Solvents can be broadly classified into two categories:
polar and
non-polar. A special case is elemental
mercury, whose solutions are known as
amalgams; also, other
metal solutions exist which are liquid at room temperature. Generally, the
dielectric constant of the solvent provides a rough measure of a solvent's polarity. The strong polarity of water is indicated by its high dielectric constant of 88 (at 0 °C). Solvents with a dielectric constant of less than 15 are generally considered to be nonpolar. The dielectric constant measures the solvent's tendency to partly cancel the field strength of the electric field of a
charged particle immersed in it. This reduction is then compared to the
field strength of the charged particle in a vacuum.
Donor number and donor acceptor scale measures polarity in terms of how a solvent interacts with specific substances, like a strong
Lewis acid or a strong Lewis base. The
Hildebrand parameter is the square root of
cohesive energy density. It can be used with nonpolar compounds, but cannot accommodate complex chemistry. Reichardt's dye, a
solvatochromic dye that changes color in response to polarity, gives a scale of
ET(30) values.
ET is the transition energy between the ground state and the lowest excited state in kcal/mol, and (30) identifies the dye. Another, roughly correlated scale (
ET(33)) can be defined with
Nile red. Gregory's solvent ϸ parameter is a quantum chemically derived charge density parameter. This parameter seems to reproduce many of the experimental solvent parameters (especially the donor and acceptor numbers) using this charge decomposition analysis approach, with an electrostatic basis. The ϸ parameter was originally developed to quantify and explain the
Hofmeister series by quantifying polyatomic ions and the monatomic ions in a united manner. The polarity, dipole moment, polarizability and
hydrogen bonding of a solvent determines what type of
compounds it is able to dissolve and with what other solvents or liquid compounds it is
miscible. Generally, polar solvents dissolve polar compounds best and non-polar solvents dissolve non-polar compounds best; hence "
like dissolves like". Strongly polar compounds like
sugars (e.g.
sucrose) or ionic compounds, like
inorganic salts (e.g.
table salt) dissolve only in very polar solvents like water, while strongly non-polar compounds like
oils or
waxes dissolve only in very non-polar organic solvents like
hexane. Similarly, water and
hexane (or
vinegar and vegetable oil) are not
miscible with each other and will quickly separate into two layers even after being shaken well. Polarity can be separated to different contributions. For example, the
Kamlet-Taft parameters are dipolarity/polarizability (
π*), hydrogen-bonding acidity (
α) and hydrogen-bonding basicity (
β). These can be calculated from the wavelength shifts of 3–6 different solvatochromic dyes in the solvent, usually including
Reichardt's dye,
nitroaniline and
diethylnitroaniline. Another option,
Hansen solubility parameters, separates the cohesive energy density into dispersion, polar, and hydrogen bonding contributions.
Polar protic and polar aprotic Solvents with a dielectric constant (more accurately,
relative static permittivity) greater than 15 (i.e. polar or polarizable) can be further divided into
protic and aprotic. Protic solvents, such as
water, solvate
anions (negatively charged solutes) strongly via
hydrogen bonding.
Polar aprotic solvents, such as
acetone or
dichloromethane, tend to have large
dipole moments (separation of partial positive and partial negative charges within the same molecule) and solvate positively charged species via their negative dipole. In
chemical reactions the use of polar protic solvents favors the
SN1 reaction mechanism, while polar aprotic solvents favor the
SN2 reaction mechanism. These polar solvents are capable of forming hydrogen bonds with water to dissolve in water whereas non-polar solvents are not capable of strong hydrogen bonds. ==Physical properties==