90 Micromole per liter = 90,000.00 Nanomole per liter
Conversion Formula
Unit Information
Micromole_per_liter
A unit of molar concentration equal to one millionth of a mole per liter (10⁻⁶ M). Commonly used in biochemical assays, enzyme kinetics, and pharmacological studies. Represents concentrations of hormones, neurotransmitters, and signaling molecules in physiological and research contexts.
Nanomole_per_liter
A unit of molar concentration equal to one billionth of a mole per liter (10⁻⁹ M). Used for measuring very low concentrations in molecular biology, toxicology, and environmental science. Typical for drug metabolites, environmental pollutants, and intracellular signaling molecules.
Conversion Tips
- Remember to check your decimal places for accuracy.
- This conversion is commonly used in international applications.
- Consider the context when choosing precision levels.
- Double-check calculations for critical applications.
Learn More About Concentration
Scientific Overview
Concentration is a measure of the amount of a substance contained in a given volume of solution or mixture. It quantifies how much solute is dissolved in a solvent and is expressed in various units like mol/L, g/L, or percentage.
Historical Background
The concept of concentration developed with the advancement of analytical chemistry in the 18th and 19th centuries. Early methods included specific gravity measurements, while modern precise methods evolved with the development of volumetric analysis.
Real-World Applications
Chemical Analysis
Used in titrations and quantitative chemical measurements.
Pharmaceuticals
Critical for drug formulation and dosage preparation.
Environmental Science
Measures pollutant levels in air, water, and soil.
Food Industry
Controls flavor strength, preservative levels, and nutritional content.
Biological Research
Essential for preparing buffers and culture media.
Interesting Facts
- Molarity (mol/L) is the most common concentration unit in chemistry.
- Parts per million (ppm) is used for very dilute solutions.
- Concentration affects reaction rates in chemical kinetics.
- Biological systems are highly sensitive to concentration changes.
- Homeopathic remedies use extremely high dilutions (very low concentrations).
Key Formulas
Molarity
C = n/VMass Concentration
C = m/VDilution Formula
C₁V₁ = C₂V₂Molality
m = n_solute/m_solventPercentage by Mass
% = (m_solute/m_solution) × 100%