15780-28-6

Basic information

• Product Name: sodium deuteride
• Synonyms: sodium deuteride;SODIUM HYDRIDE {609.1.6};(2H)Hydridesodium;Sodium hydride-d1
• CAS NO: 15780-28-6
• Molecular Formula: HNa
• Molecular Weight: 25.003871778
• EINECS: 239-875-0
• Mol File: 15780-28-6.mol
• Article Data: 3

Chemical Properties

• Appearance: /
• CAS DataBase Reference: sodium deuteride(CAS DataBase Reference)
• NIST Chemistry Reference: sodium deuteride(15780-28-6)
• EPA Substance Registry System: sodium deuteride(15780-28-6)

Safety Data

• Hazardous Substances Data: 15780-28-6(Hazardous Substances Data)

Usage

Description

Sodium deuteride is a chemical compound consisting of sodium and deuterium, an isotope of hydrogen. It appears as a gray powder and is sensitive to moisture. The compound is typically available as a 20% solution in oil, with a high isotopic purity of 98%.

Uses

Used in Nuclear Industry:
Sodium deuteride is used as a neutron source for various applications in the nuclear industry. The reason for its use is due to its ability to generate neutrons when bombarded with high-energy particles, making it a valuable tool for research and development in nuclear technology.
Used in Chemical Industry:
In the chemical industry, sodium deuteride is used as a reducing agent for certain chemical reactions. Its application is based on its ability to donate deuterium, which can be used to label compounds and study their behavior in various chemical processes.
Used in Research and Development:
Sodium deuteride is also utilized in research and development for its unique properties. It is used as a tracer in isotope labeling studies, allowing scientists to track the movement and reactions of specific molecules within complex systems. This application is valuable for understanding the mechanisms of various chemical and biological processes.
Used in Deuterium Production:
Sodium deuteride can be used as a source of deuterium, which is an important isotope for various applications, including nuclear fusion and heavy water production. The compound's high isotopic purity makes it a suitable choice for these purposes.

InChI:InChI=1/Na.H/q+1;-1

Synthetic route

sodium (7440-23-5) + deuterium hydride → sodium hydride (7646-69-7) + sodium deuteride (15780-28-6)

Conditions	Yield
In neat (no solvent) byproducts: D, H; Na, HD (10 Torr) heated resistively in a stainless steel "cross" oven to 570 K; not isolated, detected by fluorescence spectroscopy;

sodium (7440-23-5) + deuterium (16873-17-9) → sodium deuteride (15780-28-6)

Conditions	Yield
In further solvent(s) in a satd. hydrocarbon (decane) at 240°C in an autoclave, D2-pressure at begin: 28 atm;;
In neat (no solvent) byproducts: D; Na, HD (1o Torr) heated resistively in a stainless steel "cross" oven to 570 K; not isolated, detected by fluorescence spectroscopy;
In neat (no solvent) on treatment of heated Na with circulating D2 (by reduction of D2O with Fe), 800-810Torr, up to 360°C;;

sodium hydride (7646-69-7) + deuterium (16873-17-9) → sodium deuteride (15780-28-6)

Conditions	Yield
deuterium uptake of NaH at 250°C; detn. by TG;

sodium deuteride (15780-28-6) + {1,1'-(3-oxa-pentamethylene)dicyclopentadienyl}lutetium chloride → (1,1'-(3-oxa-pentamethylene)dicyclopentadienyl lutetium deuteride)2

Conditions	Yield
In tetrahydrofuran (under Ar), a Schlenk flask is charged with Lu-compd., NaD and THF, mixt. is stirred for 7 days at 45°C; centrifugation, concn., diffusion of pentane at 0°C, washing with pentane, drying in vac., elem. anal.;	80.1%

sodium deuteride (15780-28-6) + {1,1'-(3-oxa-pentamethylene)dicyclopentadienyl}yttrium chloride → (1,1'-(3-oxa-pentamethylene)dicyclopentadienyl yttrium deuteride)2

Conditions	Yield
In tetrahydrofuran (under Ar), a Schlenk flask is charged with Y-compd., NaD and THF, mixt. is stirred for 7 days at 45°C; centrifugation, concn., diffusion of pentane at 0°C, washing with pentane, drying in vac., elem. anal.;	68.3%

sodium deuteride (15780-28-6) + water (7732-18-5) → deuterium hydride + sodium hydroxide (1310-73-2)

Conditions	Yield
In neat (no solvent) exothermic react., react.-enthalpy given;;

Upstream product

• 7440-23-5 sodium 
• 16873-17-9 deuterium 
• 7646-69-7 sodium hydride 

Downstream Products

• 1310-73-2 sodium hydroxide 

Relevant articles and documents

Nascent rotational quantum state distribution of NaH (NaD) from the reaction of Na*(42P) with H2, D2, and HD

The nascent rotational quantum state distributions of NaH and NaD products resulting from the reactions of Na*(42Pj) with H2, D2, and HD have been determined using the laser pump-probe technique.We have observed a bimodal rotational distribution with a minor component peaking at low J and a major component peaking at high J.We have observed no evidence for a kinematic isotope effect on the product distribution.Our results are consisent with a model wherein the reaction occurs predominantly on the attractive 2B2 potential energy surface in near C2v geometry with the rotational distribution being determined late in the exit channel.

Hydrogen diffusion in NaH as derived from isotope exchange experiments

We report on hydrogen-deuterium-exchange experiments on NaH probed by thermogravimetry. From the measurements a diffusion parameter of deuterium in NaH of D=1.1× 10-17 m2 /s at 523 K is derived. The activation energy of tracer diffus