solvent

A solvent (also solvent or solvent , also menstruum ) is a substance that can dissolve or dilute gases , liquids or solids without causing chemical reactions between the dissolved substance and the solvent [ see also: solution (chemistry) ]. As a rule, liquids such as water and liquid organic substances are used to dissolve other substances. But solids can also dissolve other substances. For example, in the hydrogen tanks of fuel cell powered cars, gaseous hydrogen is dissolved in solid material (metal-organic framework compounds, MOFs for short ).

"Solvent" or "Solvent"

Both terms have been used in literature for over 200 years. In research and laboratory area has solvents established in industrial and technical chemicals industry, however solvent . For example, the Römpp Lexikon Chemie speaks of solvents , while the TRGS (Technical Rules for Hazardous Substances) prefer solvents .

Definition in everyday life

Probably the best known solvent is water. When it comes to paints, varnishes, adhesives, etc., however, the term “solvent” is used to refer to substances that can cause unpleasant smells, damage to health and the environment and explosive vapors. What is meant here are solvents in the sense of TRGS (Technical Rules for Hazardous Substances) 610, according to which only volatile organic solvents with a boiling point of up to 200 ° C are referred to as solvents.

The "high boilers", less volatile substances with boiling points above 200 ° C, are therefore not legally considered solvents. While classic solvents, due to their volatility, have completely evaporated a few hours to days after processing, the high boilers contained in some "solvent-free" products may still be released into the room air for months or years and are therefore sometimes even judged to be significantly more critical than Products with classic solvents.

Avoiding toxic and environmentally harmful substances is part of green chemistry .

chemistry

Although the solvent does not take part in the chemical reaction itself, it is very important for chemical reactions. The effects of the solvent are different and depend on the reaction. By dissolving reactants in a solvent, reactions can be controlled thermally. Concentrations of substances that are dissolved in a solvent only apply to a certain temperature due to the temperature dependence.

The most important tasks of the solvent in chemical reactions are

convective heat and mass transfer
Stabilization of transition states of the reaction
Dilution to avoid side reactions

Solvents also play an important role in the purification and processing of reaction mixtures ( downstream process ). Some important procedures are named here as examples:

Market economy aspects

The most important group of solvents are alcohols such as ethanol, n -butanol, isopropanol and methanol. In 2011, around 6.4 million tons of this were in demand worldwide. An above-average increase in consumption of more than 3% annually is expected for ethanol and ethers in the period 2011 to 2019. In addition to halogenated solvents, which are continuing their downward trend in Western Europe and North America, aromatics and pure hydrocarbons will continue to lose importance in the long term.

Dissolving properties

The quantitative prediction of dissolving properties is difficult and often defies intuition . General rules can be drawn up, but they can only be used as a rough guide.

Polar substances generally dissolve well in polar solvents (e.g. salts in water). Non-polar substances generally dissolve well in non-polar solvents (e.g. non-polar organic substances in benzene or ether).

Solvents are usually divided into classes according to their physical properties. Such classification criteria are e.g. B .:

Aprotic solvents

If a molecule does not have a functional group from which hydrogen atoms in the molecule can be split off as protons (dissociation), one speaks of an aprotic solvent. These are opposed to the protic solvents .

Aprotic-non-polar

Alkanes are non-polar because of the small difference in electronegativity between carbon and hydrogen . This makes all substances of these groups easily soluble in one another; they are very lipophilic (actually even more lipophilic than the very weakly polar, eponymous fats) and very hydrophobic (water-repellent). But not only water cannot dissolve, but also all other strongly polar substances, such as B. short-chain alcohols , hydrogen chloride or salts . In the liquid, the particles are only held together by van der Waals forces . This is why the boiling temperatures of this group of substances are significantly lower in comparison to the molecular size and mass than with permanent dipoles . Since protons can only be split off with the formation of carbanions with extremely strong bases, they are aprotic . The group of aprotic non-polar solvents also includes compounds such as carboxylic acid esters or ethers, which contain polar bonds but are not able to dissolve ionic compounds due to their low permittivity .

Representatives of this group are:

Alkanes (paraffins)
Alkenes (olefins), alkynes
Benzene and other aromatics with aliphatic and aromatic substituents
Carboxylic acid ester
Ethers , e.g. B. diethyl ether
completely symmetrically built molecules such as tetramethylsilane or carbon tetrachloride
Carbon disulfide , at high pressure also carbon dioxide

halogenated hydrocarbons which are either completely non-polar (such as carbon tetrachloride) or despite the high electronegativity of the halogen in question, e.g. B. chlorine, are only slightly polar ( methylene chloride )

A special subgroup of halogenated hydrocarbons are the perfluorinated hydrocarbons (e.g. hexafluorobenzene ), which are not only non-polar themselves, but also very difficult to polarize from the outside and therefore also tend to be poorly compatible with the other non-polar solvents.

Aprotically polar

However, if the molecule is substituted with strongly polar functional groups such as the carbonyl group , the nitro group or the nitrile group , then the molecule has a dipole moment , so that there is now an intermolecular electrostatic attraction of permanent dipoles to the still present (but much weaker) van der- Waals forces added. This results in a substantial increase in the boiling point and in many cases a deterioration in the miscibility with non-polar solvents and an improvement in the solubility of and in polar substances. Typical aprotic polar solvents have a permittivity greater than 15 and are able to solvate cations . Since the anions are hardly solvated ( naked anions ), they show a high S _N 2 reactivity. Such solvents are eminently suitable for carrying out nucleophilic substitutions under mild conditions. This includes:

Ketones , e.g. B. acetone
Lactones such as γ-butyrolactone
Lactams such as N -methyl-2-pyrrolidone
Nitriles such as acetonitrile
Nitro compounds such as nitromethane
tertiary carboxamides such as dimethylformamide
Urea derivatives such as tetramethyl urea or dimethyl propylene urea (DMPU)

Sulfoxides such as dimethyl sulfoxide (DMSO)

Sulfones such as sulfolane

Carbonic acid esters such as dimethyl carbonate or ethylene carbonate

Protic solvents

As soon as a molecule has a functional group from which hydrogen atoms in the molecule can be split off as protons ( dissociation ), one speaks of a protic solvent. These contrast with the aprotic solvents .

The most important protic solvent is water , which (in simplified terms) dissociates into a proton and a hydroxide ion.

Other protic solvents are e.g. B. Alcohols and carboxylic acids . Here the proton is always split off at the OH group, since the electronegative oxygen can easily absorb the negative charge.

The degree to which the respective solvent dissociates is determined by the acidity (according to the acid-base concept of Brønsted and Lowry ). It should be noted that hydrogen atoms bonded to carbon can also be split off as protons ( CH acidity ), but the acidity of these compounds is usually too low to allow significant dissociation in a neutral medium. The release of these protons is only possible with very strong bases.

Polar protic solvents dissolve salts and polar compounds, while the solubility of non-polar compounds is low.

Protic solvents are:

Water , the most important solvent of all, especially in living nature
Methanol , ethanol and other alcohols (the larger the carbon structure, the less pronounced the polar character; cholesterol, for example, is an alcohol but still highly lipophilic)
primary and secondary amines
Carboxylic acids ( formic acid , acetic acid )
primary and secondary amides such as formamide
Mineral acids ( sulfuric acid , hydrogen halides or hydrohalic acids)

Polarity scales

Reichardt dye

A well-known scale for the polarity of a solvent is the E _T (30) or E _T^N scale . It is derived from empirical spectroscopic measurements. The E _T (30) value is defined as the transition energy of the longest-wave Vis / NIR absorption band in a solution with the negatively solvatochromic Reichardt dye (betaine 30) under normal conditions in kcal · mol ⁻¹ . The E _T^N value is the E _T (30) value normalized to the polarity extremes tetramethylsilane (= 0) and water (= 1) .

Table with solvents and their data

solvent	Melting point [° C]	Siedep. [° C]	Flammp. [° C]	Density [g / cm ³ ] at 20 ° C	Permittivity at 25 ° C	Dipole moment [· 10 ⁻³⁰ cm]	Refractive index ${\ displaystyle n _ {\ mathrm {D}} ^ {20}}$	${\ displaystyle E _ {\ tau} (30)}$ [kJ / mol]	Compressibility [ 10 −6 ^/ bar]
acetone	−95.35	56.2	−19	0.7889	20.70	9.54	1.3588	176.4	126
Acetonitrile	−45.7	81.6	13	0.7857	37.5 (20 ° C)	11.48	1.3442	192.3	115
aniline	−6.3	184	76	1.0217	6.89 (20 ° C)	5.04	1.5863	185.2	-
Anisole	−37.5	155.4	41	0.9961	4.33	4.17	1.5179	155.5	-
benzene	5.5	80.1	−8	0.87565	2.28	0.0	1.5011	142.2	95
Benzonitrile	−13	190.7	70	1.0102 (15 ° C)	25.20	13.51	1.5289	175.6	-
Bromobenzene	−30.8	156	51	1.4950	5.40	5.17	1.5597	156.8	-
1-butanol	−89.8	117.3	34	0.8098	17.51	5.84	1.3993	209.8	-
tert -butyl methyl ether (MTBE)	−108.6	55.3	−28	0.74	?	?	1.3690	145.2	-
γ-butyrolactone	−44	204-206	101	1.13	39.1	4.12	1,436	-	-
Quinoline	−15.6	238	101	1.0929	9.00	7.27	1.6268	164.7	-
Chlorobenzene	−45.6	132	28	1.1058	5.62	5.14	1.5241	156.8	-
chloroform	−63.5	61.7	-	1.4832	4.81 (20 ° C)	3.84	1.4459	163.4	100
Cyclohexane	6.5	80.7	4.5	0.7785	2.02 (20 ° C)	0.0	1.4266	130.4	118
Dibutyl ether	−98	142.5	25th	0.764	4.34 (20 ° C)	3.9	1,399	187.6	-
Diethylene glycol	−6.5	244.3	124	1.1197 (15 ° C)	7.71	7.71	1.4475	224.9	-
Diethyl ether	−116.2	34.5	−40	0.7138	4.34 (20 ° C)	4.34	1.3526	144.6	-
Dimethylacetamide	−20	165	66	0.9366 (25 ° C)	37.78	12.41	1.4380	182.7	-
Dimethylformamide	−60.5	153	67	0.9487	37.0	12.88	1.4305	183.1	-
Dimethyl sulfoxide	18.4	189	88	1.1014	46.68	13.00	1.4770	188.1	-
1,4-dioxane	11.8	101	12	1.0337	2.21	1.5	1.4224	150.0	-
Glacial acetic acid	16.6	117.9	42	1.0492	6.15 (20 ° C)	5.60	1.3716	214.0	-
Acetic anhydride	−73.1	139.5	49	1.0820	20.7 (19 ° C)	9.41	1.3900	183.5	-
Ethyl acetate	−83.6	77.06	−2	0.9003	6.02	6.27	1.3723	159.3	104
Ethanol	−114.5	78.3	18th	0.7893	24.55	5.77	1.3614	216.9	114
1,2-dichloroethane (ethylene dichloride)	−35.3	83.5	13	1.2351	10.36	6.2	1.4448	175.1	-
Ethylene glycol	−13	197	117	1.1088	37.7	7.61	1.4313	235.3	-
Ethylene glycol dimethyl ether	−58	84	−6	0.8628	7.20	5.70	1.3796	159.7	-
Formamide	2.5	210.5	175	1.1334	111.0 (20 ° C)	11.24	1.4472	236.6	-
n -hexane	−95	68	−20	0.6603	1.88	0.0	1.3748	129.2	150
n -heptane	−91	98	−4	0.684	1.97	0.0	1.387	130.1	120
2-propanol (isopropyl alcohol)	−89.5	82.3	16	0.7855	19.92	5.54	1.3776	203.1	100
Methanol	−97.8	64.7	6.5	0.7914	32.70	5.67	1.3287	232.0	120
3-methyl-1-butanol (isoamyl alcohol)	−117.2	130.5	42	0.8092	14.7	6.07	1.4053	196.5	-
2-methyl-2-propanol ( tert- butanol)	25.5	82.5	9	0.7887	12.47	5.54	1.3878	183.1	-
Methylene chloride (dichloromethane, DCM)	−95.1	40	-	1.3266	8.93	5.17	1.4242	171.8	-
Methyl ethyl ketone (butanone)	−86.3	79.6	−4	0.8054	18.51 (20 ° C)	9.21	1.3788	172.6	-
N -Methyl-2-pyrrolidone (NMP)	−24	202	245	1.03	32.2	4.09	1.47	-	-
N -methylformamide	−3.8	183	111	1.011 (19 ° C)	182.4	12.88	1.4319	226.1	-
Nitrobenzene	5.76	210.8	81	1.2037	34.82	13.44	1.5562	175.6	-
Nitromethane	−28.5	100.8	35	1.1371	35.87 (30 ° C)	11.88	1.3817	193.5	-
n -pentane	−130	36	−49	0.6262	-	-	1.358	129.7	-
Petroleum ether / light petrol	-	25-80	-26	0.63-0.83	-	-	-	-	-
Piperidine	−9	106	4th	0.8606	5.8 (20 ° C)	3.97	1.4530	148.4	-
Propanol	−126.1	97.2	24	0.8035	20.33	5.54	1.3850	211.9	100
Propylene carbonate (4-methyl-1,3-dioxol-2-one)	−48.8	241.7	130	1.2069	65.1	16.7	1.4209	195.6	-
Pyridine	−42	115.5	23	0.9819	12.4 (21 ° C)	7.91	1.5095	168.0	-
Carbon disulfide	−110.8	46.3	−30	1.2632	2.64 (20 ° C)	0.0	1.6319	136.3	-
Sulfolane	27	285	177	-	43.3 (30 ° C)	16.05	1.4840	183.9	-
Tetrachlorethylene	−19	121	-	1.6227	2.30	0.0	1.5053	133.3	-
Carbon tetrachloride	−23	76.5	-	1.5940	2.24 (20 ° C)	0.0	1.4601	135.9	110
Tetrahydrofuran	−108.5	66	−22.5	0.8892	7.58	5.84	1.4070	156.3	-
toluene	−95	110.6	7th	0.8669	2.38	1.43	1.4961	141.7	87
1,1,1-trichloroethane	−30.4	74.1	-	1.3390	7.53 (20 ° C)	5.24	1.4379	151.3	-
Trichlorethylene	−73	87	-	1.4642	3.42 (16 ° C)	2.7	1.4773	150.1	-
Triethylamine	−114.7	89.3	−7	0.7275	2.42	2.90	1.4010	139.2	-
Triethylene glycol	−5	278.3	166	1.1274 (15 ° C)	23.69 (20 ° C)	9.97	1.4531	223.6	-
Triethylene glycol dimethyl ether (triglyme)	-	222	113	-	7.5	-	1.4233	161.3	-
water	0.0	100	-	0.9982	78.39	6.07	1.3330	263.8	46

Table with alcoholic solvents and their evaporation rates

relative to acetic acid n- butyl ester (= 1)

solvent	Siedep. [° C]	Evaporation rate
Methanol	65	2.1
Ethanol	78	1.6
2-propanol	82	1.4
tert -butanol	83	0.95
tert -amyl alcohol	102	0.93
1-propanol	97	0.86
2-butanol	100	0.81
2-methyl-1-propanol	108	0.62
1-butanol	118	0.44
4-methyl-2-pentanol (MIBC)	132	0.3
1-pentanol (amyl alcohol)	137	0.2
Diacetone alcohol	166	0.14
2-ethyl-1-butanol	146	0.11
Hexanol	148	0.096
Cyclohexanol	161	0.05
Tetrahydrofurfuryl alcohol	178	0.03
2-ethylhexanol	185	0.02
2-octanol	177	0.018
1-octanol	196	0.007
Benzyl alcohol	205	0.007
1-decanol	231	0.001

Indifferent solvents

In polymer chemistry, an inert or neutral solvent is understood to mean a medium which

Termination and transfer reactions of polymerizations and thus also the rate and degree of polymerization little or no influence.

has the same solution properties for all domains of a block copolymer (the opposite is a selective solvent).

literature

C. Reichardt: Solvents and Solvent Effects in Organic Chemistry . Wiley-VCH Verlag, Weinheim 1979 (1st edition), 1988 (2nd edition), 2003 (3rd edition), 2010 (4th edition; with T. Welton).

Web links

Properties of solvents (Engl.)

Wiktionary: Solvents - explanations of meanings, word origins, synonyms, translations

Commons : Solvent - collection of images, videos, and audio files

Individual evidence

↑ TRGS (baua.de) .
↑ Product group adhesives (lga.de) ( Memento from September 16, 2010 in the Internet Archive )
↑ Ceresana solvent market study .
↑ Entry on aprotic solvents. In: Römpp Online . Georg Thieme Verlag, accessed on 2014-06-03.
^ Alan R. Katritzky, Dan C. Fara, Hongfang Yang, Kaido Tämm et al .: Quantitative Measures of Solvent Polarity , p. 183 Spectroscopic Measurements .
↑ Karl Dimroth , Christian Reichardt , Theodor Siepmann, Ferdinand Bohlmann : About pyridinium- N -phenol-betaine and their use to characterize the polarity of solvents . In: Justus Liebig's Annals of Chemistry . tape 661 , no. 1 , February 18, 1963, p. 1-37 , doi : 10.1002 / jlac.19636610102 ( PDF ).
^ AG Reichardt: E _T (30) values of the aliphatic, cycloaliphatic, aromatic ethers, thioethers and acetals and alkanes
↑ Agilent Technologies : Table 9: Compressibility of solvents. (PDF; 5.1 MB) February 2009, archived from the original on July 31, 2013 ; Retrieved July 31, 2013 .
↑ Nicholas P. Cheremisinoff: Industrial Solvents Handbook . 2nd Edition. Marcel Dekker, 2003, ISBN 0-8247-4033-5 , p. 6 .
^ MD Lechner, K. Gehrke, EH Nordmeier, Makromolekulare Chemie, 4th edition, Basel 2010, p. 160.
↑ H.-G. Elias, Makromoleküle Volume 1, 5th edition, Basel 1990, p. 797.

[1] TRGS (baua.de) .

[2] Product group adhesives (lga.de) ( Memento from September 16, 2010 in the Internet Archive )

[3] Ceresana solvent market study .

[4] Entry on aprotic solvents. In: Römpp Online . Georg Thieme Verlag, accessed on 2014-06-03.

[5] Alan R. Katritzky, Dan C. Fara, Hongfang Yang, Kaido Tämm et al .: Quantitative Measures of Solvent Polarity , p. 183 Spectroscopic Measurements .

[6] Karl Dimroth , Christian Reichardt , Theodor Siepmann, Ferdinand Bohlmann : About pyridinium- N -phenol-betaine and their use to characterize the polarity of solvents . In: Justus Liebig's Annals of Chemistry . tape 661 , no. 1 , February 18, 1963, p. 1-37 , doi : 10.1002 / jlac.19636610102 ( PDF ).

[7] AG Reichardt: E _T (30) values of the aliphatic, cycloaliphatic, aromatic ethers, thioethers and acetals and alkanes

[8] Agilent Technologies : Table 9: Compressibility of solvents. (PDF; 5.1 MB) February 2009, archived from the original on July 31, 2013 ; Retrieved July 31, 2013 .

[9] Nicholas P. Cheremisinoff: Industrial Solvents Handbook . 2nd Edition. Marcel Dekker, 2003, ISBN 0-8247-4033-5 , p. 6 .

[10] MD Lechner, K. Gehrke, EH Nordmeier, Makromolekulare Chemie, 4th edition, Basel 2010, p. 160.

[11] H.-G. Elias, Makromoleküle Volume 1, 5th edition, Basel 1990, p. 797.