Caesium or cesium[note 1] ( /ˈsiːziəm/ SEE-zee-əm) is the chemical element with the symbol Cs
and atomic number 55. It is a soft, silvery-gold alkali metal with a
melting point of 28 °C (82 °F), which makes it one of only five
elemental metals that are liquid at (or near) room temperature.[note 2]
Caesium is an alkali metal and has physical and chemical properties
similar to those of rubidium and potassium. The metal is extremely
reactive and pyrophoric, reacting with water even at −116 °C (−177 °F).
It is the least electronegative element that has stable isotopes, of
which it has only one, caesium-133. Caesium is mined mostly from
pollucite, while the radioisotopes, especially caesium-137, are
extracted from waste produced by nuclear reactors.
Two German
chemists, Robert Bunsen and Gustav Kirchhoff, discovered caesium in 1860
by the newly developed method of flame spectroscopy. The first
small-scale applications for caesium have been as a "getter" in vacuum
tubes and in photoelectric cells. In 1967, a specific frequency from the
emission spectrum of caesium-133 was chosen to be used in the
definition of the second by the International System of Units. Since
then, caesium has been widely used in atomic clocks.
Since the
1990s, the largest application of the element has been as caesium
formate for drilling fluids. It has a range of applications in the
production of electricity, in electronics, and in chemistry. The
radioactive isotope caesium-137 has a half-life of about 30 years and
is used in medical applications, industrial gauges, and hydrology.
Although the element is only mildly toxic, it is a hazardous material
as a metal and its radioisotopes present a high health risk in case of
radiation leaks.
Contents
[hide]
- 1 Characteristics
- 1.1 Physical properties
- 1.2 Chemical properties
- 1.3 Compounds
- 1.3.1 Complexes
- 1.3.2 Halides
- 1.3.3 Oxides
- 1.4 Isotopes
- 1.5 Occurrence
- 2 Production
- 3 History
- 4 Applications
- 4.1 Petroleum exploration
- 4.2 Atomic clocks
- 4.3 Electric power and electronics
- 4.4 Centrifugation fluids
- 4.5 Chemical and medical use
- 4.6 Nuclear and isotope applications
- 4.7 Other uses
- 4.8 Prognostications
- 5 Health and safety hazards
- 6 See also
- 7 Notes
- 8 References
- 9 External links
[edit] Characteristics
[edit] Physical properties
High-purity caesium-133 preserved under argon
Caesium
is a very soft (it has the lowest Mohs hardness of all elements), very
ductile, silvery-white metal, which develops a silvery-gold hue in the
presence of trace amounts of oxygen.[6][7] It has a melting point of
28.4 °C (83.1 °F), making it one of the few elemental metals which are
liquid near room temperature. Mercury is the only metal with a known
melting point lower than caesium.[note 3][9] In addition, the metal has a
rather low boiling point, 641 °C (1,186 °F), the lowest of all metals
other than mercury.[10] Its compounds burn with a blue color.[11]
Caesium
forms alloys with the other alkali metals as well as with gold, and
amalgams with mercury. At temperatures below 650 °C (1,202 °F), it
alloys with cobalt, iron, molybdenum, nickel, platinum, tantalum or
tungsten. It forms well-defined intermetallic compounds with antimony,
gallium, indium and thorium, which are photosensitive.[6] It mixes with
the other alkali metals (except with lithium), and the alloy with a
molar distribution of 41% caesium, 47% potassium, and 12% sodium has the
lowest melting point of any known metal alloy, at −78 °C
(−108 °F).[9][12] A few amalgams have been studied: CsHg2 is black with a
purple metallic lustre, while CsHg is golden-coloured, also with a
metallic lustre.[13]
[edit] Chemical properties
Addition of a small amount of caesium to cold water is explosive.
Caesium
metal is highly reactive and very pyrophoric. In addition to igniting
spontaneously in air, it reacts explosively with water even at low
temperatures, more so than other members of the first group of the
periodic table.[6] The reaction with solid water occurs at temperatures
as low as −116 °C (−177 °F).[9] Because of its high reactivity, the
metal is classified as a hazardous material. It is stored and shipped in
dry saturated hydrocarbons such as mineral oil. Similarly, it must be
handled under inert atmosphere such as argon or nitrogen. It can be
stored in vacuum-sealed borosilicate glass ampoules. In quantities of
more than about 100 grams (3.5 oz), caesium is shipped in hermetically
sealed stainless steel containers.[6]
The chemistry of caesium is
similar to that of other alkali metals, but is more closely similar to
that of rubidium, the element above caesium in the periodic table.[14]
Some small differences arise from the fact that it has a higher atomic
mass and is more electropositive than other (non-radioactive) alkali
metals.[15] Caesium is the most electropositive stable chemical
element.[note 4][9] The caesium ion is also larger and less "hard" than
those of the lighter alkali metals.
[edit] Compounds
Ball-and-stick model of the cubic coordination of Cs and Cl in CsCl
The vast majority of caesium compounds contain the element as the cation Cs+
, which binds ionically to a wide variety of anions. One noteworthy exception is provided by the caeside anion (Cs−
).[17] Other exceptions include the several suboxides (see section on oxides below).
Returning
to more normal compounds, salts of Cs+ are almost invariably colorless
unless the anion itself is colored. Many of the simple salts are
hygroscopic, but less so than the corresponding salts of the lighter
alkali metals. The acetate, carbonate, halides, oxide, nitrate, and
sulfate salts are water-soluble. Double salts are often less soluble,
and the low solubility of cesium aluminum sulfate is exploited in the
purification of Cs from its ores. The double salt with antimony (such
as CsSbCl4), bismuth, cadmium, copper, iron, and lead are also poorly
soluble.[6]
Caesium hydroxide (CsOH) is hygroscopic and a very
strong base.[14] It rapidly etches the surface of semiconductors such as
silicon.[18] CsOH has been previously regarded by chemists as the
"strongest base", reflecting the relatively weak attraction between the
large Cs+ ion and OH-.[11] Many compounds are far more basic than CsOH,
such as n-butyllithium and sodium amide.[14]
[edit] Complexes
Like
all metal cations, Cs+ forms complexes with Lewis bases in solution.
Because of its large size, Cs+ usually adopts coordination numbers
greater than six-coordination, which is typical for the lighter alkali
metal cations. This trend is already apparent by the 8-coordination in
CsCl, vs the halite motif adopted by the other alkali metal chlorides.
Its high coordination number and softness (tendency to form covalent
bonds) are the basis of the separation of Cs+ from other cations, as is
practiced in the remediation of nuclear wastes, where 137Cs+ is
separated from large amounts of non-radioactive K+.[19]
[edit] Halides
Caesium
chloride (CsCl) crystallizes in the simple cubic crystal system. Also
called the "caesium chloride structure",[15] this structural motif is
composed of a primitive cubic lattice with a two-atom basis, each with
an eightfold coordination; the chloride atoms lie upon the lattice
points at the edges of the cube, while the caesium atoms lie in the
holes in the center of the cubes. This structure is shared with CsBr
and CsI, and many other compounds that do not contain Cs. In contrast,
most other alkaline halides adopt the sodium chloride (NaCl)
structure.[15] The CsCl structure is preferred because Cs+ has an ionic
radius of 174 pm and Cl−
181 pm.[20]
[edit] Oxides
Cs11O3 cluster
More
so than the other alkali metals, caesium forms numerous binary
compounds with oxygen. When caesium burns in air, the superoxide CsO2 is
the main product.[21] The "normal" caesium oxide (Cs2O) forms
yellow-orange hexagonal crystals,[22] and is the only oxide of the
anti-CdCl2 type.[23] It vaporizes at 250 °C (482 °F), and decomposes to
caesium metal and the peroxide Cs2O2 at temperatures above 400 °C
(752 °F).[24] Aside from the superoxide and the ozonide CsO3,[25][26]
several brightly colored suboxides have also been studied.[27] These
include Cs7O, Cs4O, Cs11O3, Cs3O (dark-green[28]), CsO, Cs3O2,[29] as
well as Cs7O2.[30][31] The latter may be heated under vacuum to generate
Cs2O.[23] Binary compounds with sulfur, selenium, and tellurium also
exist.[6]
[edit] Isotopes
Main article: Isotopes of caesium
Caesium
has a total of 39 known isotopes that range in their mass number (i.e.
number of nucleons in its nucleus) from 112 to 151. Several of these are
synthesized from lighter elements by the slow neutron capture process
(S-process) inside old stars,[32] as well as inside supernova explosions
(R-process).[33] However, the only stable isotope is 133Cs, which has
78 neutrons. Although it has a large nuclear spin (7/2+), nuclear
magnetic resonance studies can be done with this isotope at a resonating
frequency of 11.7 MHz.[34]
Decay of caesium-137
The
radioactive 135Cs has a very long half-life of about 2.3 million years,
while 137Cs and 134Cs have half-lives of 30 and 2 years, respectively.
137Cs decomposes to a short-lived 137mBa by beta decay, and then to
non-radioactive barium, while 134Cs transforms into 134Ba directly. The
isotopes with mass numbers of 129, 131, 132 and 136, have half-times
between a day and two weeks, while most of the other isotopes have
half-lives from a few seconds to fractions of a second. There are at
least 21 metastable nuclear isomers. Other than 134mCs (with a half-life
of just under 3 hours), all are very unstable and decay with half-lives
of a few minutes or less.[35][36]
The isotope 135Cs is one of
medium-lived fission products of uranium which form in nuclear
reactors.[37] However, its fission product yield is reduced in most
reactors because its predecessor, 135Xe, is an extremely potent neutron
poison and transmutes frequently to stable 136Xe before it can decay to
135Cs.[38][39]
Because of its beta decay (to 137mBa), 137Cs is a
strong emitter of gamma radiation.[40] Its half-life makes it the
principal long-lived fission product along with 90Sr—both are
responsible for radioactivity of spent nuclear fuel after several years
of cooling up to several hundred years after use.[41] For example 137Cs
together with 90Sr currently generate the largest source of
radioactivity generated in the area around the Chernobyl disaster.[42]
It is not feasible to dispose of 137Cs through neutron capture (due to
the low capture rate) and as a result it must be allowed to decay.[43]
Almost
all caesium produced from nuclear fission comes from beta decay of
originally more neutron-rich fission products, passing through various
isotopes of iodine and of xenon.[44] Because iodine and xenon are
volatile and can diffuse through nuclear fuel or air, radioactive
caesium is often created far from the original site of fission.[45]
With the commencement of nuclear weapons testing around 1945, 137Cs was
released into the atmosphere and then returned to the surface of the
earth as a component of radioactive fallout.[6]
[edit] Occurrence
Pollucite, a caesium mineral
See also: Caesium minerals
Caesium
is a relatively rare element as it is estimated to average
approximately 3 parts per million in the Earth’s crust.[46] This makes
it the 45th most abundant of all elements and the 36th of all the
metals. Nevertheless, it is more abundant than such elements as
antimony, cadmium, tin and tungsten, and two orders of magnitude more
abundant than mercury or silver, but 30 times less abundant than
rubidium—with which it is so closely chemically associated.[6]
Due
to its large ionic radius, caesium is one of the "incompatible
elements."[47] During magma crystallization, caesium is concentrated in
the liquid phase and crystallizes last. Therefore the largest deposits
of caesium are zone pegmatite ore bodies formed by this enrichment
process. Because caesium does not substitute for potassium as readily as
does rubidium, the alkali evaporite minerals sylvite (KCl) and
carnallite (KMgCl3·6H2O) may contain only 0.002% caesium. Consequently,
Cs is found in few minerals. Percent amounts of caesium may be found in
beryl (Be3Al2(SiO3)6) and avogadrite ((K,Cs)BF4), up to 15 wt% Cs2O in
the closely related mineral pezzottaite (Cs(Be2Li)Al2Si6O18), up to
8.4 wt% Cs2O in the rare mineral londonite ((Cs,K)Al4Be4(B,Be)12O28),
and less in the more widespread rhodizite.[6] The only economically
important source mineral for caesium is pollucite Cs(AlSi2O6), which is
found in a few places around the world in zoned pegmatites, and is
associated with the more commercially important lithium minerals
lepidolite and petalite. Within the pegmatites, the large grain size and
the strong separation of the minerals create high-grade ore for
mining.[48]
One of the world's most significant and richest
sources of the metal is the Tanco mine at Bernic Lake in Manitoba,
Canada. The deposits there are estimated to contain 350,000 metric tons
of pollucite ore, which represents more than two-thirds of the world’s
reserve base.[48][49] Although the stoichiometric content of caesium in
pollucite is 42.6%, pure pollucite samples from this deposit contain
only about 34% caesium, while the average content is 24 wt%.[49]
Commercial pollucite contains over 19% caesium.[50] The Bikita pegmatite
deposit in Zimbabwe is mined for its petalite but it also contains a
significant amount of pollucite. Notable amounts of pollucite are also
mined in the Karibib Desert, Namibia.[49] At the present rate of world
mine production of 5 to 10 metric tons per year, reserves will last
thousands of years.[6]
[edit] Production
The
mining of pollucite ore is a selective process and is conducted on a
small scale in comparison with most metal mining operations. The ore is
crushed, hand-sorted, but not usually concentrated, and then ground.
Caesium is then extracted from pollucite mainly by three methods: acid
digestion, alkaline decomposition, and direct reduction.[6][51]
In
the acid digestion, the silicate pollucite rock is dissolved with
strong acids such as hydrochloric (HCl), sulfuric (H2SO4), hydrobromic
(HBr), or hydrofluoric (HF). With hydrochloric acid, a mixture of
soluble chlorides is produced, and the insoluble chloride double salts
of caesium are precipitated as caesium antimony chloride (Cs4SbCl7),
caesium iodine chloride (Cs2ICl), or caesium hexachlorocerate
(Cs2(CeCl6)). After separation, the pure precipitated double salt is
decomposed, and pure CsCl is obtained after evaporating the water. The
method using sulfuric acid yields the insoluble double salt directly as
caesium alum (CsAl(SO4)2·12H2O). The aluminium sulfate in it is
converted to the insoluble aluminium oxide by roasting the alum with
carbon, and the resulting product is leached with water to yield a
Cs2SO4 solution.[6]
The roasting of pollucite with calcium
carbonate and calcium chloride yields insoluble calcium silicates and
soluble caesium chloride. Leaching with water or dilute ammonia (NH4OH)
yields then a dilute chloride (CsCl) solution. This solution can be
evaporated to produce caesium chloride or transformed into caesium alum
or caesium carbonate. Albeit not commercially feasible, direct
reduction of the ore with potassium, sodium or calcium in vacuum can
produce caesium metal directly.[6]
Most of the mined caesium (as
salts) is directly converted into caesium formate (HCOO−Cs+) for
applications such as oil drilling. To supply the developing market,
Cabot Corporation built a production plant in 1997 at the Tanco Mine
near Bernic Lake in Manitoba, Canada, with a capacity of 12,000 barrels
per year of caesium formate solution.[52] The primary smaller-scale
commercial compounds of caesium are caesium chloride and its
nitrate.[53]
Alternatively, caesium metal may be obtained from the
purified compounds derived from the ore. Caesium chloride, and the
other caesium halides as well, can be reduced at 700 to 800 °C
(1,292 to 1,472 °F) with calcium or barium, followed by distillation of
the caesium metal. In the same way, the aluminate, carbonate, or
hydroxide may be reduced by magnesium.[6] The metal can also be isolated
by electrolysis of fused caesium cyanide (CsCN). Exceptionally pure and
gas-free caesium can be made by the thermal decomposition at 390 °C
(734 °F) of caesium azide CsN3, which is produced from aqueous caesium
sulfate and barium azide.[51] In vacuum applications, caesium dichromate
can be reacted with zirconium forming pure caesium metal without other
gaseous products.[53]
Cs2Cr2O7 + 2 Zr → 2 Cs + 2 ZrO2+ Cr2O3
The
price of 99.8% pure caesium (metal basis) in 2009 was about US$10 per
gram ($280 per ounce), but its compounds are significantly cheaper.[49]
[edit] History
Gustav Kirchhoff (left) and Robert Bunsen (center) discovered caesium spectroscopically.
In
1860, Robert Bunsen and Gustav Kirchhoff discovered caesium in the
mineral water from Dürkheim, Germany. Due to the bright blue lines in
its emission spectrum, they chose a name derived from the Latin word caesius,
meaning sky-blue.[note 5][54][55][56] Caesium was the first element to
be discovered spectroscopically, only one year after the invention of
the spectroscope by Bunsen and Kirchhoff.[9]
To obtain a pure
sample of caesium, 44,000 litres (9,700 imp gal; 12,000 US gal) of
mineral water had to be evaporated to yield 240 kilograms (530 lb) of
concentrated salt solution. The alkaline earth metals were precipitated
either as sulfates or oxalates, leaving the alkali metal in the
solution. After conversion to the nitrates and extraction with ethanol, a
sodium-free mixture was obtained. From this mixture, the lithium was
precipitated by ammonium carbonate. Potassium, rubidium and caesium form
insoluble salts with chloroplatinic acid, but these salts show a
slight difference in solubility in hot water. Therefore, the
less-soluble caesium and rubidium hexachloroplatinate ((Cs,Rb)2PtCl6)
could be obtained by fractional crystallization. After reduction of the
hexachloroplatinate with hydrogen, caesium and rubidium could be
separated by the difference in solubility of their carbonates in
alcohol. The process yielded 9.2 grams (0.32 oz) of rubidium chloride
and 7.3 grams (0.26 oz) of caesium chloride from the initial
44,000 liters of mineral water.[55]
The two scientists used the
caesium chloride thus obtained to estimate the atomic weight of the new
element at 123.35 (compared to the currently accepted one of 132.9).[55]
They tried to generate elemental caesium by electrolysis of molten
caesium chloride, but instead of a metal, they obtained a blue
homogenous substance which "neither under the naked eye nor under the
microscope" showed the slightest trace of metallic substance;" as a
result, they assigned it as a subchloride (Cs2Cl). In reality, the
product was probably a colloidal mixture of the metal and caesium
chloride.[57] The electrolysis of the aqueous solution of chloride with
a mercury anode produced a caesium amalgam which readily decomposed
under the aqueous conditions.[55] The pure metal was eventually
isolated by the German chemist Carl Setterberg while working on his
doctorate with Kekule and Bunsen.[56] In 1882 he produced caesium metal
by electrolyzing caesium cyanide, and thus avoiding the problems with
the chloride.[58]
Historically, the most important use for caesium
has been in research and development, primarily in chemical and
electrical fields. Very few applications existed for caesium until the
1920s when it became used in radio vacuum tubes. It had two functions:
as a getter it removed excess oxygen after manufacture, and as a coating
on the heated cathode, it increased its electrical conductivity.
Caesium did not become recognized as a high-performance industrial metal
until the 1950s.[59] Applications of non-radioactive caesium included
photoelectric cells, photomultiplier tubes, optical components of
infrared spectrophotometers, catalysts for several organic reactions,
crystals for scintillation counters, and in magnetohydrodynamic power
generators.[6]
Since 1967, the International System of
Measurements has based its unit of time, the second, on the properties
of caesium. The International System of Units (SI) defines the second as
9,192,631,770 cycles of the radiation, which corresponds to the
transition between two hyperfine energy levels of the ground state of
the caesium-133 atom.[60] The 13th General Conference on Weights and
Measures of 1967 defined a second as: "the duration of 9,192,631,770
cycles of microwave light absorbed or emitted by the hyperfine
transition of caesium-133 atoms in their ground state undisturbed by
external fields".
[edit] Applications
[edit] Petroleum exploration
The largest current end-use of caesium is in caesium formate-based drilling fluids for the extractive oil industry.[citation needed]
Aqueous solutions of caesium formate (HCOO-Cs+)—made by reacting
caesium hydroxide with formic acid—were developed in the mid-1990s for
use as oil well drilling and completion fluids. The function of caesium
formate as a drilling fluid is to lubricate drill bits, to bring rock
cuttings to the surface, and to maintain pressure on the formation
during drilling of the well; as completion fluid (which refers to the
emplacement of control hardware after drilling but prior to production)
is to maintain the pressure.[6]
The high density of the caesium
formate brine (up to 2.3 g·cm−3, or 19.2 pounds per gallon),[61]
coupled with the relatively benign nature of most caesium compounds,
reduces the requirement for toxic high-density suspended solids in the
drilling fluid—a significant technological, engineering and
environmental advantage. Unlike the components of many other heavy
liquids, caesium formate is relatively environment-friendly.[61] The
caesium formate brine can be blended with potassium and sodium formates
to decrease the density of the fluids down to that of water
(1.0 g·cm−3, or 8.3 pounds per gallon). Furthermore, it is
biodegradable and reclaimable, and may be recycled, which is important
in view of its high cost (about $4,000 per barrel in 2001).[62] Alkali
formates are safe to handle and do not damage the producing formation
or downhole metals as their corrosive alternative, high-density brines
(such as zinc bromide ZnBr2 solutions),sometimes do; they also require
less cleanup and disposal costs.[6]
[edit] Atomic clocks
Atomic clock ensemble at the U.S. Naval Observatory
FOCS-1,
a continuous cold caesium fountain atomic clock in Switzerland,
started operating in 2004 at an uncertainty of one second in 30 million
years
Caesium-based atomic clocks observe electromagnetic
transitions in the hyperfine structure of caesium-133 atoms and use it
as a reference point. The first accurate caesium clock was built by
Louis Essen in 1955 at the National Physical Laboratory in the UK.[63]
Since then, they have been improved repeatedly over the past
half-century, and form the basis for standards-compliant time and
frequency measurements. These clocks measure frequency with an accuracy
of 2 to 3 parts in 1014, which would correspond to a time measurement
accuracy of 2 nanoseconds per day, or one second in 1.4 million years.
The latest versions in the United States and France are accurate to
1.7 parts in 1015, which means they would be off by about 4 seconds
since the extinction of the dinosaurs 65 million years ago,[6] and has
been regarded as "the most accurate realization of a unit that mankind
has yet achieved."[60]
Caesium clocks are also used in networks
that oversee the timing of cell phone transmissions and the information
flow on the Internet.[64]
[edit] Electric power and electronics
Caesium
vapor thermionic generators are low-power devices that convert heat
energy to electrical energy. In the two-electrode vacuum tube converter,
it neutralizes the space charge that builds up near the cathode, and in
doing so, it enhances the current flow.[65]
Caesium is also
important for its photoemissive properties by which light energy is
converted to electron flow. It is used in photoelectric cells because
caesium-based cathodes such as the intermetallic compound K2CsSb have
low threshold voltage for emission of electrons.[66] The range of
photoemissive devices using caesium include optical character
recognition devices, photomultiplier tubes, and video camera
tubes.[67][68] Nevertheless, germanium, rubidium, selenium, silicon,
tellurium, and several other elements can substitute caesium in
photosensitive materials.[6]
Caesium iodide (CsI), bromide (CsBr)
and caesium fluoride (CsF) crystals are employed for scintillators in
scintillation counters widely used in mineral exploration and particle
physics research as they are well suited for the detection of gamma and
x-ray radiation. Caesium, being a heavy element, provides good stopping
power contributing to better detectivity. Caesium compounds may also
provide a faster response (CsF) and be less hygroscopic (CsI).
Caesium
vapor is used in many common magnetometers.[69] The element is also
used as an internal standard in spectrophotometry.[70] Like other alkali
metals, caesium has a great affinity for oxygen and is used as a
"getter" in vacuum tubes.[71] Other uses of the metal include
high-energy lasers, vapor glow lamps, and vapor rectifiers.[6]
[edit] Centrifugation fluids
Because
of their high density, solutions of caesium chloride (CsCl), sulfate
(Cs2SO4), and trifluoroacetate (Cs(O2CCF3)) are commonly used in
molecular biology for density gradient ultracentrifugation.[72] This
technology is primarily applied to the isolation of viral particles,
sub-cellular organelles and fractions, and nucleic acids from biological
samples.[73]
[edit] Chemical and medical use
A sample of caesium chloride
Relatively
few chemical applications exist for caesium.[74] Doping with caesium
compounds is used to enhance the effectiveness of several metal-ion
catalysts used in the production of chemicals, such as acrylic acid,
anthraquinone, ethylene oxide, methanol, phthalic anhydride, styrene,
methyl methacrylate monomers, and various olefins. It is also used in
the catalytic conversion of sulfur dioxide into sulfur trioxide in the
production of sulfuric acid.[citation needed]
Caesium
fluoride enjoys niche use in organic chemistry as a base,[14] or as an
anhydrous source of fluoride ion.[75] Caesium salts sometimes replace
potassium or sodium salts in organic synthesis, such as cyclization,
esterification, and polymerization.
[edit] Nuclear and isotope applications
Caesium-137
is a very common radioisotope used as a gamma-emitter in industrial
applications. Its advantages include a half-life of roughly 30 years,
its availability from the nuclear fuel cycle, and having 137Ba as
stable end product. The high water solubility is a disadvantage which
makes it incompatible with irradiation of food and medical
supplies.[76] It has been used in agriculture, cancer treatment, and the
sterilization of food, sewage sludge, and surgical equipment.[6][77]
Radioactive isotopes of caesium in radiation devices were used in the
medical field to treat certain types of cancer,[78] but emergence of
better alternatives and the use of water-soluble caesium chloride in
the sources, which could create wide-ranging contamination, gradually
put some of these caesium sources out of use.[79][80] Caesium-137 has
been employed in a variety of industrial measurement gauges, including
moisture, density, leveling, and thickness gauges.[81] It has also been
used in well logging devices for measuring the electron density of the
rock formations, which is analogous to the bulk density of the
formations.[82]
Isotope 137 has also been used in hydrologic
studies analogous to those using tritium. It is produced from detonation
of nuclear weapons and emissions from nuclear power plants. With the
commencement of nuclear testing around 1945, and continuing through the
mid-1980s, caesium-137 was released into the atmosphere where it is
absorbed readily into solution. Known year-to-year variation within
that period allows correlation with soil and sediment layers.
Caesium-134, and to a lesser extent caesium-135, have also been used in
hydrology as a measure of caesium output by the nuclear power
industry. While they are less prevalent than either caesium-133 or
caesium-137, these isotopes have the advantage of being produced solely
from anthropogenic sources.[83]
[edit] Other uses
Schematics of an electrostatic ion thruster which was initially developed for use with caesium or mercury
Caesium
and mercury were used as a propellant in early ion engines designed for
spacecraft propulsion on very long interplanetary or extraplanetary
missions. The ionization method was to strip the outer electron from
the propellant upon contact with a tungsten electrode that had voltage
applied. Concerns about the corrosive action of caesium on spacecraft
components have pushed development in the direction of use of inert gas
propellants such as xenon; this is easier to handle in ground-based
tests and has less potential to interfere with the spacecraft.[6]
Eventually, xenon was used in the experimental spacecraft Deep Space 1
launched in 1998.[84][85] Nevertheless, field emission electric
propulsion thrusters which use a simple system of accelerating liquid
metal ions such as of caesium to create thrust have been built.[86]
Caesium
nitrate is used as an oxidizer and pyrotechnic colorant to burn silicon
in infrared flares[87] such as the LUU-19 flare,[88] because it emits
much of its light in the near infrared spectrum.[89] Caesium has been
used to reduce the radar signature of exhaust plumes in the SR-71
Blackbird military aircraft.[90] Caesium, along with rubidium, has been
added as a carbonate to glass because it reduces electrical conductivity
and improves stability and durability of fiber optics and night vision
devices. Caesium fluoride or caesium aluminium fluoride are used in
fluxes formulated for the brazing of aluminium alloys that contain
magnesium.[6]
[edit] Prognostications
Magnetohydrodynamic
(MHD) power-generating systems were researched but failed to gain
widespread acceptance.[91] Caesium metal has also been considered as the
working fluid in high-temperature Rankine cycle turboelectric
generators.[92] Caesium salts have been evaluated as antishock reagents
to be used following the administration of arsenical drugs. Because of
their effect on heart rhythms, however, they are less likely to be used
than potassium or rubidium salts. They have also been used to treat
epilepsy.[6]
[edit] Health and safety hazards
The
portion of the total radiation dose (in air) contributed by each
isotope versus time after the Chernobyl disaster depicting caesium-137
becoming the largest source of radiation about 200 days after the
accident.[93]
Caesium compounds are rarely encountered by most
people, but most caesium compounds are mildly toxic because of chemical
similarity of caesium to potassium. Exposure to large amounts of
caesium compounds can cause hyperirritability and spasms, but as such
amounts would not ordinarily be encountered in natural sources, caesium
is not a major chemical environmental pollutant.[94] The median lethal
dose (LD50) value for caesium chloride in mice is 2.3 g per kilogram,
which is comparable to the LD50 values of potassium chloride and sodium
chloride.[95]
NFPA 704
3
3
2
W
The fire diamond hazard sign for caesium metal
Caesium
metal is one of the most reactive elements and is highly explosive when
it comes in contact with water. The hydrogen gas produced by the
reaction is heated by the thermal energy released at the same time,
causing ignition and a violent explosion. This can occur with other
alkali metals, but caesium is so potent that this explosive reaction
can even be triggered by cold water.[6] The metal is highly pyrophoric,
and ignites spontaneously in air to form caesium hydroxide and various
oxides. Caesium hydroxide is a very strong base, and can rapidly corrode
glass.[10]
The isotopes 134 and 137 (present in the biosphere in
small amounts from radiation leaks) represent a radioactivity burden
which varies depending on location. Radiocaesium does not accumulate in
the body as effectively as many other fission products (such as
radioiodine and radiostrontium). As with other alkali metals,
radiocaesium washes out of the body relatively quickly in sweat and
urine. However, radiocaesium follows potassium and tends to accumulate
in plant tissues, including fruits and vegetables.[96][97][98]
Accumulation of caesium-137 in lakes has been a high concern after the
Chernobyl disaster.[99][100] Experiments with dogs showed that a single
dose of 3800 μCi (4.1 μg of caesium-137) per kilogram is lethal within
three weeks;[101] smaller amounts may cause infertility and cancer.[102]
The International Atomic Energy Agency and other sources have warned
that radioactive materials, such as caesium-137, could be used in
radiological dispersion devices, or “dirty bombs”.[
引用出處:
http://en.wikipedia.org/wiki/Caesium
歡迎來到Bewise Inc.的世界,首先恭喜您來到這接受新的資訊讓產業更有競爭力,我們是提供專業刀具製造商,應對客戶高品質的刀具需求,我們可以協助客戶滿足您對產業的不同要求,我們有能力達到非常卓越的客戶需求品質,這是現有相關技術無法比擬的,我們成功的滿足了各行各業的要求,包括:精密HSS DIN切削刀具、協助客戶設計刀具流程、DIN or JIS 鎢鋼切削刀具設計、NAS986 NAS965 NAS897 NAS937orNAS907 航太切削刀具,NAS航太刀具設計、超高硬度的切削刀具、醫療配件刀具設計、複合式再研磨機、PCD地板專用企口鑽石組合刀具、粉末造粒成型機、主機版專用頂級電桿、PCD V-Cut刀、捨棄式圓鋸片組、粉末成型機、航空機械鉸刀、主機版專用頂級電感、’汽車業刀具設計、電子產業鑽石刀具、木工產業鑽石刀具、銑刀與切斷複合再研磨機、銑刀與鑽頭複合再研磨機、銑刀與螺絲攻複合再研磨機等等。我們的產品涵蓋了從民生刀具到工業級的刀具設計;從微細刀具到大型刀具;從小型生產到大型量產;全自動整合;我們的技術可提供您連續生產的效能,我們整體的服務及卓越的技術,恭迎您親自體驗!!
BW Bewise Inc. Willy Chen willy@tool-tool.com bw@tool-tool.com www.tool-tool.com
skype:willy_chen_bw mobile:0937-618-190 Head &Administration Office
No.13,Shiang Shang 2nd St., West Chiu Taichung,Taiwan 40356 http://www.tool-tool.com/
/ FAX:+886 4 2471 4839 N.Branch 5F,No.460,Fu Shin North
Rd.,Taipei,Taiwan S.Branch No.24,Sec.1,Chia Pu East Rd.,Taipao
City,Chiayi Hsien,Taiwan
Welcome to BW
tool world! We are an experienced tool maker specialized in cutting
tools. We focus on what you need and endeavor to research the best
cutter to satisfy users’ demand. Our
customers involve wide range of industries, like mold & die,
aerospace, electronic, machinery, etc. We are professional expert in
cutting field. We would like to solve every problem from you. Please
feel free to contact us, its our pleasure to serve for you. BW product including: cutting tool、aerospace tool .HSS DIN Cutting tool、Carbide end mills、Carbide cutting tool、NAS Cutting tool、NAS986 NAS965 NAS897 NAS937orNAS907 Cutting Tools,Carbide end mill、disc milling cutter,Aerospace cutting tool、hss drill’Фрезеры’Carbide drill、High speed steel、Compound Sharpener’Milling cutter、INDUCTORS FOR PCD’CVDD(Chemical Vapor Deposition Diamond )’PCBN (Polycrystalline Cubic Boron Nitride) ’Core drill、Tapered end mills、CVD Diamond Tools Inserts’PCD Edge-Beveling Cutter(Golden Finger’PCD V-Cutter’PCD Wood tools’PCD Cutting tools’PCD Circular Saw Blade’PVDD End Mills’diamond tool. INDUCTORS FOR PCD . POWDER FORMING MACHINE ‘Single Crystal Diamond ‘Metric end mills、Miniature end mills、Специальные режущие инструменты ‘Пустотелое сверло ‘Pilot reamer、Fraises’Fresas con mango’ PCD (Polycrystalline diamond) ‘Frese’POWDER FORMING MACHINE’Electronics cutter、Step drill、Metal cutting saw、Double margin drill、Gun barrel、Angle milling cutter、Carbide burrs、Carbide tipped cutter、Chamfering tool、IC card engraving cutter、Side cutter、Staple Cutter’PCD diamond cutter specialized in grooving floors’V-Cut PCD Circular Diamond Tipped Saw Blade with Indexable Insert’ PCD Diamond Tool’ Saw Blade with Indexable Insert’NAS tool、DIN or JIS tool、Special tool、Metal slitting saws、Shell end mills、Side and face milling cutters、Side chip clearance saws、Long end mills’end mill grinder’drill grinder’sharpener、Stub roughing end mills、Dovetail milling cutters、Carbide slot drills、Carbide torus cutters、Angel carbide end mills、Carbide torus cutters、Carbide ball-nosed slot drills、Mould cutter、Tool manufacturer.
Bewise Inc. www.tool-tool.com
ようこそBewise Inc.の世界へお越し下さいませ、先ず御目出度たいのは新たな
情報を受け取って頂き、もっと各産業に競争力プラス展開。
弊社は専門なエンド・ミルの製造メーカーで、客先に色んな分野のニーズ、
豊富なパリエーションを満足させ、特にハイテク品質要求にサポート致します。
弊社は各領域に供給できる内容は:
(1)精密HSSエンド・ミルのR&D
(2)Carbide Cutting tools設計
(3)鎢鋼エンド・ミル設計
(4)航空エンド・ミル設計
(5)超高硬度エンド・ミル
(6)ダイヤモンド・エンド・ミル
(7)医療用品エンド・ミル設計
(8)自動車部品&材料加工向けエンド・ミル設計
弊社の製品の供給調達機能は:
(1)生活産業~ハイテク工業までのエンド・ミル設計
(2)ミクロ・エンド・ミル~大型エンド・ミル供給
(3)小Lot生産~大量発注対応供給
(4)オートメーション整備調達
(5)スポット対応~流れ生産対応
弊社の全般供給体制及び技術自慢の総合専門製造メーカーに貴方のご体験を御待ちしております。
Bewise
Inc. talaşlı imalat sanayinde en fazla kullanılan ve üç eksende (x,y,z)
talaş kaldırabilen freze takımlarından olan Parmak Freze imalatçısıdır.
Çok geniş ürün yelpazesine sahip olan firmanın başlıca ürünlerini
Karbür Parmak Frezeler, Kalıpçı Frezeleri, Kaba Talaş Frezeleri, Konik
Alın Frezeler, Köşe Radyüs Frezeler, İki Ağızlı Kısa ve Uzun Küresel
Frezeler, İç Bükey Frezeler vb. şeklinde sıralayabiliriz.
BW специализируется
в научных исследованиях и разработках, и снабжаем самым
высокотехнологичным карбидовым материалом для поставки режущих /
фрезеровочных инструментов для почвы, воздушного пространства и
электронной индустрии. В нашу основную продукцию входит твердый карбид /
быстрорежущая сталь, а также двигатели, микроэлектрические дрели, IC
картонорезальные машины, фрезы для гравирования, режущие пилы,
фрезеры-расширители, фрезеры-расширители с резцом, дрели, резаки форм
для шлицевого вала / звездочки роликовой цепи, и специальные нано
инструменты. Пожалуйста, посетите сайт www.tool-tool.com для получения большей информации.
BW
is specialized in R&D and sourcing the most advanced carbide
material with high-tech coating to supply cutting / milling tool for
mould & die, aero space and electronic industry. Our main products
include solid carbide / HSS end mills, micro electronic drill, IC card
cutter, engraving cutter, shell end mills, cutting saw, reamer, thread
reamer, leading drill, involute gear cutter for spur wheel, rack and
worm milling cutter, thread milling cutter, form cutters for spline
shaft/roller chain sprocket, and special tool, with nano grade. Please
visit our web www.tool-tool.com for more info.
