In analytical chemistry, a standard solution (titrant or titrator) is a solution containing an accurately known concentration. Standard solutions are generally prepared by dissolving a solute of known mass into a solvent to a precise volume, or by diluting a solution of known concentration with more solvent. A standard solution ideally has a high degree of purity and is stable enough that the concentration can be accurately measured after a long shelf time.

Making a standard solution requires great attention to detail to avoid introducing any risk of contamination that could diminish the accuracy of the concentration. For this reason, glassware with a high degree of precision such as a volumetric flask, volumetric pipette, micropipettes, and automatic pipettes are used in the preparation steps. The solvent used must also be pure and readily able to dissolve the solute into a homogenous solution.

Standard solutions are used for various volumetric procedures, such as determining the concentration of solutions with an unknown concentration in titrations. The concentrations of standard solutions are normally expressed in units of moles per litre (mol/L, often abbreviated to M for molarity), moles per cubic decimetre (mol/dm³), kilomoles per cubic metre (kmol/m³), grams per milliliters (g/mL), or in terms related to those used in particular titrations (such as titres).

Standard solutions can be categorized by the type of analyte used to prepare them. These analytical standards can either be a primary standard or a secondary standard.

Primary standards are compounds with known stoichiometry, high purity, and high stability under standard conditions. The compound must not be hydroscopic to have a mass that accurately represents the exact number of moles when weighed. These characteristics make primary standards reliable for preparing standard solutions with an accurate concentration just by knowing the amount of compound and solvent used. Primary standard solutions are commonly used to determine the concentration of secondary standard solutions through titration. An example of a primary standard is potassium dichromate.

Secondary standards do not satisfy the requirements for a primary standard. A standard solution created from a secondary standard cannot have its concentration accurately known without stoichiometric analysis against a primary standard. An example of a secondary standard is sodium hydroxide, a hydroscopic compound that is highly reactive with its surroundings. The concentration of a standard solution made with sodium hydroxide may fluctuate over time due to the instability of the compound, requiring for calibration using a primary standard before use.

Standard solutions are commonly used for standardization processes in quantitative analysis to minimize error and maintain accuracy in the results.

This is the most common method of standardization which requires one or multiple standards, each containing a known concentration of the same analyte. External standards are analyzed separately from the sample unlike other methods of standardization, hence the name "external". When concentrations of a set of external solutions are plotted against a measured value such as the absorbance of each external solution, a normal calibration curve can be obtained. Multiple samples with unknown concentrations can then be analyzed using this calibration curve which make it a useful tool. The external standardization method can introduce determinate error if the matrix of the unknown solution differs drastically from the external standard. This issue can be accounted for by replicating the matrix of the unknown solution in the external standard with a process called "matrix matching".