Как написать хлорид магния

Физические свойства

Хлорид магния MgCl — соль щелочного металла магния и хлороводородной кислоты. Белый, плавится без разложения. Хорошо растворяется в воде (слабый гидролиз по катиону).

Относительная молекулярная масса M_r = 95,21; относительная плотность для тв. и ж. состояния d = 2,32; t_пл = 714º C; t_кип = 1370º C;

Способ получения 

1. Хлорид магния можно получить путем взаимодействия магния и разбавленной хлороводородной кислоты, образуются хлорид магния и газ водород:

Mg + 2HCl = MgCl₂ + H₂↑

2. При комнатной температуре, в результате взаимодействия магния и влажного хлора, образуется хлорид магния:

Mg + Cl₂ = MgCl₂

3. Разбавленная хлороводородная кислота реагирует с гидроксидом магния. Взаимодействие хлороводородной кислоты с гидроксидом магния приводит к образованию хлорида магния и воды:

Mg(OH)₂ + 2HCl = MgCl₂ + 2H₂O

4. Карбонат лития взаимодействует с разбавленной соляной кислотой, образуя хлорид магния, углекислый газ и воду:

MgCO₃ + 2HCl = MgCl₂ + CO₂↑ + H₂O

5. Оксид магния взаимодействует с разбавленной соляной кислотой, образуя хлорид магния и воду:

MgO + 2HCl = MgCl₂ + H₂O

6. В результате взаимодействия оксида магния, углерода и хлора при 800 — 1000º С образуется хлорид магния и угарный газ:

MgO + C + Cl₂ = MgCl₂ + CO

Качественная реакция

Качественная реакция на хлорид магния — взаимодействие его с нитратом серебра, в результате реакции происходит образование белого творожного осадка:

1. При взаимодействии с нитратом серебра, хлорид магния образует нитрат магния и осадок хлорид серебра:

MgCl₂ + 2AgNO₃ = Mg(NO₃)₂ + 2AgCl↓

Химические свойства

1. Хлорид магния вступает в реакцию со многими сложными веществами:

1.1. Хлорид магния вступает в реакции с основаниями:

Хлорид магния взаимодействует с разбавленным раствором гидроксида натрия. При этом образуются гидроксид магния и хлорид натрия:

MgCl₂ + 2NaOH = Mg(OH)₂↓ + 2NaCl

1.2. Насыщенный хлорид магния реагирует с концентрированным и горячим гидратом аммиака, образуя гидроксид магния и хлорид аммония:

MgCl₂ + 2(NH₃ · H₂O) = Mg(OH)₂↓ + 2NH₄Cl

From Wikipedia, the free encyclopedia

Magnesium chloride

Names
Other names Magnesium dichloride
Identifiers
CAS Number	7786-30-3  7791-18-6 (hexahydrate)
3D model (JSmol)	Interactive image Interactive image
ChEBI	CHEBI:6636
ChEMBL	ChEMBL1200547
ChemSpider	22987
ECHA InfoCard	100.029.176
EC Number	232-094-6
E number	E511 (acidity regulators, …)
Gmelin Reference	9305
PubChem CID	24584
RTECS number	OM2975000
UNII	59XN63C8VM  02F3473H9O (hexahydrate)
CompTox Dashboard (EPA)	DTXSID5034690
InChI InChI=1S/2ClH.Mg/h2*1H;/q;;+2/p-2  Key: TWRXJAOTZQYOKJ-UHFFFAOYSA-L  InChI=1S/2ClH.Mg/h2*1H;/q;;+2/p-2
SMILES Cl[Mg]Cl [Mg+2].[Cl-].[Cl-]
Properties
Chemical formula	MgCl2
Molar mass	95.211 g/mol (anhydrous) 203.31 g/mol (hexahydrate)
Appearance	white or colourless crystalline solid
Density	2.32 g/cm3 (anhydrous) 1.569 g/cm3 (hexahydrate)
Melting point	714 °C (1,317 °F; 987 K) anhydrous 117 °C (243 °F; 390 K) hexahydrate on rapid heating; slow heating leads to decomposition from 300 °C (572 °F; 573 K)
Boiling point	1,412 °C (2,574 °F; 1,685 K)
Solubility in water	Anhydrous: 52.9 g/(100 mL) (0 °C) 54.3 g/(100 mL) (20 °C) 72.6 g/(100 mL) (100 °C)
Solubility	slightly soluble in acetone, pyridine
Solubility in ethanol	7.4 g/(100 mL) (30 °C)
Magnetic susceptibility (χ)	−47.4·10−6 cm3/mol
Refractive index (nD)	1.675 (anhydrous) 1.569 (hexahydrate)
Structure
Crystal structure	CdCl2
Coordination geometry	(octahedral, 6-coordinate)
Thermochemistry
Heat capacity (C)	71.09 J/(mol·K)
Std molar entropy (S⦵298)	89.88 J/(mol·K)
Std enthalpy of formation (ΔfH⦵298)	−641.1 kJ/mol
Gibbs free energy (ΔfG⦵)	−591.6 kJ/mol
Pharmacology
ATC code	A12CC01 (WHO) B05XA11 (WHO)
Hazards[1]
Occupational safety and health (OHS/OSH):
Main hazards	Irritant
GHS labelling:
Pictograms
Signal word	Warning
Hazard statements	H319, H335
NFPA 704 (fire diamond)	1 0 0
Flash point	Non-flammable
Lethal dose or concentration (LD, LC):
LD50 (median dose)	2800 mg/kg (oral, rat)
Safety data sheet (SDS)	ICSC 0764
Related compounds
Other anions	Magnesium fluoride Magnesium bromide Magnesium iodide
Other cations	Beryllium chloride Calcium chloride Strontium chloride Barium chloride Radium chloride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).  verify (what is  ?) Infobox references

Magnesium chloride is an inorganic compound with the formula MgCl₂. It forms hydrates MgCl₂·nH₂O, where n can range from 1 to 12. These salts are colorless or white solids that are highly soluble in water. These compounds and their solutions, both of which occur in nature, have a variety of practical uses. Anhydrous magnesium chloride is the principal precursor to magnesium metal, which is produced on a large scale. Hydrated magnesium chloride is the form most readily available.^[2]

Production[edit]

Magnesium chloride can be extracted from brine or sea water. In North America, it is produced primarily from Great Salt Lake brine. In the Jordan Valley, it is obtained from the Dead Sea. The mineral bischofite (MgCl₂·6H₂O) is extracted (by solution mining) out of ancient seabeds, for example, the Zechstein seabed in northwest Europe. Some deposits result from high content of magnesium chloride in the primordial ocean.^[3] Some magnesium chloride is made from evaporation of seawater.

In the Dow process, magnesium chloride is regenerated from magnesium hydroxide using hydrochloric acid:

Mg(OH)₂(s) + 2 HCl(aq) → MgCl₂(aq) + 2 H₂O(l)

It can also be prepared from magnesium carbonate by a similar reaction.

Structure, preparation, and general properties[edit]

MgCl₂ crystallizes in the cadmium chloride CdCl₂ motif, which features octahedral Mg centers. Several hydrates are known with the formula MgCl₂·nH₂O, and each loses water upon heating: n = 12 (−16.4 °C), 8 (−3.4 °C), 6 (116.7 °C), 4 (181 °C), 2 (about 300 °C).^[4] In the hexahydrate, the Mg²⁺ is also octahedral, but is coordinated to six water ligands.^[5] The thermal dehydration of the hydrates MgCl₂·nH₂O (n = 6, 12) does not occur straightforwardly.^[6] Anhydrous MgCl₂ is produced industrially by heating the complex salt named hexamminemagnesium dichloride [Mg(NH₃)₆]²⁺(Cl⁻)₂.^[2]

As suggested by the existence of hydrates, anhydrous MgCl₂ is a Lewis acid, although a weak one. One derivative is tetraethylammonium tetrachloromagnesate [N(CH₂CH₃)₄]₂[MgCl₄]. The adduct MgCl₂(TMEDA) is another.^[7] In the coordination polymer with the formula MgCl₂(dioxane)₂, Mg adopts an octahedral geometry.^[8] The Lewis acidity of magnesium chloride is reflected in its deliquescence, meaning that it attracts moisture from the air to the extent that the solid turns into a liquid.

Applications[edit]

Precursor to Mg metal[edit]

Anhydrous MgCl₂ is the main precursor to metallic magnesium. The reduction of Mg²⁺ into metallic Mg is performed by electrolysis in molten salt.^[2][9] As it is also the case for aluminium, an electrolysis in aqueous solution is not possible as the produced metallic magnesium would immediately react with water, or in other words that the water H⁺ would be reduced into gaseous H₂ before Mg reduction could occur. So, the direct electrolysis of molten MgCl₂ in the absence of water is required because the reduction potential to obtain Mg is lower than the stability domain of water on an E_h–pH diagram (Pourbaix diagram).

MgCl₂ → Mg + Cl₂

The production of metallic magnesium at the cathode (reduction reaction) is accompanied by the oxidation of the chloride anions at the anode with release of gaseous chlorine. This process is developed at a large industrial scale.

Dust and erosion control[edit]

Magnesium chloride is one of many substances used for dust control, soil stabilization, and wind erosion mitigation.^[10] When magnesium chloride is applied to roads and bare soil areas, both positive and negative performance issues occur which are related to many application factors.^[11]

Catalysis[edit]

Ziegler-Natta catalysts, used commercially to produce polyolefins, often contain MgCl₂ as a catalyst support.^[12] The introduction of MgCl₂ supports increases the activity of traditional catalysts and allowed the development of highly stereospecific catalysts for the production of polypropylene.^[13]

Magnesium chloride is also a Lewis acid catalyst in aldol reactions.^[14]

Ice control[edit]

Magnesium chloride is used for low-temperature de-icing of highways, sidewalks, and parking lots. When highways are treacherous due to icy conditions, magnesium chloride is applied to help prevent ice from bonding to the pavement, allowing snow plows to clear treated roads more efficiently.

For the purpose of preventing ice from forming on pavement, magnesium chloride is applied in three ways: anti-icing, which involves spreading it on roads to prevent snow from sticking and forming; prewetting, which means a liquid formulation of magnesium chloride is sprayed directly onto salt as it is being spread onto roadway pavement, wetting the salt so that it sticks to the road; and pretreating, when magnesium chloride and salt are mixed together before they are loaded onto trucks and spread onto paved roads. Calcium chloride damages concrete twice as fast as magnesium chloride.^[15] The amount of magnesium chloride is supposed to be controlled when it is used for de-icing as it may cause pollution to the environment.^[16]

Nutrition and medicine[edit]

Magnesium chloride is used in nutraceutical and pharmaceutical preparations.

Cuisine[edit]

Magnesium chloride (E511^[17]) is an important coagulant used in the preparation of tofu from soy milk.

In Japan it is sold as nigari (にがり, derived from the Japanese word for «bitter»), a white powder produced from seawater after the sodium chloride has been removed, and the water evaporated. In China, it is called lushui (卤水).

Nigari or Iushui is, in fact, natural magnesium chloride, meaning that it is not completely refined (it contains up to 5% magnesium sulfate and various minerals). The crystals originate from lakes in the Chinese province of Qinghai, to be then reworked in Japan.

It is an inexpensive dietary supplement providing magnesium, hence its interest in view of a general deficit in our current consumption (to be in full health, the human body must in particular benefit from a balance between calcium and magnesium). It is also an ingredient in baby formula milk.^[18]

Gardening and horticulture[edit]

Because magnesium is a mobile nutrient, magnesium chloride can be effectively used as a substitute for magnesium sulfate (Epsom salt) to help correct magnesium deficiency in plants via foliar feeding. The recommended dose of magnesium chloride is smaller than the recommended dose of magnesium sulfate (20 g/L).^[19] This is due primarily to the chlorine present in magnesium chloride, which can easily reach toxic levels if over-applied or applied too often.^[20]

It has been found that higher concentrations of magnesium in tomato and some pepper plants can make them more susceptible to disease caused by infection of the bacterium Xanthomonas campestris, since magnesium is essential for bacterial growth.^[21]

Occurrence[edit]

Magnesium concentrations in natural seawater are between 1250 and 1350 mg/L, around 3.7% of the total seawater mineral content. Dead Sea minerals contain a significantly higher magnesium chloride ratio, 50.8%. Carbonates and calcium^{[clarification needed]} are essential for all growth of corals, coralline algae, clams, and invertebrates. Magnesium can be depleted by mangrove plants and the use of excessive limewater or by going beyond natural calcium, alkalinity, and pH values.^[22] The most common mineral form of magnesium chloride is its hexahydrate, bischofite.^[23][24] Anhydrous compound occurs very rarely, as chloromagnesite.^[24] Magnesium chloride-hydroxides, korshunovskite and nepskoeite, are also very rare.^[25][26][24]

Toxicology[edit]

Magnesium ions are bitter-tasting, and magnesium chloride solutions are bitter in varying degrees, depending on the concentration.

Magnesium toxicity from magnesium salts is rare in healthy individuals with a normal diet, because excess magnesium is readily excreted in urine by the kidneys. A few cases of oral magnesium toxicity have been described in persons with normal renal function ingesting large amounts of magnesium salts, but it is rare. If a large amount of magnesium chloride is eaten, it will have effects similar to magnesium sulfate, causing diarrhea, although the sulfate also contributes to the laxative effect in magnesium sulfate, so the effect from the chloride is not as severe.

Plant toxicity[edit]

Chloride (Cl⁻) and magnesium (Mg²⁺) are both essential nutrients important for normal plant growth. Too much of either nutrient may harm a plant, although foliar chloride concentrations are more strongly related with foliar damage than magnesium. High concentrations of MgCl₂ ions in the soil may be toxic or change water relationships such that the plant cannot easily accumulate water and nutrients. Once inside the plant, chloride moves through the water-conducting system and accumulates at the margins of leaves or needles, where dieback occurs first. Leaves are weakened or killed, which can lead to the death of the tree.^[27]

See also[edit]

• Acceptable daily intake
• Magnesium oil

Notes and references[edit]

Notes

References

• Handbook of Chemistry and Physics, 71st edition, CRC Press, Ann Arbor, Michigan, 1990.

External links[edit]

• Magnesium Chloride as a De-Icing Agent
• MSDS file for Magnesium Chloride Hexahydrate

From Wikipedia, the free encyclopedia

Magnesium chloride

Names
Other names Magnesium dichloride
Identifiers
CAS Number	7786-30-3  7791-18-6 (hexahydrate)
3D model (JSmol)	Interactive image Interactive image
ChEBI	CHEBI:6636
ChEMBL	ChEMBL1200547
ChemSpider	22987
ECHA InfoCard	100.029.176
EC Number	232-094-6
E number	E511 (acidity regulators, …)
Gmelin Reference	9305
PubChem CID	24584
RTECS number	OM2975000
UNII	59XN63C8VM  02F3473H9O (hexahydrate)
CompTox Dashboard (EPA)	DTXSID5034690
InChI InChI=1S/2ClH.Mg/h2*1H;/q;;+2/p-2  Key: TWRXJAOTZQYOKJ-UHFFFAOYSA-L  InChI=1S/2ClH.Mg/h2*1H;/q;;+2/p-2
SMILES Cl[Mg]Cl [Mg+2].[Cl-].[Cl-]
Properties
Chemical formula	MgCl2
Molar mass	95.211 g/mol (anhydrous) 203.31 g/mol (hexahydrate)
Appearance	white or colourless crystalline solid
Density	2.32 g/cm3 (anhydrous) 1.569 g/cm3 (hexahydrate)
Melting point	714 °C (1,317 °F; 987 K) anhydrous 117 °C (243 °F; 390 K) hexahydrate on rapid heating; slow heating leads to decomposition from 300 °C (572 °F; 573 K)
Boiling point	1,412 °C (2,574 °F; 1,685 K)
Solubility in water	Anhydrous: 52.9 g/(100 mL) (0 °C) 54.3 g/(100 mL) (20 °C) 72.6 g/(100 mL) (100 °C)
Solubility	slightly soluble in acetone, pyridine
Solubility in ethanol	7.4 g/(100 mL) (30 °C)
Magnetic susceptibility (χ)	−47.4·10−6 cm3/mol
Refractive index (nD)	1.675 (anhydrous) 1.569 (hexahydrate)
Structure
Crystal structure	CdCl2
Coordination geometry	(octahedral, 6-coordinate)
Thermochemistry
Heat capacity (C)	71.09 J/(mol·K)
Std molar entropy (S⦵298)	89.88 J/(mol·K)
Std enthalpy of formation (ΔfH⦵298)	−641.1 kJ/mol
Gibbs free energy (ΔfG⦵)	−591.6 kJ/mol
Pharmacology
ATC code	A12CC01 (WHO) B05XA11 (WHO)
Hazards[1]
Occupational safety and health (OHS/OSH):
Main hazards	Irritant
GHS labelling:
Pictograms
Signal word	Warning
Hazard statements	H319, H335
NFPA 704 (fire diamond)	1 0 0
Flash point	Non-flammable
Lethal dose or concentration (LD, LC):
LD50 (median dose)	2800 mg/kg (oral, rat)
Safety data sheet (SDS)	ICSC 0764
Related compounds
Other anions	Magnesium fluoride Magnesium bromide Magnesium iodide
Other cations	Beryllium chloride Calcium chloride Strontium chloride Barium chloride Radium chloride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).  verify (what is  ?) Infobox references

Magnesium chloride is an inorganic compound with the formula MgCl₂. It forms hydrates MgCl₂·nH₂O, where n can range from 1 to 12. These salts are colorless or white solids that are highly soluble in water. These compounds and their solutions, both of which occur in nature, have a variety of practical uses. Anhydrous magnesium chloride is the principal precursor to magnesium metal, which is produced on a large scale. Hydrated magnesium chloride is the form most readily available.^[2]

Production[edit]

Magnesium chloride can be extracted from brine or sea water. In North America, it is produced primarily from Great Salt Lake brine. In the Jordan Valley, it is obtained from the Dead Sea. The mineral bischofite (MgCl₂·6H₂O) is extracted (by solution mining) out of ancient seabeds, for example, the Zechstein seabed in northwest Europe. Some deposits result from high content of magnesium chloride in the primordial ocean.^[3] Some magnesium chloride is made from evaporation of seawater.

In the Dow process, magnesium chloride is regenerated from magnesium hydroxide using hydrochloric acid:

Mg(OH)₂(s) + 2 HCl(aq) → MgCl₂(aq) + 2 H₂O(l)

It can also be prepared from magnesium carbonate by a similar reaction.

Structure, preparation, and general properties[edit]

MgCl₂ crystallizes in the cadmium chloride CdCl₂ motif, which features octahedral Mg centers. Several hydrates are known with the formula MgCl₂·nH₂O, and each loses water upon heating: n = 12 (−16.4 °C), 8 (−3.4 °C), 6 (116.7 °C), 4 (181 °C), 2 (about 300 °C).^[4] In the hexahydrate, the Mg²⁺ is also octahedral, but is coordinated to six water ligands.^[5] The thermal dehydration of the hydrates MgCl₂·nH₂O (n = 6, 12) does not occur straightforwardly.^[6] Anhydrous MgCl₂ is produced industrially by heating the complex salt named hexamminemagnesium dichloride [Mg(NH₃)₆]²⁺(Cl⁻)₂.^[2]

As suggested by the existence of hydrates, anhydrous MgCl₂ is a Lewis acid, although a weak one. One derivative is tetraethylammonium tetrachloromagnesate [N(CH₂CH₃)₄]₂[MgCl₄]. The adduct MgCl₂(TMEDA) is another.^[7] In the coordination polymer with the formula MgCl₂(dioxane)₂, Mg adopts an octahedral geometry.^[8] The Lewis acidity of magnesium chloride is reflected in its deliquescence, meaning that it attracts moisture from the air to the extent that the solid turns into a liquid.

Applications[edit]

Precursor to Mg metal[edit]

Anhydrous MgCl₂ is the main precursor to metallic magnesium. The reduction of Mg²⁺ into metallic Mg is performed by electrolysis in molten salt.^[2][9] As it is also the case for aluminium, an electrolysis in aqueous solution is not possible as the produced metallic magnesium would immediately react with water, or in other words that the water H⁺ would be reduced into gaseous H₂ before Mg reduction could occur. So, the direct electrolysis of molten MgCl₂ in the absence of water is required because the reduction potential to obtain Mg is lower than the stability domain of water on an E_h–pH diagram (Pourbaix diagram).

MgCl₂ → Mg + Cl₂

The production of metallic magnesium at the cathode (reduction reaction) is accompanied by the oxidation of the chloride anions at the anode with release of gaseous chlorine. This process is developed at a large industrial scale.

Dust and erosion control[edit]

Magnesium chloride is one of many substances used for dust control, soil stabilization, and wind erosion mitigation.^[10] When magnesium chloride is applied to roads and bare soil areas, both positive and negative performance issues occur which are related to many application factors.^[11]

Catalysis[edit]

Ziegler-Natta catalysts, used commercially to produce polyolefins, often contain MgCl₂ as a catalyst support.^[12] The introduction of MgCl₂ supports increases the activity of traditional catalysts and allowed the development of highly stereospecific catalysts for the production of polypropylene.^[13]

Magnesium chloride is also a Lewis acid catalyst in aldol reactions.^[14]

Ice control[edit]

Magnesium chloride is used for low-temperature de-icing of highways, sidewalks, and parking lots. When highways are treacherous due to icy conditions, magnesium chloride is applied to help prevent ice from bonding to the pavement, allowing snow plows to clear treated roads more efficiently.

For the purpose of preventing ice from forming on pavement, magnesium chloride is applied in three ways: anti-icing, which involves spreading it on roads to prevent snow from sticking and forming; prewetting, which means a liquid formulation of magnesium chloride is sprayed directly onto salt as it is being spread onto roadway pavement, wetting the salt so that it sticks to the road; and pretreating, when magnesium chloride and salt are mixed together before they are loaded onto trucks and spread onto paved roads. Calcium chloride damages concrete twice as fast as magnesium chloride.^[15] The amount of magnesium chloride is supposed to be controlled when it is used for de-icing as it may cause pollution to the environment.^[16]

Nutrition and medicine[edit]

Magnesium chloride is used in nutraceutical and pharmaceutical preparations.

Cuisine[edit]

Magnesium chloride (E511^[17]) is an important coagulant used in the preparation of tofu from soy milk.

In Japan it is sold as nigari (にがり, derived from the Japanese word for «bitter»), a white powder produced from seawater after the sodium chloride has been removed, and the water evaporated. In China, it is called lushui (卤水).

Nigari or Iushui is, in fact, natural magnesium chloride, meaning that it is not completely refined (it contains up to 5% magnesium sulfate and various minerals). The crystals originate from lakes in the Chinese province of Qinghai, to be then reworked in Japan.

It is an inexpensive dietary supplement providing magnesium, hence its interest in view of a general deficit in our current consumption (to be in full health, the human body must in particular benefit from a balance between calcium and magnesium). It is also an ingredient in baby formula milk.^[18]

Gardening and horticulture[edit]

Because magnesium is a mobile nutrient, magnesium chloride can be effectively used as a substitute for magnesium sulfate (Epsom salt) to help correct magnesium deficiency in plants via foliar feeding. The recommended dose of magnesium chloride is smaller than the recommended dose of magnesium sulfate (20 g/L).^[19] This is due primarily to the chlorine present in magnesium chloride, which can easily reach toxic levels if over-applied or applied too often.^[20]

It has been found that higher concentrations of magnesium in tomato and some pepper plants can make them more susceptible to disease caused by infection of the bacterium Xanthomonas campestris, since magnesium is essential for bacterial growth.^[21]

Occurrence[edit]

Magnesium concentrations in natural seawater are between 1250 and 1350 mg/L, around 3.7% of the total seawater mineral content. Dead Sea minerals contain a significantly higher magnesium chloride ratio, 50.8%. Carbonates and calcium^{[clarification needed]} are essential for all growth of corals, coralline algae, clams, and invertebrates. Magnesium can be depleted by mangrove plants and the use of excessive limewater or by going beyond natural calcium, alkalinity, and pH values.^[22] The most common mineral form of magnesium chloride is its hexahydrate, bischofite.^[23][24] Anhydrous compound occurs very rarely, as chloromagnesite.^[24] Magnesium chloride-hydroxides, korshunovskite and nepskoeite, are also very rare.^[25][26][24]

Toxicology[edit]

Magnesium ions are bitter-tasting, and magnesium chloride solutions are bitter in varying degrees, depending on the concentration.

Magnesium toxicity from magnesium salts is rare in healthy individuals with a normal diet, because excess magnesium is readily excreted in urine by the kidneys. A few cases of oral magnesium toxicity have been described in persons with normal renal function ingesting large amounts of magnesium salts, but it is rare. If a large amount of magnesium chloride is eaten, it will have effects similar to magnesium sulfate, causing diarrhea, although the sulfate also contributes to the laxative effect in magnesium sulfate, so the effect from the chloride is not as severe.

Plant toxicity[edit]

Chloride (Cl⁻) and magnesium (Mg²⁺) are both essential nutrients important for normal plant growth. Too much of either nutrient may harm a plant, although foliar chloride concentrations are more strongly related with foliar damage than magnesium. High concentrations of MgCl₂ ions in the soil may be toxic or change water relationships such that the plant cannot easily accumulate water and nutrients. Once inside the plant, chloride moves through the water-conducting system and accumulates at the margins of leaves or needles, where dieback occurs first. Leaves are weakened or killed, which can lead to the death of the tree.^[27]

See also[edit]

• Acceptable daily intake
• Magnesium oil

Notes and references[edit]

Notes

References

• Handbook of Chemistry and Physics, 71st edition, CRC Press, Ann Arbor, Michigan, 1990.

External links[edit]

• Magnesium Chloride as a De-Icing Agent
• MSDS file for Magnesium Chloride Hexahydrate

Хлорид магния

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Справочник содержит названия веществ и описания химических формул (в т.ч. структурные формулы и скелетные формулы). Введите часть названия или формулу для поиска: Языки: По умолчанию | Все возможные | Из списка | Применить к найденному Хлорид магния Брутто-формула: Cl2Mg CAS# 7786-30-3 Категории: Неорганические соли PubChem CID: 24584 | NSC 529832 Названия Русский: Хлорид магния(IUPAC) магния хлорид хлористый магний English: Aerotex Accelerator MX C-TEK Catalyst G E 511 Ekimac FIX-Mg Freecat MX HMC 23D Magnesium chloride(IUPAC)(CAS) Magnesium dichloride Magnesium(II) chloride Magnogene White Nigari NS Варианты формулы: MgCl2 Mg(+2)Cl(-1)2 $L(1.4)Cl^-hMg^++/hCl^- Вещества, имеющие отношение… Анион: Хлориды Химический состав Реакции, в которых участвует Хлорид магния {M}O + 2H{X} -> {M}{X}2 + H2O , где M = Cu Ca Mg Sr Ba Hg Mn Cr Ni Fe Cd Zn Pb; X = Cl F Br I {M} + 2H{X} -> {M}{X}2 + H2″|^» , где M = Ca Mg Ba Sr Cd Zn; X = Cl F Br I {M} + {Hal}2 = {M}{Hal}2 , где M = Mg Ca Ba Sr Cd Zn; Hal = F Cl Br I {M}(OH)2 + 2H{X} -> {M}{X}2 + 2H2O , где M = Ca Mg Ba Sr Cd Fe Ni Zn Mn; X = F Cl Br I {M}CO3 + 2H{X} -> {M}{X}2 + CO2″|^» + H2O , где M = Ca Mg Ba Sr Cd Zn Be Mn Pb; X = F Cl Br I И ещё 18 реакций…

Хлорид магния
Общие
Систематическое наименование	хлорид магния
Хим. формула	MgCl2
Физические свойства
Молярная масса	95.211 г/моль
Плотность	2,316 г/см³
Термические свойства
Температура
• плавления	714 °C
• кипения	1412 °C
• разложения	300 °C
Химические свойства
Растворимость
• в воде	54,620; 73,4100 г/100 мл
• в этаноле	50 г/100 мл
Структура
Кристаллическая структура	гексагональная
Классификация
Рег. номер CAS	7786-30-3
Приведены данные для стандартных условий (25 °C, 100 кПа), если не указано иное.

Хлори́д ма́гния (хлори́стый ма́гний) — бинарное неорганическое химическое соединение магния с хлором, магниевая соль соляной кислоты. Растворяется в воде, этаноле. Встречается в природе в виде минерала бишофита. Химическая формула [math]displaystyle{ mathsf{stackrel{+2}{Mg}stackrel{-1}{Cl}_2.} }[/math]

Свойства

Бесцветные кристаллы, плотность 2,316 г/см³, температура плавления 713 °C, температура кипения 1412 °C. Хлорид магния весьма гигроскопичен; растворимость в воде при 20 °C — 35,3 % по массе. Хлорид магния образует кристаллогидраты с 1, 2, 4, 6, 8 и 12 молекулами воды. В интервале от −3,4 до 116,7 °C устойчив гидрат [math]displaystyle{ mathsf{MgCl_2 cdot 6 H_2O} }[/math], который встречается в природе в виде минерала бишофита, а в больших количествах получается при упаривании морских рассолов. Хлорид магния образует двойные соли, из которых исключительно важен минерал карналлит [math]displaystyle{ mathsf{KCl cdot MgCl_2 cdot 6 H_2O} }[/math] — источник получения магния и хлорида калия.

Получение

• Безводный хлорид магния можно получить прямым хлорированием магния:

[math]displaystyle{ mathsf{Mg + Cl_2 rightarrow MgCl_2} }[/math]

• Хлорид магния также образуется при взаимодействии оксида магния с хлором при высокой температуре. При этом в присутствии угля данная реакция идёт легче и при гораздо меньших температурах:

[math]displaystyle{ mathsf{2MgO + 2Cl_2 rightarrow 2MgCl_2 + O_2} }[/math]

[math]displaystyle{ mathsf{MgO + C + Cl_2 rightarrow MgCl_2 + CO} }[/math]

• Иногда безводный хлорид магния синтезируют также действием хлороводорода на магний в среде абсолютного спирта. Образующийся сольват хлорида магния со спиртом [math]displaystyle{ mathsf{MgCl_2cdot6C_2H_5OH} }[/math] разрушают в вакууме водоструйного насоса.
• Также для получения безводного хлорида магния обезвоживают бишофит до [math]displaystyle{ mathsf{MgCl_2 cdot 2H_2O} }[/math], а затем сушат в токе хлороводорода при 100—200 °C.
• Получается как побочный продукт при восстановлении титана из тетрахлорида титана.

Химические свойства

• Реагирует с щелочами и с раствором аммиака с образование осадка гидроксида магния:

[math]displaystyle{ mathsf{MgCl_2 + 2NaOH rightarrow Mg(OH)_2downarrow +, 2NaCl} }[/math]

• При добавлении соды к раствору MgCl₂ образуется белый осадок основного карбоната магния:

[math]displaystyle{ mathsf{5MgCl_2 + 5Na_2CO_3 + 2H_2O rightarrow Mg(OH)_2cdot 3MgCO_3downarrow + , Mg(HCO_3)_2 + , 10NaCl} }[/math]

• При взаимодействии с растворимыми гидрокарбонатами (например, с гидрокарбонатом натрия) образуется белый осадок среднего карбоната магния:

[math]displaystyle{ mathsf{MgCl_2 + 2NaHCO_3 rightarrow MgCO_3downarrow +, 2NaCl +, H_2O + CO_2uparrow} }[/math]

[math]displaystyle{ mathsf{2MgCl_2 + LiAlH_4 rightarrow MgH_2 +, LiCl +, AlCl_3} }[/math]

• При упаривании раствора хлорида магния получают кристаллогидрат [math]displaystyle{ mathsf{MgCl_2cdot6H_2O} }[/math], который при нагревании испытывает серию превращений:

[math]displaystyle{ mathsf{MgCl_2 cdot 6H_2O xrightarrow{120^circ C} MgCl_2 cdot 4H_2O + 2H_2O} }[/math]

[math]displaystyle{ mathsf{MgCl_2 cdot 4H_2O xrightarrow{150^circ C} MgCl_2 cdot 2H_2O + 2H_2O} }[/math]

[math]displaystyle{ mathsf{MgCl_2 cdot 2H_2O xrightarrow{240^circ C} MgCl_2 cdot H_2O + H_2O} }[/math]

[math]displaystyle{ mathsf{MgCl_2 cdot H_2O xrightarrow{gt 300^circ C} MgOHCl + HCl} }[/math]

[math]displaystyle{ mathsf{2MgOHCl xrightarrow{gt 400^circ C} Mg_2OCl_2 + H_2O} }[/math]

Применение

• Хлорид магния применяют главным образом в производстве металлического магния, MgCl₂·6H₂O используется для получения магнезиальных цементов.
• Используется для обработки ледяного и снежного покрова в качестве добавки. В результате реакции со снегом вызывает его таяние. Имеет 3-й класс опасности (умеренно опасные вещества) и агрессивные коррозионные свойства^[1]

В пищевой промышленности

Хлорид магния зарегистрирован в качестве пищевой добавки E511.

Является основным компонентом «нигари» (яп. 苦汁, дословно «горький сок») — концентрированного солевого раствора — продукта, получаемого после выпаривания глубинных морских вод и выделения из них морской соли. В состав нигари в небольших количествах входит множество полезных минералов: хлорид натрия, калия, кальция, железо, фосфор, цинк и др. Нигари используется преимущественно для створаживания соевого молока при приготовлении тофу^[2].

Литература

• Третьяков Ю.Д., Мартыненко Л.И., Григорьев А.Н., Цивадзе А.Ю. Неорганическая химия. Химия элементов. — М.: Химия, 2001. — Т. 1. — 472 с. — ISBN 5-7245-1213-0.
• Третьяков Ю. Д., Дроздов А.А., Зломанов В.П., Мазо Г. Н., Спиридонов Ф. М. Неорганическая химия.. — М.: Издательский центр «Академия», 2004. — Т. 2 Химия непереходных элементов. — 368 с. — ISBN 5-7695-1436-1.

Неорганическая химия, Том 2, Третьяков Ю.Д., 2004.

Примечания