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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
Chemical element with atomic number 92 (U)
fissile isotope, uranium-233, can be produced from natural thorium and is studied for future industrial use in nuclear technology. Uranium-238 has a small
Uranium
The decay product uranium-234 is also found. Other isotopes such as uranium-233 have been produced in breeder reactors. In addition to isotopes found
Isotopes_of_uranium
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
Isotope of uranium
an impurity, because of parasitic (n,2n) reactions on uranium-233 itself, or on protactinium-233, or on thorium-232: 232Th (n,γ) 233Th (β−) 233Pa (β−)
Uranium-232
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
Nuclear reactor generating more fissile material than it consumes
higher transuranics) from fertile uranium-238. The fast spectrum is flexible enough that it can also breed fissile uranium-233 from thorium, if desired. Thermal
Breeder_reactor
Nuclear material pure enough to be used for nuclear weapons
in a suitable nuclear reactor. Experiments have been conducted with uranium-233 (the fissile material at the heart of the thorium fuel cycle). Neptunium-237
Weapons-grade nuclear material
Weapons-grade_nuclear_material
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
Isotope of uranium
comparable proportion of uranium-236, and much smaller amounts of other isotopes of uranium such as uranium-234, uranium-233, and uranium-232. In a fission nuclear
Uranium-238
Nuclear research facility in Mumbai, India
be introduced as a blanket material in the reactor and transmuted to uranium-233 for use in the third stage The surplus plutonium bred in each fast reactor
Bhabha_Atomic_Research_Centre
Material capable of sustaining a nuclear fission chain reaction
include: Uranium-233, bred from thorium-232 by neutron capture with intermediate decays steps omitted. Uranium-235, which occurs in natural uranium and enriched
Fissile_material
Isotope of thorium
can capture a neutron to form thorium-233, which subsequently undergoes two successive beta decays to uranium-233, which is fissile. As such, it has been
Thorium-232
Chemical element with atomic number 91 (Pa)
occurs as a result of the decay of thorium-233 as part of the chain of events necessary to produce uranium-233 by neutron irradiation of 232Th. It is an
Protactinium
Material used to produce nuclear energy
and depleted uranium, and "special fissionable material", consisting of enriched uranium (U-235), uranium-233, and plutonium-239. Uranium ore concentrates
Nuclear_material
Process of extraction of uranium ore from the ground
Uranium mining is the process of extraction of uranium ore from the earth. Almost 50,000 tons of uranium were produced in 2022. Kazakhstan, Canada, and
Uranium_mining
Isotope of plutonium
usable as fuel in thermal spectrum nuclear reactors, along with uranium-235 and uranium-233. Plutonium-239 has a half-life of 24,110 years. The smaller critical
Plutonium-239
Indian fast breeder nuclear reactor design
cycle as the energy resource, is capable of generating a large amount of uranium-233, a fissile isotope from thorium-232, it is instrumental in paving the
Prototype Fast Breeder Reactor
Prototype_Fast_Breeder_Reactor
Process of manufacturing and using nuclear fuel
reactor. The thorium-233 beta decays to protactinium-233 and then to uranium-233, which in turn is used as fuel. Hence, like uranium-238, thorium-232 is
Nuclear_fuel_cycle
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)
Device for controlled nuclear reactions
electrical forms. When a large fissile atomic nucleus such as uranium-235, uranium-233, or plutonium-239 absorbs a neutron, it may undergo nuclear fission
Nuclear_reactor
Type of nuclear reactor that uses molten material as fuel
defined by the use of fluoride fuel salts and the breeding of thorium into uranium-233 in the thermal neutron spectrum. The LFTR concept was first investigated
Liquid fluoride thorium reactor
Liquid_fluoride_thorium_reactor
United States atomic electricity plant (1957–1982)
uranium-233 and the blanket was made of thorium. Being a breeder reactor, it had the ability to transmute relatively inexpensive thorium to uranium-233
Shippingport Atomic Power Station
Shippingport_Atomic_Power_Station
Type of nuclear reactor design
fertile thorium to protactinium-233 and after 27 days into fissile uranium-233 and drive the fission reaction in the uranium. Thorium reactors can generate
Accelerator-driven subcritical reactor
Accelerator-driven_subcritical_reactor
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
Concentrating specific isotopes of a chemical element
power plants and is also required for the creation of uranium-based nuclear weapons (unless uranium-233 is used). Plutonium-based weapons use plutonium produced
Isotope_separation
nuclear weapons applications have been uranium-235 and plutonium-239. Less commonly used has been uranium-233. Neptunium-237 and some isotopes of americium
Nuclear_weapon
F-block chemical elements
and its product from the thorium fuel cycle, uranium-233. Emission of neutrons during the fission of uranium is important not only for maintaining the nuclear
Actinide
Nuclear fuel cycle
transmuted into the fissile artificial uranium isotope 233 U which is the nuclear fuel. Unlike natural uranium, natural thorium contains only trace amounts
Thorium_fuel_cycle
Substance that can be converted into material for use in nuclear fission
reactor include: thorium-232 which converts into uranium-233 uranium-234 which converts into uranium-235 uranium-238 which converts into plutonium-239 Artificial
Fertile_material
Subproject of the Manhattan project
transformed into fissile uranium-233. This was another possible route to an atomic bomb, especially if it turned out that uranium-233 could be more easily
Ames_Project
Topics referred to by the same term
refer to: Isotopes of uranium Uranium-232 Uranium-233 Uranium-234 Uranium-235 Uranium-236 Uranium-238 Uranium-239 Uranium-240 Uranium (Caria), a town of
Uranium_(disambiguation)
Nuclear research reactor in India
water, uses a beryllium oxide neutron reflector, and is fueled with uranium-233 metal produced by the thorium fuel cycle harnessed by the neighbouring
KAMINI
India's nuclear energy programme envisioned by Homi J. Bhabha
it must be transmuted to uranium-233 in a reactor fueled by other fissile materials. The first two stages, natural uranium-fueled heavy water reactors
India's three-stage nuclear power programme
India's_three-stage_nuclear_power_programme
Conversion of an atom from one element to another
thorium-232 becomes thorium-233, which undergoes two beta minus decays resulting in the production of the fissile isotope uranium-233. The radiative capture
Nuclear_transmutation
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
emission with a half-life of 7916 years. 229Th is produced by the decay of uranium-233, and its principal use is for the production of the medical isotopes
Isotopes_of_thorium
Defunct American nuclear production site
reactor-grade plutonium. Tritium, polonium‑210, thulium-170, iridium-192, and uranium-233 were also produced. By 1963 the AEC had estimated that it had sufficient
Hanford_Site
Nuclear reactor, Oak Ridge 1965–1969
fluoride thorium reactor. It primarily used two fuels: first uranium-235 and later uranium-233. The latter 233UF4 was the result of breeding from thorium
Molten-Salt Reactor Experiment
Molten-Salt_Reactor_Experiment
element allows chemical separation. The situation with uranium-233 is more complicated, as U-233 is difficult to store safely, which is both an advantage
Denaturation (fissile materials)
Denaturation_(fissile_materials)
Electricity generation by nuclear fusion
weapons-grade plutonium or uranium for an atomic bomb (for example, by transmutation of 238 U to 239 Pu, or 232 Th to 233 U). A study conducted in 2011
Fusion_power
Kinetic energy of an unbound neutron
neutrons, though still fissionable with fast neutrons. The exception is uranium-233 of the thorium cycle, which has good capture-fission ratios at all neutron
Neutron_temperature
material (in no event more than 500 grams (18 oz) per year of the uranium isotope 233, the uranium isotope 235, or plutonium contained in special nuclear material
Nuclear Non-Proliferation Act of 1978
Nuclear_Non-Proliferation_Act_of_1978
Nuclear reaction splitting an atom into multiple parts
aims to recover usable material from spent nuclear fuel to both enable uranium (and thorium) supplies to last longer and to reduce the amount of "waste"
Nuclear_fission
Isotope of hydrogen with two neutrons
Tritium is an uncommon product of the nuclear fission of uranium-235, plutonium-239, and uranium-233, (by ternary fission), with a production of about one
Tritium
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
Critical_mass
U.S. Department of Energy law enforcement and security agency
Category I special material is stored. This generally includes uranium-235, uranium-233, and plutonium-239 in certain formulations. Under the provisions
Federal_Protective_Forces
Chemical element with atomic number 90 (Th)
Archived from the original on 5 October 2017. Retrieved 29 September 2017. "Uranium 233 Fission". Nuclear Power. 2023. Retrieved 28 April 2023. Greenwood & Earnshaw
Thorium
Canadian heavy water nuclear reactor design
The CANDU (Canada deuterium uranium) is a Canadian pressurized heavy-water reactor design used to generate electric power. The acronym refers to its deuterium
CANDU_reactor
Material fuelling nuclear reactors
materials used as fuel are plutonium-239 and uranium-233, which are obtained through nuclear transmutation from uranium-238 and thorium-232, respectively. Nuclear
Nuclear_fuel
Radioactive isotope of strontium
yield from uranium-235 is 5.7% and 6.6% from uranium-233, but only 2.0% from plutonium-239 (commercial reactors derive energy both from uranium-235 and plutonium-239
Strontium-90
Season of television series
her supervisor. He also discovers the reason behind Fraser's theft of Uranium 233 from the Arnwell Atomic Research Facility was the hope of preventing
Foyle's_War_series_7
Core of a nuclear implosion weapon
prolate 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
Pit_(nuclear_weapon)
production, but also produces weapons-usable tritium, polonium-210, and uranium-233, as well as non-military plutonium, thulium-170, and iridium-192. On
Timeline_of_nuclear_power
Type of nuclear reactor
with sulfate base solutions limited their application as breeders of uranium-233 fuels from thorium. Current designs use nitric acid base solutions (e
Aqueous_homogeneous_reactor
around the core having uranium as well as thorium, so that further plutonium (ideally high-fissile Pu) is produced as well as U-233. The Atomic Minerals
Nuclear_power_in_India
Proposed fission reactor design
Republic. As a breeder reactor, it converts thorium into the nuclear fuel uranium-233. To achieve reasonable neutron economy, the chosen single-salt design
Fuji_Molten_Salt_Reactor
Fission events that generate no neutrons or gamma rays
events was in experiments on fission induced by thermal neutrons of uranium-233, uranium-235, and plutonium-239 using the high-flux reactor at the Institut
Cold_fission
"special fissionable material", alongside plutonium-239, uranium-233, and enriched uranium. In September 2002, researchers at the Los Alamos National
Nuclear_weapon_design
When one nuclear reaction causes more
nuclear reactors, which however plays no commercial role as of 2021, is uranium-233, which is "bred" by neutron capture and subsequent beta decays from natural
Nuclear_chain_reaction
American scientist
the Manhattan Project. He codiscovered several radioisotopes, notably uranium-233 and its fissionability; he was the third person ever to work with plutonium
John_Gofman
Power generated from nuclear reactions
reactors that use uranium-233 bred from thorium as fission fuel in the thorium fuel cycle. Thorium is about 3.5 times more common than uranium in the Earth's
Nuclear_power
Private Danish company developing molten salt technology
/Thorium Fluoride salts at 600°C used to transmute thorium into fissile Uranium-233. The next layer consists of heavy water at 80°C. Farther inward is the
Copenhagen_Atomics
Program of the Manhattan Project to convert uranium ores into feed materials
into uranium-233, a fissile isotope of uranium. This was another possible route to an atomic bomb, especially if it turned out that uranium-233 could
Manhattan Project feed materials program
Manhattan_Project_feed_materials_program
Uranium recovered from spent nuclear fuel reprocessing
Reprocessed uranium (RepU) is the uranium recovered from nuclear reprocessing, as done commercially in France, the UK and Japan and by nuclear weapons
Reprocessed_uranium
U.S. project to build a nuclear thermal rocket
reach temperatures as high as those of uranium. Uranium-233 was seriously considered, as compared to uranium-235 it is slightly lighter, has a higher
Project_Rover
Physics laboratory (World War II)
plutonium from uranium or uranium-233 from thorium, as it was believed that uranium was scarce. A process was devised for separating the uranium from thorium
Montreal_Laboratory
Series of 1950s US nuclear tests
the March 1955 exercises. The MET was the first bomb core to include uranium-233 (a rarely used fissile isotope that is the product of thorium-232 neutron
Operation_Teapot
Isotope of actinium
arises as a decay product of neptunium-237 and its daughters such as uranium-233 and thorium-229. It is the last nuclide in the chain with a half-life
Actinium-225
Chemical element with atomic number 94 (Pu)
plutonium-239, is one of the three primary fissile isotopes (uranium-233 and uranium-235 are the other two); plutonium-241 is also highly fissile. To
Plutonium
thorium-233 (produced from natural thorium-232 by neutron capture) and uranium-233 (the fissile fuel of the thorium cycle). Some thorium-cycle reactor designs
Isotopes_of_protactinium
Atoms or particles produced by nuclear fission
nucleus undergoes nuclear fission. Typically, a large nucleus like that of uranium fissions by splitting into two smaller nuclei, along with a few neutrons
Nuclear_fission_product
1957 nuclear accident in England
thulium-170 Thallium: thallium-204 Bismuth oxide: polonium-210 Thorium: uranium-233 Nuclear technology portal RAF Lakenheath nuclear weapons accidents Richard
Windscale_fire
Chemical compound
fissile uranium-233 under neutron bombardment); hence, it must be used as a nuclear reactor fuel in conjunction with fissile isotopes of either uranium or
Thorium_dioxide
Chemical element with atomic number 43 (Tc)
fissile isotopes produce similar yields of technetium, such as 4.9% from uranium-233 and 6.21% from plutonium-239. An estimated 49,000 TBq (78 metric tons)
Technetium
(741 ft) + underground, 300 t A 0.2 kt experimental device that used uranium-233; exact locations of sites is unknown. Shakti 2 - 3 (canceled) 13 May
List of nuclear weapons tests of India
List_of_nuclear_weapons_tests_of_India
International agreement on the nuclear program of Iran
are uranium 235 (235 U) and plutonium 239 (239 Pu). Both uranium 233 (233 U) and reactor-grade plutonium have also been used. The amount of uranium or
Iran_nuclear_deal
American nuclear physicist (1915–2006)
contamination by plutonium-240 led Wigner to propose switching to breeding uranium-233 from thorium, but the challenge was met by the Los Alamos Laboratory
Alvin_M._Weinberg
British contribution to the WWII atomic bomb project
possible alternative, as it could be irradiated to produce uranium-233, another isotope of uranium suitable for making atomic bombs. In December 1943, Groves
British contribution to the Manhattan Project
British_contribution_to_the_Manhattan_Project
Chemical element with atomic number 93 (Np)
named after Neptune, the planet beyond Uranus in the Solar System, which uranium is named after. A neptunium atom has 93 protons and 93 electrons, of which
Neptunium
Indian nuclear physicist (born 1943)
engage in designing the Advanced Heavy Water Reactor, that uses thorium-uranium 233 as the primary energy source with plutonium as the driver fuel. The unique
Anil_Kakodkar
Component of nuclear fission or fusion reactors
thorium-232, ultimately producing uranium-233: Th 90 232 + 0 1 n → (n, γ ) Th 90 233 → 21.8 min β − Pa 91 233 → 27 days β − U 92 233 {\displaystyle {\ce
Breeding_blanket
Type of nuclear reactor cooled by molten sodium
construction of commercial SFR plants that can breed fissile plutonium and uranium-233 for use in heavy-water reactors. The experimental Fast Breeder Test Reactor
Sodium-cooled_fast_reactor
2010 book by Sam Kean
poisonous elements mentioned, such as David Hahn who tried to create Uranium-233 in his backyard with the lithium from batteries and thorium and was soon
The_Disappearing_Spoon
Nuclear bomb
conducted using a Mk7 warhead using an experimental composite plutonium/uranium-233 pit, producing a 22kt yield, 33% lower than expected. As Shot MET was
Mark_7_nuclear_bomb
S2CID 257976576. Yirka, Bob (April 5, 2023). "Previously unknown isotope of uranium discovered". Phys.org. Retrieved 2023-04-12. Radiation, UAB.
List of radioactive nuclides by half-life
List_of_radioactive_nuclides_by_half-life
Nuclear weapon component
of initiating a predetonation. Tungsten carbide was commonly used in uranium-233 gun-type nuclear weapons used with artillery pieces for the same reason
Tamper_(nuclear_weapon)
Chemical compound
"Simultaneous voltammetric generation of uranium(III) and spectrophotometric observation of the uranium(III)-uranium(IV) system in molten lithium fluoride-beryllum
FLiBe
Nuclear power safety method that does not require electrical power nor intervention
moderated and the coolant salt used was FLiBe, which also carried the uranium-233 fluoride fuel dissolved in it. The MSRE had a negative temperature coefficient
Passive_nuclear_safety
Long-lived radioisotope of selenium
20 times the yield of 79Se in the case of uranium-235, 6 times in the case of plutonium-239 or uranium-233, and 14 times in the case of plutonium-241
Selenium-79
Environmental contamination by nuclear weapons production
of plutonium, americium, and uranium were detected, with the highest measured activity being 0.0125 pCi/g of uranium-233, 234. The study found that the
Radioactive contamination from the Rocky Flats Plant
Radioactive_contamination_from_the_Rocky_Flats_Plant
Former air-cooled graphite-moderated nuclear reactors
available was natural uranium, since there were no enrichment plants to produce uranium-235, and no reactors to produce plutonium or uranium-233. This restricted
Windscale_Piles
Ongoing debate on whether nuclear power is renewable
converting fertile materials, such as uranium-238 and thorium, into fissile isotopes of plutonium or uranium-233, respectively. Fertile materials are also
Nuclear power proposed as renewable energy
Nuclear_power_proposed_as_renewable_energy
Nuclear fuel that has been irradiated in a nuclear reactor
are fissioned, or "burnt", in the reactor. A fresh rod of low-enriched uranium pellets (which can be safely handled with gloved hands) will become a highly
Spent_nuclear_fuel
nuclear material detection: Special nuclear materials (SNM) such as uranium-233 and plutonium-239 decay by spontaneous fission, yielding neutrons. Neutrons
Neutron_detection
does not violate the accepted definition. Definition of Weapons-Usable Uranium-233 Archived 15 January 2010 at the Wayback Machine, C.W. Forsberg et al
Iran and weapons of mass destruction
Iran_and_weapons_of_mass_destruction
Type of nuclear reactor cooled by a gas
nuclear fuel such as uranium, other fuels can be used. The most common is thorium, which absorbs a fast neutron and decays into uranium-233. This means GFR
Gas-cooled_fast_reactor
materials are uranium-235 and uranium-233. 239Pu is virtually nonexistent in nature. It is made by bombarding uranium-238 with neutrons. Uranium-238 is present
Isotopes_of_plutonium
British nuclear weapons research group, 1940–1941
theorising that irradiation of thorium could produce a new isotope of uranium, uranium-233, which might also be susceptible to fission by both fast and slow
MAUD_Committee
Nuclear fusion process
fissile fuels from fertile material – for example, thorium-232 could breed uranium-233 in this way. The fissile fuels that have been bred can then be "burned
Muon-catalyzed_fusion
URANIUM 233
URANIUM 233
Girl/Female
Greek
Heavenly.
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.
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."
Girl/Female
Australian, British, Christian, English, French, German, Greek, Italian, Portuguese
Heavenly; Muse of Astronomy
Boy/Male
Greek
Sky.
Girl/Female
Muslim
Great, Famous, Peace protector (1)
Surname or Lastname
English
English : variant spelling of Francom.
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
Indian
Great, Famous, Peace protector
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.
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.
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.
Female
German
German form of Roman Latin Porcius, PORSCHE means "pig." A moon of Uranus was given this name.
Female
English
English Shakespeare character name derived from Roman Latin Porcius, PORTIA means "pig." A moon of Uranus was given this name.
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
Female
Hebrew
(×ï¬µ×¨Ö¸× Ö´×™×ª) Hebrew name URANIT means "light."
Girl/Female
Greek
Crane.
Girl/Female
Arabic, Australian, Muslim
To Recite in a Sing Song Voice
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).
URANIUM 233
URANIUM 233
Boy/Male
Indian
Courier of the truth i.e. Allah
Boy/Male
British, English
From the Old Town
Surname or Lastname
English (chiefly Bristol)
English (chiefly Bristol) : patronymic from Hiscock.
Boy/Male
Arabic
Obedient; Submissive
Girl/Female
Indian
Unconquerable; Mirror
Girl/Female
Hindu, Indian
Knowledgeable; Inspired; Intuitive; Creative
Boy/Male
Arabic, Muslim
Slave of the Giver
Girl/Female
Indian
River Yamuna, Success
Girl/Female
Arabic, Muslim
Spirituality
Girl/Female
Hebrew
Bitter.
URANIUM 233
URANIUM 233
URANIUM 233
URANIUM 233
URANIUM 233
n.
The dove's-foot geranium (Geranium molle).
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 planet Uranus; as, the Uranian year.
n.
A general term for the uranium phosphates, autunite, or lime uranite, and torbernite, or copper uranite.
a.
A combining form (also used adjectively) from uranium; -- used in naming certain complex compounds; as in uranoso-uranic oxide, uranoso-uranic sulphate.
pl.
of Bucranium
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.
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.
n.
Scientific examination of the cranium.
a.
Within the cranium or skull.
pl.
of Cranium
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.
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.
The contents of the cranium; the brain.
a.
Of or pertaining to uranium; containing uranium.
n.
The periosteum which covers the cranium externally; the region around the cranium.
n.
The bony cranium, as distinguished from the cartilaginous cranium.
a.
Pertaining to, or containing, uranium; designating those compounds in which uranium has a lower valence as contrasted with the uranic compounds.
a.
Of or pertaining to the cranium.
pl.
of Cranium