Buy Xenon (Xe) Cas 7440-63-3

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Xenon is a chemical element; it has symbol Xe and atomic number 54. It is a dense, colorless, odorless noble gas found in Earth’s atmosphere in trace amounts.^[16] Although generally unreactive, it can undergo a few chemical reactions such as the formation of xenon hexafluoroplatinate, the first noble gas compound to be synthesized.^[17][18][19]

Xenon is used in flash lamps^[20] and arc lamps,^[21] and as a general anesthetic.^[22] The first excimer laser design used a xenon dimer molecule (Xe₂) as the lasing medium,^[23] and the earliest laser designs used xenon flash lamps as pumps.^[24] Xenon is also used to search for hypothetical weakly interacting massive particles^[25] and as a propellant for ion thrusters in spacecraft.  Buy Xenon (Xe) Cas 7440-63-3

Naturally occurring xenon consists of seven stable isotopes and two long-lived radioactive isotopes. More than 40 unstable xenon isotopes undergo radioactive decay, and the isotope ratios of xenon are an important tool for studying the early history of the Solar System.^[27] Radioactive xenon-135 is produced by beta decay from iodine-135 (a product of nuclear fission), and is the most significant (and unwanted) neutron absorber in nuclear reactors.^[28]

Xenon was discovered in England by the Scottish chemist William Ramsay and English chemist Morris Travers on July 12, 1898,^[29] shortly after their discovery of the elements krypton and neon. They found xenon in the residue left over from evaporating components of liquid air.^[30][31] Ramsay suggested the name xenon for this gas from the Greek word ξένον xénon, neuter singular form of ξένος xénos, meaning ‘foreign(er)’, ‘strange(r)’, or ‘guest’.^[32][33] In 1902, Ramsay estimated the proportion of xenon in the Earth’s atmosphere to be one part in 20 million.^[34]

During the 1930s, American engineer Harold Edgerton began exploring strobe light technology for high speed photography. This led him to the invention of the xenon flash lamp in which light is generated by passing brief electric current through a tube filled with xenon gas. In 1934, Edgerton was able to generate flashes as brief as one microsecond with this method.^[20][35][36]

In 1939, American physician Albert R. Behnke Jr. began exploring the causes of “drunkenness” in deep-sea divers. He tested the effects of varying the breathing mixtures on his subjects, and discovered that this caused the divers to perceive a change in depth. From his results, he deduced that xenon gas could serve as an anesthetic. Although Russian toxicologist Nikolay V. Lazarev apparently studied xenon anesthesia in 1941, the first published report confirming xenon anesthesia was in 1946 by American medical researcher John H. Lawrence, who experimented on mice. Xenon was first used as a surgical anesthetic in 1951 by American anesthesiologist Stuart C. Cullen, who successfully used it with two patients. Buy Xenon (Xe) Cas 7440-63-3

Xenon and the other noble gases were for a long time considered to be completely chemically inert and not able to form compounds. However, while teaching at the University of British Columbia, Neil Bartlett discovered that the gas platinum hexafluoride (PtF₆) was a powerful oxidizing agent that could oxidize oxygen gas (O₂) to form dioxygenyl hexafluoroplatinate (O⁺
₂[PtF
₆]⁻
).^[38] Since O₂ (1165 kJ/mol) and xenon (1170 kJ/mol) have almost the same first ionization potential, Bartlett realized that platinum hexafluoride might also be able to oxidize xenon. On March 23, 1962, he mixed the two gases and produced the first known compound of a noble gas, xenon hexafluoroplatinate.^[39][19]

Bartlett thought its composition to be Xe⁺[PtF₆]⁻, but later work revealed that it was probably a mixture of various xenon-containing salts.^[40][41][42] Since then, many other xenon compounds have been discovered,^[43] in addition to some compounds of the noble gases argon, krypton, and radon, including argon fluorohydride (HArF),^[44] krypton difluoride (KrF₂),^[45][46] and radon fluoride.^[47] By 1971, more than 80 xenon compounds were known.^[48][49]

In November 1989, IBM scientists demonstrated a technology capable of manipulating individual atoms. The program, called IBM in atoms, used a scanning tunneling microscope to arrange 35 individual xenon atoms on a substrate of chilled crystal of nickel to spell out the three-letter company initialism. It was the first-time atoms had been precisely positioned on a flat surface.^[50]

Xenon has atomic number 54; that is, its nucleus contains 54 protons. At standard temperature and pressure, pure xenon gas has a density of 5.894 kg/m³, about 4.5 times the density of the Earth’s atmosphere at sea level, 1.217 kg/m³.^[51] As a liquid, xenon has a density of up to 3.100 g/mL, with the density maximum occurring at the triple point.^[52] Liquid xenon has a high polarizability due to its large atomic volume, and thus is an excellent solvent. It can dissolve hydrocarbons, biological molecules, and even water.^[53] Under the same conditions, the density of solid xenon, 3.640 g/cm³,^[52] is greater than the average density of granite, 2.75 g/cm³. Under gigapascals of pressure, xenon forms a metallic phase.^[54]

Solid xenon changes from Face-centered cubic (fcc) to hexagonal close packed (hcp) crystal phase under pressure and begins to turn metallic at about 140 GPa, with no noticeable volume change in the hcp phase.^[55] It is completely metallic at 155 GPa.^[56] When metallized, xenon appears sky blue because it absorbs red light and transmits other visible frequencies. Such behavior is unusual for a metal and is explained by the relatively small width of the electron bands in that state. Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3, Buy Xenon (Xe) Cas 7440-63-3

Liquid or solid xenon nanoparticles can be formed at room temperature by implanting Xe⁺ ions into a solid matrix. Many solids have lattice constants smaller than solid Xe. This results in compression of the implanted Xe to pressures that may be sufficient for its liquefaction or solidification. Buy Xenon (Xe) Cas 7440-63-3

7440-63-3

Post Buying Request

Xenon

Catalog No.

S575069

CAS No.

7440-63-3

M.F

Xe

M. Wt

131.29 g/mol

Availability

In Stock

* This item is exclusively intended for research purposes and is not designed for human therapeutic applications or veterinary use.

Content Navigation

• 1. General Information
• 2. Scientific Research Applications
• 3. Description
• 4. Mechanism of Action
• 5. Chemical Reactions

• 6. Applications
• 7. Interaction Studies
• 8. Similar Compounds
• 9. Specification
• 10. Others

General Information

CAS Number

7440-63-3

Product Name

Xenon

IUPAC Name

xenon

Molecular Formula

Xe

Molecular Weight

131.29 g/mol

InChI

InChI=1S/Xe

InChI Key

FHNFHKCVQCLJFQ-UHFFFAOYSA-N

SMILES

[Xe]

solubility

Solubility in water, g/100ml at 20 °C: 0.6 (very poor)

Synonyms

Xenon

Canonical SMILES

[Xe]

Scientific Research Applications

The XENON project, operating at the Gran Sasso National Laboratory in Italy, utilizes large detectors filled with liquid xenon . These detectors aim to capture weakly interacting massive particles (WIMPs), which are a theorized candidate for dark matter. When a WIMP collides with a xenon nucleus, it produces minute amounts of light and ionization. These signals are then captured by the detector, and any excess events beyond known background noise could potentially indicate the presence of dark matter.

Xenon in Medical Imaging

Beyond its role in dark matter exploration, xenon finds valuable applications in the field of medical imaging. Its unique properties, particularly its high atomic number and ability to dissolve in various tissues, make it a useful contrast agent for a variety of imaging techniques.

One notable application is xenon-enhanced computed tomography (Xe-CT) . In this technique, xenon-129, a stable isotope of xenon, is inhaled by the patient and readily dissolves in lung tissue. This allows for the creation of detailed images of the lungs, offering valuable insights into lung function and potential abnormalities. Additionally, xenon can be used in magnetic resonance imaging (MRI) as a contrast agent for specific tissues, such as the lungs and brain .

Xenon in Other Scientific Fields

The research applications of xenon extend beyond dark matter detection and medical imaging. Here are some other notable examples:

• Nuclear dating: Isotopic ratios of xenon in meteorites act as a powerful tool for studying the formation of the Solar System . By analyzing these ratios, scientists can gain insights into the nucleosynthesis processes and timeline of our solar system’s formation.
• Cryogenics: Due to its low thermal conductivity, xenon is used in some cryogenic applications requiring extremely low temperatures .
• Spectroscopy: Xenon exhibits unique spectral properties that make it useful for various spectroscopic techniques, allowing researchers to analyze the composition and structure of materials .

Description

Xenon is a colorless, odorless, and tasteless noble gas, classified as a member of Group 18 in the periodic table. It has an atomic number of 54 and is the heaviest stable noble gas. Xenon is primarily obtained from the fractional distillation of liquid air, where it exists in trace amounts. Despite its general reputation for being chemically inert due to its complete valence electron shell, xenon can form a variety of compounds under specific conditions, particularly with highly electronegative elements such as fluorine and oxygen  .

Mechanism of Action

Xenon-129 and Magnetic Resonance Imaging (MRI):

One specific isotope, Xenon-129 (¹²⁹Xe), holds particular significance in scientific research. Its high polarizability and ability to dissolve in blood and be taken up by lungs allows its detection using MRI []. This provides valuable insights into lung function and structure, aiding in the diagnosis and study of various lung diseases [].

Chemical Reactions

– Pilgaard Elements” class=”citation ml-xs inline” data-state=”closed” href=”https://pilgaardelements.com/Xenon/Reactions.htm” rel=”nofollow noopener” target=”_blank”>  .

• Oxide Synthesis:
  • Xenon trioxide can be synthesized through the hydrolysis of xenon hexafluoride.
  • Xenon tetroxide is generated from barium perxenate treated with concentrated sulfuric acid  .
• Excimer Formation: Xenon can form excimers when energized, leading to transient species that emit light upon returning to ground state .

Applications

Xenon’s unique properties allow for a range of applications:

• Lighting: Xenon is used in high-intensity discharge lamps and flash lamps due to its ability to produce bright light when ionized.
• Anesthesia: Its anesthetic properties are being explored in medical settings for general anesthesia.
• Nuclear Imaging: Xenon’s isotopes are utilized in medical imaging techniques such as computed tomography scans.
• Research: Xenon’s reactivity allows it to serve as a subject in studies related to noble gas chemistry and potential applications in materials science .

Interaction Studies

Studies on xenon’s interactions focus on its behavior with various chemical species:

• Fluorides: Xenon’s fluorides can act as both fluoride donors and acceptors, forming complex ions with transition metals.
• Water: While xenon does not react directly with water, it dissolves slightly in it, which has implications for its behavior in biological systems  .
• Excimers: The formation of excimers with other elements indicates potential applications in photonics and material sciences .

Similar Compounds

Xenon’s unique properties set it apart from other noble gases and compounds. Below is a comparison with similar compounds:

Compound	Type	Notable Characteristics
Krypton	Noble Gas	Forms fewer compounds; less reactive than xenon
Argon	Noble Gas	Generally inert; minimal compound formation
Radon	Noble Gas	Radioactive; limited chemical reactivity
Neon	Noble Gas	Very low reactivity; primarily used in lighting
Fluorine	Halogen	Highly reactive; forms stable compounds with xenon

Xenon’s ability to form stable compounds under specific conditions distinguishes it from other noble gases, which typically exhibit much lower reactivity. Its diverse chemistry enables the formation of numerous halides and oxides, making it unique among its peers  .

Specification

Physical Description

Xenon appears as a colorless odorless gas. Noncombustible. Heavier than air. May asphyxiate by the displacement of air. Under prolonged exposure to fire or heat containers may rupture violently and rocket.
Xenon, refrigerated liquid (cryogenic liquid) appears as a colorless odorless nonflammable cold liquid. Boils at -150 °F. Contact with the liquid may cause frost bite. Can asphyxiate by displacing air in enclosed spaces. Exposure of the container to prolonged heat or fire may cause it to rupture violently and rocket. Used to make flash bulbs for photography.
Odorless, nonflammable gas; [CAMEO]
COLOURLESS ODOURLESS COMPRESSED LIQUEFIED GAS.

Exact Mass

131.90415508 g/mol

Monoisotopic Mass

131.90415508 g/mol

Boiling Point

-108.1 °C

Heavy Atom Count

1

Vapor Density

Relative vapor density (air = 1): 4.5

LogP

1.4

Others

Melting Point

-111.8 °C

UNII

3H3U766W84

GHS Hazard Statements

Aggregated GHS information provided by 342 companies from 5 notifications to the ECHA C&L Inventory. Each notification may be associated with multiple companies.;
Reported as not meeting GHS hazard criteria by 22 of 342 companies. For more detailed information, please visit ECHA C&L website;
Of the 4 notification(s) provided by 320 of 342 companies with hazard statement code(s):;
H280 (74.06%): Contains gas under pressure;
may explode if heated [Warning Gases under pressure];
H281 (25.94%): Contains refrigerated gas;
may cause cryogenic burns or injury [Warning Gases under pressure];
Information may vary between notifications depending on impurities, additives, and other factors. The percentage value in parenthesis indicates the notified classification ratio from companies that provide hazard codes. Only hazard codes with percentage values above 10% are shown.

Pictograms

Compressed Gas

Other CAS

7440-63-3

Wikipedia

Xenon

Use Classification

Human drugs -> Rare disease (orphan)

General Manufacturing Information

Xenon: ACTIVE

Dates

Last modified: 08-15-2023

• Basic information

  1. Product Name: Xenon
  2. Synonyms: Xenon atom;
  3. CAS NO:7440-63-3
  4. Molecular Formula: Xe
  5. Molecular Weight: 131.293
  6. EINECS: 231-172-7
  7. Product Categories: N/A
  8. Mol File: 7440-63-3.mol

• Chemical Properties

  1. Melting Point: -111.7℃
  2. Boiling Point: N/A
  3. Flash Point: N/A
  4. Appearance: Colorless gas
  5. Density: N/A
  6. Vapor Pressure: 47500mmHg at 25°C
  7. Refractive Index: N/A
  8. Storage Temp.: N/A
  9. Solubility: N/A
  10. CAS DataBase Reference: Xenon(CAS DataBase Reference)
  11. NIST Chemistry Reference: Xenon(7440-63-3)
  12. EPA Substance Registry System: Xenon(7440-63-3)

• Safety Data

  1. Hazard Codes: N/A
  2. Statements: N/A
  3. Safety Statements: N/A
  4. WGK Germany:
  5. RTECS:
  6. HazardClass: N/A
  7. PackingGroup: N/A
  8. Hazardous Substances Data: 7440-63-3(Hazardous Substances Data)

Xenon is a member of the zero-valence elements that are called noble or inert gases. It is inert to most common chemical reactions (such as combustion, for example) because the outer valence shell contains eight electrons. This produces a stable,

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   • Boiling point: bp -108.13°
   • Melting point: 111.79°C

   • form: colorless gas
   • solubility: slightly soluble in H2O
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