26041-18-9

Basic information

• Product Name: (~35~S)sulfide
• CAS NO: 26041-18-9
• Molecular Formula: ³⁵S
• Molecular Weight: 34.9701
• Mol File: 26041-18-9.mol
• Article Data: 8

Chemical Properties

• CAS DataBase Reference: (~35~S)sulfide(CAS DataBase Reference)
• NIST Chemistry Reference: (~35~S)sulfide(26041-18-9)
• EPA Substance Registry System: (~35~S)sulfide(26041-18-9)

Safety Data

• Hazardous Substances Data: 26041-18-9(Hazardous Substances Data)

Usage

Description

(35S)sulfide is a radioactive isotope of sulfur that is utilized in various research and medical applications. It is produced by irradiating sulfur with high-energy particles like protons or deuterons, resulting in a compound with unique properties due to its radioactivity.

Uses

Used in Biochemical and Physiological Studies:
(35S)sulfide serves as a valuable tracer in biochemical and physiological research, allowing scientists to track and study the behavior of sulfur-containing compounds within biological systems. Its radioactivity provides a means to monitor the distribution, metabolism, and interactions of these compounds in living organisms.
Used in Metabolic Pathway Analysis:
In the field of metabolism, (35S)sulfide is employed to investigate the intricate pathways involved in the synthesis, breakdown, and transformation of sulfur-containing molecules. This helps researchers understand the role of sulfur in various metabolic processes and its impact on overall health and disease.
Used in the Synthesis of Complex Molecules:
(35S)sulfide is also used in the synthesis of complex organic molecules that contain sulfur. Its radioactivity allows for the tracking of these molecules during chemical reactions, providing insights into reaction mechanisms and the formation of desired products.
Used in Environmental and Occupational Health:
Due to its radioactivity, (35S)sulfide can be used to study the environmental impact of sulfur compounds and their potential hazards in occupational settings. This helps in the development of safety measures and guidelines to minimize exposure and contamination risks.
Precautions:
Given the radioactivity of (35S)sulfide, it is crucial to handle this compound with care to prevent environmental contamination and human exposure. Strict safety protocols and containment measures must be followed during its production, use, and disposal to ensure the protection of both researchers and the environment.

Upstream product

• 421-17-0 Trifluoromethylsulfenyl chloride 
• 21109-95-5 barium sulfide 
• 7732-18-5 water 
• 1313-82-2 sodium sulfide 
• 1345-25-1 iron(II) oxide 
• 10025-67-9 disulfur dichloride 
• 7446-09-5 sulfur dioxide 
• 12775-96-1 copper 
• 7439-95-4 magnesium 
• 7783-06-4 hydrogen sulfide 
• 7440-23-5 sodium 
• 7704-34-9 sulfur 
• 1310-73-2 sodium hydroxide 
• 23550-45-0 disulfur 

Downstream Products

• 14808-79-8 Sulfate 
• 7704-34-9 sulfur 
• 14383-50-7 thiosulphate ion 
• 16330-92-0 tetrathiomolybdate(VI) 
• 14265-45-3 sulfite^(2-) 
• 86436-87-5 Rh₂(CO)2(C₅H₄NCH(P(C₆H₅)2)2)2(S) 

Relevant articles and documents

Electrochemical synthesis of organochalcogenides in aqueous medium

The electrochemical preparation of telluride, selenide and sulfide ions was carried out in NaOH aqueous solution, using a two compartment cell. Organochalcogenides were prepared from halogenated compounds in a two-step procedure. The monochalcogenides were obtained as the major products in good yields.

Chemical species in sulfur-ammonia solutions: Influence of amide addition

The acidity of sulfur-ammonia solutions has been modified by the introduction of an alkali-metal amide, and the chemical composition of the solution has been studied by using UV-visible spectrophotometry and Raman spectroscopy. It is shown that the progressive introduction of an alkali-metal amide makes the oxidized species more oxidized and the reduced species more reduced. It is found that, in sulfur-ammonia solutions, a chemical species less oxidized than S4N- exists in solution, which is neither S7N- nor a polysulfide; it is suggested that this species is a neutral form of sulfur. It is shown that the concentration of S4N- can be increased after amide addition by a factor of about 3 for a 10-2 M solution. Other oxidized forms of sulfur that have been observed are assigned to S3N- and S2N-. Very slow kinetics are observed for the modifications of the species induced by the introduction of the alkali-metal amide.