Absorbance Calculator

Free Absorbance Calculator for analytical chemistry. Enter variables to compute results with formulas and detailed steps.

Share this calculator

X Facebook LinkedIn

Formula

A = -log₁₀(I/I₀) = ε × l × c

Absorbance equals the negative base-10 logarithm of the ratio of transmitted to incident light intensity. By Beer-Lambert Law, it also equals the product of molar absorptivity (ε), path length (l), and concentration (c).

Worked Examples

Example 1: Determining Concentration from Absorbance

Problem: A solution gives an absorbance of 0.45 at 520 nm. The molar absorptivity at this wavelength is 1500 L/(mol·cm) and the cuvette path length is 1 cm. Find the concentration.

Solution: Using Beer-Lambert Law: A = ε × l × c\nc = A / (ε × l)\nc = 0.45 / (1500 × 1)\nc = 3.0 × 10⁻⁴ mol/L\nTransmittance: T = 10^(-0.45) = 0.3548 = 35.48%

Result: Concentration = 3.0 × 10⁻⁴ M | Transmittance = 35.48%

Example 2: Absorbance from Light Intensities

Problem: A spectrophotometer measures incident light intensity I₀ = 1000 and transmitted intensity I = 250. Calculate the absorbance and percent transmittance.

Solution: Transmittance: T = I / I₀ = 250 / 1000 = 0.25\nPercent Transmittance: %T = 25%\nAbsorbance: A = -log₁₀(T) = -log₁₀(0.25) = 0.6021

Result: A = 0.6021 | T = 25.00% | 75% of light absorbed

Frequently Asked Questions

What is absorbance and how is it measured?

Absorbance (A) is a dimensionless quantity that measures how much light a sample absorbs at a particular wavelength. It is defined as the negative logarithm (base 10) of transmittance: A = -log10(T), where T = I/I0 is the ratio of transmitted light intensity (I) to incident light intensity (I0). Absorbance is measured using a spectrophotometer, which passes monochromatic light through a sample and detects how much light emerges. Higher absorbance values indicate more light absorbed. Typical absorbance values in analytical chemistry range from 0.1 to 1.0 for accurate measurements, as values above 2.0 mean over 99% of light is absorbed and measurements become unreliable.

How do I convert between absorbance and transmittance?

Absorbance (A) and transmittance (T) are inversely related through a logarithmic function. To convert transmittance to absorbance: A = -log10(T), where T is expressed as a decimal fraction (0 to 1). To convert absorbance to transmittance: T = 10^(-A). Percent transmittance (%T) is simply T multiplied by 100. For example, if %T = 50%, then T = 0.50 and A = -log10(0.50) = 0.301. If A = 1.0, then T = 10^(-1) = 0.10 or 10% transmittance, meaning 90% of light was absorbed. An absorbance of 2.0 corresponds to only 1% transmittance. This logarithmic relationship means that absorbance is more useful for quantitative analysis because it is linearly proportional to concentration.

What are common sources of error in absorbance measurements?

Several factors can introduce errors into absorbance measurements. Instrumental errors include stray light (light reaching the detector without passing through the sample), which causes negative deviations from Beer's Law at high absorbance values. Non-monochromatic light sources reduce accuracy because epsilon varies with wavelength. Chemical errors arise from concentration-dependent equilibria, solute-solvent interactions, and pH-dependent speciation changes. Sample preparation errors include fingerprints or scratches on cuvettes, air bubbles in the solution, and improper blank corrections. Temperature fluctuations affect both molar absorptivity and solution volume. To minimize errors, work in the absorbance range of 0.2 to 0.8, use matched cuvettes, calibrate with standards, and maintain consistent temperature throughout measurements.

How accurate are the results from Absorbance Calculator?

All calculations use established mathematical formulas and are performed with high-precision arithmetic. Results are accurate to the precision shown. For critical decisions in finance, medicine, or engineering, always verify results with a qualified professional.

Can I use the results for professional or academic purposes?

You may use the results for reference and educational purposes. For professional reports, academic papers, or critical decisions, we recommend verifying outputs against peer-reviewed sources or consulting a qualified expert in the relevant field.

How do I get the most accurate result?

Enter values as precisely as possible using the correct units for each field. Check that you have selected the right unit (e.g. kilograms vs pounds, meters vs feet) before calculating. Rounding inputs early can reduce output precision.