Lithium borohydride

Lithium borohydride (LiBH₄) is an inorganic compound consisting of lithium and the borohydride anion, appearing as a white crystalline powder with orthorhombic crystal structure.^[1] It has a molecular weight of 21.78 g/mol, a density of 0.666 g/cm³ at 25°C, melts at approximately 275 °C, and decomposes above 400 °C without a distinct boiling point due to its thermal instability.^[2]^[3] Highly reactive with water, producing hydrogen gas and lithium hydroxide, it is moisture-sensitive and must be handled under inert atmospheres.^[2] As a strong reducing agent, lithium borohydride is widely employed in organic synthesis for selectively reducing esters, ketones, aldehydes, acid chlorides, lactones, and epoxides to alcohols, often in solvents like tetrahydrofuran (THF) or ethanol where it shows good solubility.^[1] Its preparation typically involves metathesis reactions, such as exchanging sodium borohydride with lithium chloride in isopropylamine or reacting lithium hydride with boron trifluoride in ethereal solvents.^[4] Beyond synthesis, it has garnered attention for energy applications, particularly as a hydrogen storage material owing to its theoretical gravimetric capacity of 18.5 wt% hydrogen—the highest among borohydrides at room temperature—though challenges like high desorption temperatures (above 400°C) and poor reversibility limit practical use without additives or nanostructuring.^[5] Safety considerations are critical due to its extreme flammability, corrosiveness, and toxicity; it ignites spontaneously in air, causes severe burns upon skin contact, and is acutely toxic if ingested or inhaled, necessitating protective equipment and dry storage conditions.^[2] Ongoing research focuses on stabilizing its high-pressure rock-salt phase or combining it with other hydrides to improve hydrogen release kinetics for potential applications in fuel cells and batteries.^[6]

Properties

Physical properties

Lithium borohydride (LiBH₄) is a white to grayish, hygroscopic crystalline solid with a molar mass of 21.78 g/mol.^[7] Its low density of 0.666 g/cm³ contributes to its lightweight nature, making it suitable for applications requiring minimal mass.^[8] The compound exhibits thermal stability up to moderate temperatures, with a melting point of 275 °C, at which point it decomposes without reaching a boiling point.^[9]

Property	Value
Molar mass	21.78 g/mol
Appearance	White to grayish hygroscopic solid
Density	0.666 g/cm³
Melting point	275 °C (decomposes)
Decomposition temperature	~275 °C (no boiling)

Lithium borohydride demonstrates high solubility in ethereal solvents, such as diethyl ether (up to 3 g/100 mL) and tetrahydrofuran (up to 25 g/100 mL), but is insoluble in hydrocarbons.^[10] It decomposes in water and other protic solvents. Thermodynamically, its standard enthalpy of formation is −190.5 kJ/mol, and the molar heat capacity at 298 K is approximately 81 J/mol·K.^[11] These properties reflect its ionic character and orthorhombic crystal structure at ambient conditions.^[9]

Chemical properties

Lithium borohydride exhibits notable thermal stability, remaining intact up to its melting point of 275 °C, after which decomposition occurs.^[2] The compound is highly sensitive to moisture, undergoing hydrolysis that releases hydrogen gas, although the reaction proceeds more slowly than with more reactive hydrides like lithium aluminum hydride.^[12] When kept dry, it is stable in air but is strongly hygroscopic, readily absorbing atmospheric water vapor which can initiate decomposition.^[13] In solution, lithium borohydride dissociates into lithium cations and the borohydride anion (BH₄⁻), serving as a source of this reducing species in aprotic solvents such as tetrahydrofuran.^[14] Solutions of the compound in these solvents display weakly basic character due to the nucleophilic nature of the BH₄⁻ ion.^[15] As a safety consideration, lithium borohydride is a flammable solid that may ignite easily and burn vigorously once initiated, particularly in the presence of oxidizers.^[14] Contact with water generates flammable hydrogen gas, creating an explosion hazard, while its reactivity with protic solvents and acids underscores the need for handling under inert atmospheres.^[2] The compound exhibits acute oral toxicity, with an LD50 of 88 mg/kg in mice.^[2] Compared to related hydrides, lithium borohydride acts as a milder reducing agent than lithium aluminum hydride (LiAlH₄), which is more aggressive toward a broader range of functional groups, but it is stronger than sodium borohydride (NaBH₄), enabling reductions such as those of esters under conditions where NaBH₄ is ineffective.^[16]

Synthesis

Laboratory methods

Lithium borohydride was first synthesized in 1940 by Schlesinger and Brown through the reaction of ethyllithium with diborane in diethyl ether, marking the initial preparation of an alkali metal borohydride via an etherate-based method.^[17] This historical approach laid the foundation for subsequent laboratory syntheses, which prioritize solvent-based reactions for small-scale production under inert atmospheres to prevent hydrolysis. A common laboratory method involves the metathesis reaction between sodium borohydride and lithium bromide in diethyl ether or ethanol. The reactants are stirred at room temperature, leading to the precipitation of sodium bromide, which is removed by filtration. The filtrate is then concentrated and cooled to isolate lithium borohydride, followed by drying under vacuum. This procedure typically affords yields of 85–97% with high purity after the metathesis step.^[18] Another established route employs the reaction of lithium hydride with boron trifluoride diethyl etherate in diethyl ether at low temperatures, such as 0 °C, to control the exothermic process. The stoichiometry is given by:

\mathrm{BF_3 + 4 LiH \rightarrow LiBH_4 + 3 LiF}

The lithium fluoride byproduct is separated by filtration, and the product is obtained by solvent evaporation. Yields in this method range from 70–90%, depending on reaction conditions and excess hydride used.^[19] Purification of lithium borohydride from either synthesis is achieved by recrystallization from diethyl ether, yielding white crystalline material suitable for laboratory use. These solvent-based techniques are well-suited for bench-scale preparations but face challenges in scaling due to solvent handling and purification demands.^[18]

Scalable methods

One scalable approach to lithium borohydride (LiBH₄) synthesis involves wet chemical methods, particularly the reaction of lithium hydride (LiH) with trimethyl borate (B(OMe)₃) in high-boiling solvents such as hydrocarbon oil. This process proceeds via the metathesis reaction $4 \ce{LiH} + \ce{B(OMe)3} \rightarrow \ce{LiBH4} + 3 \ce{LiOMe}, typically conducted at elevated temperatures of 225–275 °C, followed by solvent removal under vacuum at 100 °C to yield pure LiBH₄ with approximately 70% efficiency. Originally developed for industrial potential, this method leverages readily available precursors and offers high purity, though it requires careful handling of reactive intermediates to minimize side products like lithium methoxide.^[8] Mechano-chemical synthesis provides an alternative for bulk production, utilizing ball milling of LiH and magnesium diboride (MgB₂) under hydrogen pressure. The reaction \ce{LiH + 1/2 MgB2 + 2 H2 -> LiBH4 + 1/2 MgH2} is facilitated by high-energy milling for 24–120 hours, followed by hydrogenation at 265 °C and 9 MPa H₂, achieving significant conversion rates enhanced by Ti-based catalysts that lower the temperature to 256 °C and pressure to 5 MPa. This solvent-free technique improves kinetics through nanostructuring and defect creation during milling, making it suitable for larger-scale operations despite energy-intensive milling requirements.^[20] Gas-solid reactions enable direct synthesis from elemental precursors, reacting lithium (Li) and boron (B) with hydrogen gas under high pressure and temperature. A representative process involves pre-milling a LiH + B mixture under 10 MPa H₂ for 10 hours, then heating to 300–500 °C at 35 MPa H₂, yielding up to 59.4% LiBH₄ at 400 °C with 6.59 wt.% hydrogen release capacity. This method reduces required temperatures by ~200 °C compared to non-pretreated routes, addressing thermodynamic barriers while utilizing high-purity hydrogen compressors for scalability, though elevated pressures pose engineering challenges.^[21] Recent innovations in electrosynthesis focus on electrochemical reduction of borate precursors to lower costs and enable continuous production. For instance, hydriding trimethyl borate at a palladium cathode under moderate hydrogen pressure (e.g., 1 atm) generates LiBH₄ via hydride transfer, offering a milder alternative to thermal methods with potential for electrode optimization to boost yields. An established electrocatalytic approach, reported in 2012, involves reduction of LiBO₂ using nano-PbO/Ti electrodes at ambient conditions, achieving a B–O to B–H conversion yield of 15.6%, which enhances scalability by minimizing energy input and byproduct formation despite the modest efficiency. Complementing this, pulsed laser deposition (PLD) fabricates LiBH₄ films via ablation of a LiB target in low-pressure hydrogen (5–70 Pa) at ambient temperature, attaining 74.4 wt.% LiBH₄ content at 70 Pa through intermediate formation of Li₂B₁₂H₁₂; while primarily for thin films, adaptations could support precursor production for bulk applications.^[8]^[22]^[23]^[24] Commercial production of LiBH₄ remains limited, with suppliers such as Albemarle (formerly Rockwood Lithium), Sigma-Aldrich (Merck Group), and American Elements providing the compound, often as solutions, due to challenges including high hydrogen pressure demands (often >30 MPa) and handling complexities from its reactivity. These factors, along with safety protocols for pyrophoric materials and energy costs for pressurization, hinder widespread adoption, though the market is projected to grow to USD 86.6 million by 2032 at a CAGR of 8.2% (as of 2025 estimates), driven by hydrogen storage needs.^[25]^[26]

Structure

Crystal polymorphs

Lithium borohydride (LiBH₄) exhibits multiple crystalline polymorphs, with the orthorhombic phase being the most stable at ambient conditions. This low-temperature form adopts the Pnma space group, featuring lattice parameters of a = 7.179 Å, b = 4.437 Å, and c = 6.803 Å at room temperature, as determined by synchrotron X-ray powder diffraction.^[27] The structure consists of tetrahedral [BH₄]⁻ anions arranged in a distorted hexagonal close-packed lattice, with Li⁺ cations occupying octahedral sites.^[27] Upon heating, LiBH₄ undergoes a reversible first-order phase transition to a hexagonal polymorph with the P6₃mc space group, stable above approximately 381 K (108 °C).^[27] This high-temperature phase has lattice parameters a = 4.276 Å and c = 7.620 Å at 408 K, reflecting a more symmetric arrangement where Li⁺ ions exhibit higher mobility.^[27] The transition has been characterized using differential scanning calorimetry and powder X-ray diffraction, showing an endothermic peak and structural reorganization without decomposition at this stage.^[28] Under high pressure, LiBH₄ displays additional polymorphs beyond the ambient phases. Experimental studies using Raman spectroscopy and X-ray diffraction up to 290 GPa have identified several distinct high-pressure forms, including phase III (tetragonal I4₁/acd) stable above approximately 1 GPa, phase V (cubic Fm-3m) above approximately 17 GPa, phase VI (orthorhombic Pnma) above 60 GPa, and indications of a seventh phase (VII) above 160 GPa.^[29] These transformations involve compression-induced changes in anion packing and cation coordination, probed via in situ neutron scattering and density functional theory calculations.^[29] Density functional theory investigations reveal that the orthorhombic polymorph is thermodynamically stable, while the hexagonal phase exhibits instability due to imaginary vibrational modes, suggesting it is dynamically metastable at ambient pressure despite experimental observation at elevated temperatures.^[30] Powder X-ray diffraction and neutron scattering remain key techniques for distinguishing these polymorphs, providing insights into their phase behavior and transitions.^[27]^[29]

Bonding and geometry

Lithium borohydride (LiBH₄) consists of Li⁺ cations and tetrahedral BH₄⁻ anions, forming an ionic lattice in its orthorhombic phase. Each BH₄⁻ anion adopts a point symmetry of m (Cₛ), with the tetrahedra aligned along two orthogonal directions within the crystal structure.^[31] The BH₄⁻ units exhibit significant distortion from ideal tetrahedral geometry due to interactions with surrounding cations, leading to variations in bond angles and lengths.^[31] The B–H bond lengths within the BH₄⁻ anion range from 1.04(2) Å to 1.28(1) Å, reflecting the distorted tetrahedral coordination.^[31] Li⁺ cations are coordinated to multiple BH₄⁻ anions, with Li–B distances spanning 2.475(4) Å to 2.542(4) Å, indicative of close ionic packing.^[31] Density functional theory (DFT) calculations confirm these structural features, showing B–H bonds averaging around 1.22 Å in the optimized orthorhombic phase.^[32] The electronic structure of LiBH₄ is predominantly ionic between Li⁺ and BH₄⁻, with the BH₄⁻ anion featuring strong covalent B–H bonds. DFT analyses reveal contributions from B p-states and H s-states near the valence band maximum, underscoring the covalent character within the anion, while Li p-states dominate the conduction band minimum, supporting the ionic inter-anion interactions. The material exhibits a wide indirect band gap, with DFT estimates ranging from 6.35 eV (LDA) to 7.58 eV (HSE06), classifying it as an insulator suitable for applications requiring electronic stability.^[33] Vibrational properties of LiBH₄ are dominated by modes associated with the BH₄⁻ anion. Infrared (IR) and Raman spectra show B–H stretching vibrations in the range of 2200–2400 cm⁻¹, split due to the reduced site symmetry (Cₛ) in the orthorhombic phase, with the triply degenerate T₂ mode of the free BH₄⁻ (T_d symmetry) splitting by approximately 100 cm⁻¹.^[34] B–H bending modes appear around 1100 cm⁻¹, further confirming the distorted tetrahedral geometry through observed mode splittings.^[34]

Reactions

Reduction reactions

Lithium borohydride (LiBH₄) serves as a selective reducing agent in organic synthesis, particularly for converting esters to primary alcohols under mild conditions, a transformation that sodium borohydride (NaBH₄) performs inefficiently or not at all. This selectivity allows preservation of other functional groups such as carboxylic acids.^[35] The mechanism involves stepwise hydride transfer from the BH₄⁻ anion to the carbonyl carbon, forming tetrahedral intermediates that collapse to release alkoxide species, ultimately yielding alcohols after protonation. For ester reduction, the overall process can be represented as:

\text{RCOOR'} + \text{LiBH}_4 \rightarrow \text{RCH}_2\text{OH} + \text{R'OH} + \text{borate byproducts}

(simplified).^[36] These reductions are commonly performed in ether solvents such as tetrahydrofuran (THF) or diethyl ether at temperatures between 0 and 25 °C, with methanol often added to accelerate ester reductions by generating alkoxyborohydride intermediates.^[36] LiBH₄ reacts faster than NaBH₄ with hindered esters, achieving complete conversion in hours rather than days. Compared to lithium aluminum hydride (LiAlH₄), LiBH₄ operates under milder conditions with fewer side products, avoiding over-reduction or elimination reactions common in sensitive substrates. For instance, the reduction of ethyl acetate to ethanol proceeds in 96–98% yield using LiBH₄ in diglyme at 100 °C, though lower temperatures suffice in THF/MeOH mixtures.

Hydrogen release

Lithium borohydride undergoes hydrolysis in the presence of water to release hydrogen gas through the reaction:

\text{LiBH}_4 + 4 \text{H}_2\text{O} \rightarrow \text{LiB(OH)}_4 + 4 \text{H}_2

This process proceeds rapidly at room temperature, achieving near-complete hydrogen evolution under stoichiometric conditions.^[37] The reaction's kinetics are enhanced by the formation of tetraborate as the byproduct, which does not significantly hinder further hydrolysis, unlike in some other borohydrides. Studies have shown that even sub-stoichiometric water amounts (e.g., H₂O/LiBH₄ ratios of 0.3–2 mol/mol) can accelerate hydrogen yield, making it suitable for controlled on-demand generation.^[37] Thermal decomposition of lithium borohydride provides an alternative pathway for hydrogen release, following the overall reaction:

\text{LiBH}_4 \rightarrow \text{LiH} + \text{B} + \frac{3}{2} \text{H}_2

This process initiates at an onset temperature of approximately 400 °C for pure LiBH₄, involving a two-step mechanism: an initial dehydrogenation to form intermediates such as Li₂B₁₂H₁₂, followed by further breakdown to the final products.^[38] The decomposition is endothermic, with a total hydrogen capacity of about 13.8 wt%, though practical yields are limited by kinetic barriers and intermediate stability. Kinetics of the thermal desorption are characterized by activation energies typically ranging from 80–100 kJ/mol for the rate-limiting steps in pure LiBH₄, which can be substantially lowered through additives. For instance, incorporation of NiO nanostructures in 2024 studies reduced the activation energy to 63–69 kJ/mol, enabling up to 4 wt% H₂ release at 250 °C within 60 minutes, due to enhanced surface interactions and bond weakening.^[39] Such modifications improve desorption rates without altering the fundamental pathway, though reversibility remains challenging owing to boride formation.

Applications

Organic synthesis

Lithium borohydride serves as a valuable reagent in organic synthesis, particularly for selective reductions in the preparation of pharmaceutical intermediates. It is commonly employed to convert esters to the corresponding alcohols, a transformation critical in active pharmaceutical ingredient (API) synthesis where functional group compatibility is essential. For instance, this selectivity allows reduction of ester groups in the presence of other sensitive moieties, such as carboxylic acids or secondary amides, enabling multistep sequences without protecting group manipulations.^[16] In addition to ester reductions, lithium borohydride facilitates the conversion of primary amides to amines, avoiding over-reduction to hydrocarbons that might occur with stronger agents. This application is particularly useful in synthesizing amine-containing intermediates for pharmaceuticals, where precise control over reduction outcomes preserves molecular integrity. A seminal example involves its use in diglyme-methanol mixtures to selectively target primary amides while leaving secondary aliphatic amides intact.^[40] Compared to lithium aluminum hydride (LiAlH₄), lithium borohydride offers advantages in ether-soluble reactions, as it exhibits good solubility in tetrahydrofuran (THF) and diethyl ether, facilitating homogeneous conditions without the vigorous reactivity of LiAlH₄ that can lead to side reactions. This milder profile, combined with its commercial availability at 95% purity from suppliers like Sigma-Aldrich, makes it a practical choice for laboratory-scale organic transformations.^[41]^[42] Advancements highlight its utility in methanol-assisted protocols, which enhance chemoselectivity for ester reductions under mild conditions, as detailed in established procedures adaptable to batch processes. Such methods support scalability in synthetic routes, though challenges persist, including a lab-scale cost of approximately $50–100 per gram and the necessity for storage under argon to mitigate moisture-induced decomposition.^[42]^[4]^[43]

Hydrogen storage

Lithium borohydride (LiBH₄) is recognized as a promising material for solid-state hydrogen storage due to its exceptionally high theoretical hydrogen capacity of 18.5 wt% and 123 g H₂/L, which exceeds the U.S. Department of Energy (DOE) ultimate targets of 4.5 wt% and 32 g H₂/L for onboard automotive systems.^[44]^[45]^[46] This gravimetric and volumetric density positions LiBH₄ favorably for applications requiring compact energy storage, such as fuel cell vehicles and stationary power systems, where it can theoretically deliver an energy density of approximately 22.2 MJ/kg—though practical systems must address reversibility and efficiency losses.^[3] A primary challenge in utilizing LiBH₄ for hydrogen storage is its high thermodynamic stability, resulting in desorption temperatures above 400 °C, which hinders practical reversibility and kinetics.^[5] To mitigate this, researchers have developed reactive hydride composites, such as the 2LiBH₄ + MgH₂ system, which undergoes the reversible reaction 2LiBH₄ + MgH₂ ⇌ 2LiH + MgB₂ + 4 H₂, offering a theoretical capacity of 11.5 wt% H₂ with reduced enthalpy (approximately 45 kJ/mol H₂) compared to pure LiBH₄ (67 kJ/mol H₂).^[47]^[48] Additionally, nanoconfinement strategies, including infiltration into carbon scaffolds like activated carbon or graphene oxide, have been explored in studies from 2021 to 2024 to enhance surface area and lower activation barriers, enabling partial desorption at temperatures as low as 300 °C while preserving up to 80% of the theoretical capacity over multiple cycles.^[49]^[50]^[51] Recent engineering advancements have further improved LiBH₄'s viability. In 2024, morphological engineering via surface oxidation and incorporation of NiO nanostructures allowed hydrogen release starting at 250 °C, with 7-8 wt% desorption achieved within 60 minutes at 350 °C, demonstrating enhanced kinetics without significant capacity loss.^[52] A 2021 review highlighted thermodynamic tailoring through additives and reactive composites as key to meeting DOE system-level targets, including 5.5 wt% gravimetric capacity by 2025.^[49] In September 2025, a facile method was developed to regenerate LiBH₄ directly from LiBO₂·2H₂O via ball milling with low-cost Al-rich alloys and Li₂O additives, improving economic viability and reversibility for hydrogen storage.^[53]