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Lithium hydride

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Lithium hydride
Space-filling model of part of the crystal structure of lithium hydride
  Lithium cation, Li+
  Hydrogen anion, H

__H __Li+
Structure of lithium hydride.
Space-filling model of the lithium hydride molecule
Identifiers
3D model (JSmol)
ChemSpider
ECHA InfoCard 100.028.623 Edit this at Wikidata
RTECS number
  • OJ6300000
UNII
  • InChI=1S/Li.Hssss ☒N
    Key: SIAPCJWMELPYOE-UHFFFAOYSA-N ☒N
  • InChI=1/Li.H/q+1;-1
    Key: SRTHRWZAMDZJOS-UHFFFAOYAZ
  • [H-].[Li+]
Properties
LiH
Molar mass 7.95 g·mol−1
Appearance colorless to gray solid[1]
Density 0.78 g/cm3[1]
Melting point 688.7 °C (1,271.7 °F; 961.9 K)[1]
Boiling point 900–1,000 °C (1,650–1,830 °F; 1,170–1,270 K) (decomposes)[2]
reacts
Solubility slightly soluble in dimethylformamide
reacts with ammonia, diethyl ether, ethanol
−4.6·10−6 cm3/mol
1.9847[3]: 43 
Structure
fcc (NaCl-type)
a = 0.40834 nm[3]: 56 
6.0 D[3]: 35 
Thermochemistry
3.51 J/(g·K)
170.8 J/(mol·K)
−90.65 kJ/mol
−68.48 kJ/mol
Hazards
Occupational safety and health (OHS/OSH):
Main hazards
extremely strong irritant, highly toxic, highly corrosive
GHS labelling:
GHS02: FlammableGHS05: CorrosiveGHS06: Toxic
Danger
H260, H301, H314
P223, P231+P232, P260, P264, P270, P280, P301+P316, P301+P330+P331, P302+P335+P334, P302+P361+P354, P304+P340, P305+P354+P338, P316, P321, P330, P363, P370+P378, P402+P404, P405, P501
NFPA 704 (fire diamond)
NFPA 704 four-colored diamondHealth 3: Short exposure could cause serious temporary or residual injury. E.g. chlorine gasFlammability 2: Must be moderately heated or exposed to relatively high ambient temperature before ignition can occur. Flash point between 38 and 93 °C (100 and 200 °F). E.g. diesel fuelInstability 2: Undergoes violent chemical change at elevated temperatures and pressures, reacts violently with water, or may form explosive mixtures with water. E.g. white phosphorusSpecial hazard W: Reacts with water in an unusual or dangerous manner. E.g. sodium, sulfuric acid
3
2
2
200 °C (392 °F; 473 K)
Lethal dose or concentration (LD, LC):
77.5 mg/kg (oral, rat)[5]
22 mg/m3 (rat, 4 h)[6]
NIOSH (US health exposure limits):
PEL (Permissible)
TWA 0.025 mg/m3[4]
REL (Recommended)
TWA 0.025 mg/m3[4]
IDLH (Immediate danger)
0.5 mg/m3[4]
Safety data sheet (SDS) ICSC 0813
Related compounds
Other cations
Sodium hydride
Potassium hydride
Rubidium hydride
Caesium hydride
Related compounds
Lithium borohydride
Lithium aluminium hydride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Lithium hydride is an inorganic compound with the formula LiH. This alkali metal hydride is a colorless solid, although commercial samples are grey. Characteristic of a salt-like (ionic) hydride, it has a high melting point, and it is not soluble but reactive with all protic organic solvents. It is soluble and nonreactive with certain molten salts such as lithium fluoride, lithium borohydride, and sodium hydride. With a molar mass of 7.95 g/mol, it is the lightest ionic compound.

Physical properties

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LiH is a diamagnetic and an ionic conductor with a conductivity gradually increasing from 2×10−5 Ω−1cm−1 at 443 °C to 0.18 Ω−1cm−1 at 754 °C; there is no discontinuity in this increase through the melting point.[3]: 36  The dielectric constant of LiH decreases from 13.0 (static, low frequencies) to 3.6 (visible-light frequencies).[3]: 35  LiH is a soft material with a Mohs hardness of 3.5.[3]: 42  Its compressive creep (per 100 hours) rapidly increases from < 1% at 350 °C to > 100% at 475 °C, meaning that LiH cannot provide mechanical support when heated.[3]: 39 

The thermal conductivity of LiH decreases with temperature and depends on morphology: the corresponding values are 0.125 W/(cm·K) for crystals and 0.0695 W/(cm·K) for compacts at 50 °C, and 0.036 W/(cm·K) for crystals and 0.0432 W/(cm·K) for compacts at 500 °C.[3]: 60  The linear thermal expansion coefficient is 4.2×10−5/°C at room temperature.[3]: 49 

Synthesis and processing

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LiH is produced by treating lithium metal with hydrogen gas:

2 Li + H2 → 2 LiH

This reaction is especially rapid at temperatures above 600 °C. Addition of 0.001–0.003% carbon, and/or increasing temperature/pressure, increases the yield up to 98% at 2-hour residence time.[3]: 147  However, the reaction proceeds at temperatures as low as 29 °C. The yield is 60% at 99 °C and 85% at 125 °C, and the rate depends significantly on the surface condition of LiH.[3]: 5 

Less common ways of LiH synthesis include thermal decomposition of lithium aluminium hydride (200 °C), lithium borohydride (300 °C), n-butyllithium (150 °C), or ethyllithium (120 °C), as well as several reactions involving lithium compounds of low stability and available hydrogen content.[3]: 144–145 

Chemical reactions yield LiH in the form of lumped powder, which can be compressed into pellets without a binder. More complex shapes can be produced by casting from the melt.[3]: 160 ff.  Large single crystals (about 80 mm long and 16 mm in diameter) can be then grown from molten LiH powder in hydrogen atmosphere by the Bridgman–Stockbarger technique. They often have bluish color owing to the presence of colloidal Li. This color can be removed by post-growth annealing at lower temperatures (~550 °C) and lower thermal gradients.[3]: 154  Major impurities in these crystals are Na (20–200 ppm), O (10–100 ppm), Mg (0.5–6 ppm), Fe (0.5-2 ppm) and Cu (0.5-2 ppm).[3]: 155 

Cracking in cast LiH after machining with a fly cutter. Scale is in inches.

Bulk cold-pressed LiH parts can be easily machined using standard techniques and tools to micrometer precision. However, cast LiH is brittle and easily cracks during processing.[3]: 171 

A more energy efficient route to form lithium hydride powder is by ball milling lithium metal under high hydrogen pressure. A problem with this method is the cold welding of lithium metal due to the high ductility. By adding small amounts of lithium hydride powder the cold welding can be avoided.[7]

Reactions

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LiH powder reacts rapidly with air of low humidity, forming LiOH, Li2O and Li2CO3. In moist air the powder ignites spontaneously, forming a mixture of products including some nitrogenous compounds. The lump material reacts with humid air, forming a superficial coating, which is a viscous fluid. This inhibits further reaction, although the appearance of a film of "tarnish" is quite evident. Little or no nitride is formed on exposure to humid air. The lump material, contained in a metal dish, may be heated in air to slightly below 200 °C without igniting, although it ignites readily when touched by an open flame. The surface condition of LiH, presence of oxides on the metal dish, etc., have a considerable effect on the ignition temperature. Dry oxygen does not react with crystalline LiH unless heated strongly, when an almost explosive combustion occurs.[3]: 6 

LiH is highly reactive towards water and other protic reagents:[3]: 7 

LiH + H2O → Li+ + H2 + OH

LiH is less reactive with water than Li and thus is a much less powerful reducing agent for water, alcohols, and other media containing reducible solutes. This is true for all the binary saline hydrides.[3]: 22 

LiH pellets slowly expand in moist air, forming LiOH; however, the expansion rate is below 10% within 24 hours in a pressure of 2 Torr of water vapor.[3]: 7  If moist air contains carbon dioxide, then the product is lithium carbonate.[3]: 8  LiH reacts with ammonia, slowly at room temperature, but the reaction accelerates significantly above 300 °C.[3]: 10  LiH reacts slowly with higher alcohols and phenols, but vigorously with lower alcohols.[3]: 14 

LiH reacts with sulfur dioxide to give the dithionite:

2 LiH + 2 SO2 → Li2S2O4 + H2

though above 50 °C the product is lithium sulfide instead.[3]: 9 

LiH reacts with acetylene to form lithium carbide and hydrogen. With anhydrous organic acids, phenols and acid anhydrides, LiH reacts slowly, producing hydrogen gas and the lithium salt of the acid. With water-containing acids, LiH reacts faster than with water.[3]: 8  Many reactions of LiH with oxygen-containing species yield LiOH, which in turn irreversibly reacts with LiH at temperatures above 300 °C:[3]: 10 

LiH + LiOH → Li2O + H2

Lithium hydride is rather unreactive at moderate temperatures with O2 or Cl2. It is, therefore, used in the synthesis of other useful hydrides,[8] e.g.,

8 LiH + Al2Cl6 → 2 Li[AlH4] + 6 LiCl
2 LiH + B2H6 → 2 Li[BH4]

Applications

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Hydrogen storage and fuel

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With a hydrogen content in proportion to its mass three times that of NaH, LiH has the highest hydrogen content of any hydride. LiH is periodically of interest for hydrogen storage, but applications have been thwarted by its stability to decomposition. Thus removal of H2 requires temperatures above the 700 °C used for its synthesis, such temperatures are expensive to create and maintain. The compound was once tested as a fuel component in a model rocket.[9][10]

Precursor to complex metal hydrides

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LiH is not usually a hydride-reducing agent, except in the synthesis of hydrides of certain metalloids. For example, silane is produced in the reaction of lithium hydride and silicon tetrachloride by the Sundermeyer process:

4 LiH + SiCl4 → 4 LiCl + SiH4

Lithium hydride is used in the production of a variety of reagents for organic synthesis, such as lithium aluminium hydride (Li[AlH4]) and lithium borohydride (Li[BH4]). Triethylborane reacts to give superhydride (Li[BH(CH2CH3)3]).[11]

In nuclear chemistry and physics

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Lithium hydride (LiH) is sometimes a desirable material for the shielding of nuclear reactors, with the isotope lithium-6 (Li-6), and it can be fabricated by casting.[12][13]

Lithium deuteride

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Lithium deuteride, in the form of lithium-7 deuteride (7Li2H or 7LiD), is a good moderator for nuclear reactors, because deuterium (2H or D) has a lower neutron absorption cross-section than ordinary hydrogen or protium (1H) does, and the cross-section for 7Li is also low, decreasing the absorption of neutrons in a reactor. 7Li is preferred for a moderator because it has a lower neutron capture cross-section, and it also forms less tritium (3H or T) under bombardment with neutrons.[14]

The corresponding lithium-6 deuteride (6Li2H or 6LiD) is the primary fusion fuel in thermonuclear weapons.[citation needed] In hydrogen warheads of the Teller–Ulam design, a nuclear fission trigger explodes to heat and compress the lithium-6 deuteride, and to bombard the 6LiD with neutrons to produce tritium in an exothermic reaction:

6LiD + n → 4He + T + D

The deuterium and tritium then fuse to produce helium, one neutron, and 17.59 MeV of free energy in the form of gamma rays, kinetic energy, etc. Tritium has a favorable reaction cross section. The helium is an inert byproduct.[citation needed]

3
1
H
+ 2
1
H
4
2
He
+ n.

Before the Castle Bravo nuclear weapons test in 1954, it was thought that only the less common isotope 6Li would breed tritium when struck with fast neutrons. The Castle Bravo test showed (accidentally) that the more plentiful 7Li also does so under extreme conditions, albeit by an endothermic reaction.

Safety

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LiH reacts violently with water to give hydrogen gas and LiOH, which is caustic. Consequently, LiH dust can explode in humid air, or even in dry air due to static electricity. At concentrations of 5–55 mg/m3 in air the dust is extremely irritating to the mucous membranes and skin and may cause an allergic reaction. Because of the irritation, LiH is normally rejected rather than accumulated by the body.[3]: 157, 182 

Some lithium salts, which can be produced in LiH reactions, are toxic. LiH fire should not be extinguished using carbon dioxide, carbon tetrachloride, or aqueous fire extinguishers; it should be smothered by covering with a metal object or graphite or dolomite powder. Sand is less suitable, as it can explode when mixed with burning LiH, especially if not dry. LiH is normally transported in oil, using containers made of ceramic, certain plastics or steel, and is handled in an atmosphere of dry argon or helium.[3]: 156  Nitrogen can be used, but not at elevated temperatures, as it reacts with lithium.[3]: 157  LiH normally contains some metallic lithium, which corrodes steel or silica containers at elevated temperatures.[3]: 173–174, 179 

References

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  1. ^ a b c Lide, D. R., ed. (2005). CRC Handbook of Chemistry and Physics (86th ed.). Boca Raton, Florida: CRC Press. p. 4.70. ISBN 0-8493-0486-5.
  2. ^ David Arthur Johnson; Open University (12 August 2002). Metals and chemical change. Royal Society of Chemistry. pp. 167–. ISBN 978-0-85404-665-2. Retrieved 1 November 2011.
  3. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad Smith, R. L.; Miser, J. W. (1963). Compilation of the properties of lithium hydride. NASA.
  4. ^ a b c NIOSH Pocket Guide to Chemical Hazards. "#0371". National Institute for Occupational Safety and Health (NIOSH).
  5. ^ Chambers, Michael. "ChemIDplus - 7580-67-8 - SIAPCJWMELPYOE-UHFFFAOYSA-N - Lithium hydride - Similar structures search, synonyms, formulas, resource links, and other chemical information". chem.sis.nlm.nih.gov. Retrieved 10 April 2018.
  6. ^ "Lithium hydride". Immediately Dangerous to Life or Health Concentrations (IDLH). National Institute for Occupational Safety and Health (NIOSH).
  7. ^ Solvent-and catalyst-free mechanochemical synthesis of alkali metal monohydrides IZ Hlova, A Castle, JF Goldston, S Gupta, T Prost… - Journal of Materials Chemistry A, 2016
  8. ^ "NCERT Chemistry Textbook" (PDF).
  9. ^ Lex Archived 2008-07-23 at the Wayback Machine. Astronautix.com (1964-04-25). Retrieved on 2011-11-01.
  10. ^ Empirical laws for hybrid combustion of lithium hydride with fluorine in small rocket engines. Ntrs.nasa.gov. Retrieved on 2011-11-01.Closed access icon (password-protected)
  11. ^ Peter Rittmeyer, Ulrich Wietelmann "Hydrides" in Ullmann's Encyclopedia of Industrial Chemistry 2002, Wiley-VCH, Weinheim. doi:10.1002/14356007.a13_199
  12. ^ Peter J. Turchi (1998). Propulsion techniques: action and reaction. AIAA. pp. 339–. ISBN 978-1-56347-115-5. Retrieved 2 November 2011.
  13. ^ Welch, Frank H. (February 1974). "Lithium hydride: A space age shielding material". Nuclear Engineering and Design. 26 (3): 440–460. doi:10.1016/0029-5493(74)90082-X.
  14. ^ Massie, Mark; Dewan, Leslie C. "US 20130083878 A1, April 4, 2013, NUCLEAR REACTORS AND RELATED METHODS AND APPARATUS". U.S. Patent Office. U.S. Government. Retrieved 2 June 2016.
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