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Magnesium bicarbonate

Magnesium bicarbonate, with the Mg(HCO₃)₂ (or C₂H₂MgO₆), is the of magnesium. It occurs naturally in some mineral waters and , characterized by its instability in solid form and primary existence in aqueous solutions. It features a molecular weight of 146.34 g/mol and decomposes readily upon heating or drying, yielding magnesium (MgCO₃), (CO₂), and water according to the reaction Mg(HCO₃)₂ → MgCO₃ + H₂O + CO₂. This exhibits properties in solution due to the ion's ability to accept protons, contributing to its role in buffering. In industrial applications, magnesium bicarbonate is utilized in processes, such as softening, where it reacts with () to precipitate magnesium as magnesium carbonate and adjust hardness and . For instance, in , the reaction Mg(HCO₃)₂ + Ca(OH)₂ → MgCO₃ ↓ + CaCO₃ ↓ + 2H₂O helps remove temporary hardness from supplies. It also finds use in , where dilute solutions of magnesium bicarbonate, often combined with , are employed for washing treatments to neutralize acids and stabilize without causing fiber damage. From a perspective, magnesium bicarbonate is notable for its when added to , providing a soluble source of magnesium that can elevate magnesium levels and influence urinary . Clinical studies have demonstrated that short-term consumption of magnesium bicarbonate-supplemented increases magnesium absorption in postmenopausal women, potentially supporting bone and acid-base , though long-term effects require further research. Its formation constants with magnesium and / ions have been studied under hydrothermal conditions up to 150°C, highlighting its relevance in geochemical processes like mineral solubility and CO₂ .

Chemical identity

Formula and molecular structure

Magnesium bicarbonate has the \ce{Mg(HCO3)2}, consisting of one magnesium cation (\ce{Mg^{2+}}) and two anions (\ce{HCO3^{-}}). This ionic compound has a of 146.34 /mol, determined from the sum of the atomic masses of magnesium (24.305 /mol), two hydrogens (2 × 1.008 /mol), two carbons (2 × 12.011 /mol), and six oxygens (6 × 15.999 /mol). In , magnesium exists as an ionic , with the \ce{Mg^{2+}} cation electrostatically interacting with the two \ce{HCO3^{-}} anions. The features a central carbon atom in a trigonal planar arrangement, bonded to one hydroxyl group (\ce{O-H}) and two oxygen atoms; the negative charge is delocalized across the two non-protonated oxygens through , resulting in equivalent bond lengths for the two C-O bonds to the non-protonated oxygens of approximately 1.26 each, while the C-OH bond is approximately 1.36 . The of the \ce{HCO3^{-}} is commonly represented with the carbon double-bonded to one oxygen (\ce{C=O}), single-bonded to the hydroxyl oxygen (\ce{C-OH}), and single-bonded to the charged oxygen (\ce{C-O^{-}}), though two forms interchange the double and single bonds between the two oxygens for charge delocalization: \ce{ O=C(OH)-O^{-} <->^{-}O-C(OH)=O } The \ce{Mg^{2+}} pairs with two such anions to form the overall in . Magnesium bicarbonate serves as a derivative of magnesium carbonate, forming when the latter reacts with dissolved to produce .

Nomenclature and related compounds

Magnesium bicarbonate is systematically named magnesium hydrogencarbonate according to IUPAC , reflecting its composition as a salt of magnesium cations and hydrogencarbonate anions. This name emphasizes the hydrogen-containing ion, distinguishing it from simpler carbonates. The compound is more commonly referred to as magnesium bicarbonate in chemical literature and databases. In health and nutritional supplement contexts, it is frequently abbreviated as magnesium bicarb or Mg-bicarb for brevity. Related compounds highlight variations in anion composition while sharing the divalent magnesium cation in magnesium bicarbonate, Mg(HCO₃)₂. Magnesium , MgCO₃, incorporates the anion (CO₃²⁻), which lacks the additional compared to the anion (HCO₃⁻), leading to differences in acidity and solubility behavior. Magnesium , Mg(OH)₂, features anions (OH⁻) instead, resulting in a basic rather than acidic salt with distinct reactivity in aqueous environments. Calcium , Ca(HCO₃)₂, is structurally analogous to its magnesium counterpart, substituting calcium for magnesium but retaining the same anions, which influences its role in geological and biological processes. The term "" originated in early 19th-century chemistry, coined by English chemist in 1814 to describe salts formed by the combination of with a in a 2:1 ratio, effectively indicating "twice the acid" relative to normal carbonates. This nomenclature arose during investigations into derivatives, reflecting the era's understanding of acid-base equivalents before modern ionic theory.

Physical and chemical properties

Solubility and stability

Magnesium bicarbonate exists primarily as a colorless , since it does not form a stable under ordinary conditions; efforts to isolate the yield an unstable white, friable mass that decomposes readily upon drying or exposure to air. The compound exhibits in of approximately 0.077 g per 100 mL at 20°C, although its concentration in solution is typically described through equilibrium dynamics in bicarbonate-carbonic acid systems rather than classical metrics due to the absence of a persistent phase. It is insoluble in solvents such as . Magnesium bicarbonate demonstrates limited stability outside aqueous environments, decomposing upon evaporation or when heated above 50°C to form magnesium carbonate, water, and carbon dioxide; decomposition can reach up to 88% at this temperature under controlled conditions. In solution, its stability is pH-dependent, with optimal persistence in neutral to mildly alkaline conditions around pH 7–9, where bicarbonate ion speciation supports ion pair formation. In aqueous media, magnesium bicarbonate manifests as hydrated species, notably the hexaaqu magnesium cation [Mg(H₂O)₆]²⁺ coordinating with bicarbonate anions (HCO₃⁻) to yield ion pairs such as MgHCO₃⁺, whose formation constants increase with (e.g., log *K ≈ 1.14 at 10°C to 1.75 at 100°C).

Thermal decomposition and reactions

Magnesium bicarbonate decomposes thermally to produce , , and , following the reaction \ce{Mg(HCO3)2 ->[heat] MgCO3 + H2O + CO2} This process occurs readily upon heating or degassing of CO2 from aqueous solutions, typically at temperatures below 100°C, which is lower than for many other metal bicarbonates due to the instability of the bicarbonate ion in solution. In aqueous environments, magnesium bicarbonate participates in the carbonate buffer system, acting as a that helps maintain stability through the equilibria \ce{CO2 + H2O <=> H2CO3 <=> H+ + HCO3-} The presence of Mg²⁺ s forms ion pairs with HCO₃⁻, influencing the overall and in the system via complexation effects. When reacting with strong acids, such as , magnesium bicarbonate liberates CO₂ gas, yielding \ce{Mg(HCO3)2 + 2HCl -> MgCl2 + 2H2O + 2CO2} a typical acid-base neutralization where the bicarbonate acts as a CO₂ source. Throughout these transformations, magnesium retains its +2 oxidation state, consistent with its role as a divalent cation in ionic compounds.

Synthesis and production

Laboratory preparation

Magnesium bicarbonate is commonly prepared in the laboratory by bubbling carbon dioxide gas through a suspension of magnesium carbonate in water, following the reaction: \mathrm{MgCO_3 + CO_2 + H_2O \rightarrow Mg(HCO_3)_2} This method produces a clear solution of the bicarbonate, which is inherently unstable and prone to decomposition if not handled properly. To perform the preparation, finely powdered magnesium carbonate is suspended in cold distilled water to enhance solubility, typically at a concentration allowing for complete reaction without excessive viscosity. Carbon dioxide is then bubbled through the mixture at a controlled rate, often using a gas dispersion tube, until the solid largely dissolves, which may take 1-2 hours depending on the setup. The reaction is monitored by cessation of effervescence or pH stabilization around 8.3. Undissolved magnesium carbonate is removed by filtration under reduced pressure, and the filtrate is stored in sealed containers to prevent carbon dioxide escape and subsequent decomposition. Cold temperatures (e.g., 4-10°C) during the process and storage minimize precipitation and maintain solution clarity. Purity is assessed by measuring (ideally 8.2-8.4 for the ), confirming the absence of significant impurities or unreacted species. An alternative laboratory route involves reacting with dilute , prepared by dissolving in : \mathrm{Mg(OH)_2 + 2H_2CO_3 \rightarrow Mg(HCO_3)_2 + 2H_2O} This reaction occurs spontaneously at ambient and . slurry is added gradually to chilled or a solution, with agitation to ensure thorough mixing and dissolution. Excess hydroxide is avoided to prevent formation of carbonates. The mixture is filtered to remove any insoluble residues, and the solution is stored sealed in a cool environment.

Commercial production methods

Commercial production of magnesium bicarbonate primarily involves the of magnesium-rich sources with under controlled conditions to yield stable aqueous solutions, as the compound is highly soluble and typically not isolated as a solid. One key industrial method entails reacting or magnesium-containing salts, such as magnesium carbonate hydroxide, with pressurized CO2 in to form Mg(HCO3)2 solutions. This occurs spontaneously at ambient temperatures and pressures, producing solutions with magnesium concentrations exceeding 650 mg/L, often up to 1500 mg/L, suitable for further applications. In water treatment and mineralization plants, magnesium-rich brines or dolomitic limestone-derived slurries are carbonated with CO2 to generate bicarbonate solutions. For instance, desalination brines, which are abundant in magnesium ions, undergo pH adjustment and reaction with concentrated CO2 to form bicarbonates, often as part of carbon capture processes where the resulting solutions precipitate into carbonates if needed. As of 2023, such methods are being explored for carbon dioxide removal, leveraging desalination outputs for mineral carbonation. Similarly, in mineral water production, purified water is enriched by adding magnesium salts followed by CO2 dissolution, mimicking natural spring processes to achieve balanced electrolyte profiles. These methods leverage industrial CO2 sources, such as from fermentation or flue gases, to enhance efficiency and reduce costs. Magnesium bicarbonate often emerges as a in facilities and processing, where CO2 injection into magnesium-laden or brines naturally yields the compound during softening or mineralization steps. In rare earth separation industries, it is generated from via CO2 , achieving over 95% conversion rates under optimized conditions like elevated magnesium concentrations and lower temperatures. This approach minimizes waste while providing a source for downstream uses. Purification typically involves filtration to remove undissolved solids like , or to eliminate impurities such as iron, aluminum, and silica (reducing levels below 15 mg/L), and controlled under a CO2 atmosphere to concentrate the without . Chilling to 5-15°C further stabilizes the product, ensuring clarity and preventing . These steps are integrated into continuous processes for . Annual yields are primarily in solution form, supporting markets for enhanced and environmental applications.

Natural occurrence

In mineral waters and geological sources

Magnesium bicarbonate forms geologically through the dissolution of magnesium-rich carbonate rocks, such as (CaMg(CO₃)₂), by carbonated containing dissolved CO₂ that generates (H₂CO₃). This reaction produces soluble calcium and magnesium bicarbonates, contributing to the mineral content of hard waters in carbonate-dominated aquifers. In natural mineral springs, magnesium bicarbonate concentrations typically range from 10 to 100 mg/L as magnesium, though values vary by region; for instance, groundwaters in the Plateaus often exhibit calcium-magnesium bicarbonate types with median magnesium levels around 6 mg/L and up to 168 mg/L. These levels impart temporary to , which arises from the presence of dissolved magnesium and calcium bicarbonates that can precipitate as carbonates upon heating or boiling, releasing CO₂. Notable examples include commercial mineral waters like San Pellegrino from the Italian Alps, which contains approximately 56 mg/L magnesium and 136 mg/L , in the form of bicarbonates including magnesium bicarbonate, and Perrier from , with about 4 mg/L magnesium and 420 mg/L . Analytical detection of magnesium bicarbonate in such waters commonly involves titration methods, such as with EDTA for total (measuring magnesium and calcium) or acid-base titration for to quantify content. Magnesium bicarbonate participates in the global by facilitating CO₂ sequestration in aquifers, where atmospheric CO₂ dissolves into to form ions that bind with magnesium, temporarily storing carbon in solution until potential precipitation as solid in systems. This process enhances carbon retention in geological formations, particularly in carbonate aquifers acting as natural sinks.

In biological systems

Magnesium and ions, constituting magnesium bicarbonate in solution, are components of the inorganic phase of the bone , where they contribute to mineralization by buffering deposition. ions in this matrix help maintain stability during formation, while magnesium ions modulate to prevent excessive . In , approximately 60% of total body magnesium is stored, often in association with and species that support structural integrity. Magnesium exhibits high in the owing to its in aqueous environments, facilitating efficient compared to less soluble magnesium forms. Upon , it dissociates into magnesium and bicarbonate ions, which are readily taken up in the via paracellular and transcellular pathways. In human plasma, total magnesium concentrations typically range from 0.7 to 1.0 , with free ionized magnesium around 0.5-0.7 , reflecting the equilibrium maintained by bicarbonate-assisted transport. In metabolic processes, magnesium bicarbonate supports CO2 transport in blood by providing bicarbonate ions that form in equilibrium with CO2 and water, aiding . Bicarbonate-dependent mechanisms enhance renal of magnesium, where elevated bicarbonate levels increase tubular magnesium retention during acid-base fluctuations. is associated with reduced bicarbonate levels and exacerbated , as promotes renal magnesium losses and impairs buffering capacity. Dietary intake of magnesium bicarbonate occurs indirectly through magnesium-rich vegetables such as and , which also supply bicarbonate precursors via organic anions that metabolize to in the body. Endogenous formation arises from the interaction of magnesium ions with in bodily fluids, particularly in the gastrointestinal and renal systems, where and ion concentrations favor the soluble complex. This formation is evident in and interstitial fluids, contributing to local ion balance without requiring direct dietary sources of the compound.

Applications and uses

Health and nutritional benefits

In terms of regulation, magnesium bicarbonate contributes to maintaining physiological levels (7.35–7.45) by supplying bioavailable that buffers metabolic acids, particularly in conditions like . Consumption of such mineral waters has been shown in clinical trials to elevate urinary (from approximately 6.0 to 6.5–7.0) and decrease net acid excretion by up to 50%, enhancing overall acid-base balance without altering significantly in short-term use. Recent studies from the 2020s, including those on renal patients, indicate that supplementation improves management and may slow kidney function decline, though magnesium bicarbonate specifically offers combined alkali and support; for instance, daily intake of 1,000–2,000 mL of water providing 100–200 mg magnesium and 1,000 mg over 4–12 weeks yielded measurable buffering effects. For bone and muscle health, supports activity essential for bone mineralization and maintenance, while also facilitating muscle relaxation by modulating calcium influx in contractile fibers. The recommended dietary allowance (RDA) for magnesium is 310–420 mg per day for adults, depending on age and sex, and adequate intake is linked to reduced risk in observational data. The form enhances uptake due to its high in aqueous solutions, potentially increasing magnesium levels by 10–20% compared to less soluble salts, as evidenced in supplementation trials where postmenopausal women consuming 180–216 mg daily maintained stable levels indicative of preserved bone metabolism. Cardiovascular benefits of magnesium bicarbonate include risk reduction for through mechanisms like and improved endothelial function. Meta-analyses of supplementation trials up to 2025 show that magnesium intake of 300–400 mg daily lowers systolic by 2–4 mm Hg and diastolic by 1–2 mm Hg, particularly in hypertensive individuals, with inverse associations to incidence (hazard ratio 0.85–0.90 per 100 mg increment). These effects are attributed to magnesium's role in regulation, and bicarbonate forms may amplify for sustained cardiovascular protection. Magnesium bicarbonate is primarily supplemented in liquid forms, such as concentrated solutions derived from mineral waters or effervescent preparations added to , offering superior compared to solid salts. Soluble forms like achieve intestinal uptake rates of 40–60%, far exceeding the 4–10% of , due to better dissolution in gastric fluids; trials confirm over 90% relative efficiency in aqueous media versus oxides' poor . Daily regimens of 1,500–2,000 provide 100–200 mg magnesium with minimal gastrointestinal side effects.

Industrial and environmental applications

Magnesium bicarbonate plays a key role in processes, particularly for softening by facilitating the precipitation of calcium as carbonate through or related methods, where it contributes to managing temporary . In municipal systems, dosages typically range from 50 to 200 mg/L to achieve effective reduction without excessive scaling. This application helps prevent boiler scale and improves for industrial use by converting soluble bicarbonates into insoluble carbonates during treatment. In , magnesium serves as a pH buffering agent for amendment, neutralizing acidity in acidic soils and enhancing in soilless substrates or hydroponic systems. It is applied at concentrations of 10-50 to maintain optimal levels, supporting availability and preventing lockup caused by excessive acidity. This buffering capacity arises from its dissociation into magnesium ions and , which react to stabilize without introducing excess salts. For , magnesium bicarbonate acts as a magnesium source in processes, absorbing by providing that enhances scrubbing efficiency and forms stable compounds. It also contributes to in , neutralizing acidic effluents and supporting precipitation of in industrial discharges. These applications leverage its reversible binding properties to mitigate precursors and improve effluent quality in plants and facilities. Recent developments in the have promoted magnesium bicarbonate in carbon capture solutions, exploiting its reversible CO2 binding to form stable carbonates via mineralization processes, often integrated with magnesium-based sorbents like MgO derivatives. Studies highlight its role in and , where or waste materials react to produce magnesium bicarbonate, sequestering CO2 for millennia with minimal energy input. This approach has gained traction in pilot projects for industrial emissions, offering a scalable, low-cost alternative to amine-based systems.