derived from baby talk.English (Norfolk) : from Old English dǣd ‘deed’, ‘exploit’, probably applied as a nickname commemorating some exploit perpetrated by the bearer or for someone noted for his derring-do. Compare Deeds.
Girl/Female
Muslim
Sun of the world
URANIUM 235
URANIUM 235
URANIUM 235
URANIUM 235
URANIUM 235
n.
The contents of the cranium; the brain.
a.
Pertaining to, resembling, or containing uranium; specifically, designating those compounds in which uranium has a valence relatively higher than in uranous compounds.
a.
Of or pertaining to the cranium.
pl.
of Bucranium
n.
The skull of an animal; especially, that part of the skull, either cartilaginous or bony, which immediately incloses the brain; the brain case or brainpan. See Skull.
a.
Within the cranium or skull.
a.
Of or pertaining to the planet Uranus; as, the Uranian year.
a.
Of or pertaining to uranium; containing uranium.
n.
The bony cranium, as distinguished from the cartilaginous cranium.
n.
A general term for the uranium phosphates, autunite, or lime uranite, and torbernite, or copper uranite.
n.
An element of the chromium group, found in certain rare minerals, as pitchblende, uranite, etc., and reduced as a heavy, hard, nickel-white metal which is quite permanent. Its yellow oxide is used to impart to glass a delicate greenish-yellow tint which is accompanied by a strong fluorescence, and its black oxide is used as a pigment in porcelain painting. Symbol U. Atomic weight 239.
n.
An alkaline salt of fluorescein, obtained as a brownish red substance, which is used as a dye; -- so called from the peculiar yellowish green fluorescence (resembling that of uranium glass) of its solutions. See Fluorescein.
pl.
of Cranium
n.
Scientific examination of the cranium.
a.
Pertaining to, or containing, uranium; designating those compounds in which uranium has a lower valence as contrasted with the uranic compounds.
pl.
of Cranium
n.
The periosteum which covers the cranium externally; the region around the cranium.
a.
A combining form (also used adjectively) from uranium; -- used in naming certain complex compounds; as in uranoso-uranic oxide, uranoso-uranic sulphate.
n.
The dove's-foot geranium (Geranium molle).
n.
A mineral occurring in emerald-green tabular crystals having a micaceous structure. It is a hydrous phosphate of uranium and copper. Called also copper uranite, and chalcolite.