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🌈 UV Spectroscopy Calculator

Beer-Lambert Law, Molar Absorptivity and Transmittance ↔ Absorbance converter — all in one page.

Beer-Lambert Law
A = ε × c × l
Transmittance ↔ Absorbance Converter
A = −log(T)    T = 10^(−A)
Type a value in either field to convert
LOD & LOQ Calculator (ICH Q2(R1))
LOD = 3.3σ/S    LOQ = 10σ/S
LOD
LOQ
📖 Example (Beer-Lambert): ε = 6,220 L mol⁻¹ cm⁻¹, path length = 1 cm, absorbance = 0.310 → concentration = 0.310 ÷ (6220 × 1) = 4.98 × 10⁻⁵ mol/L. Cite as: "Concentration determined by UV absorbance at 260 nm using Beer-Lambert law (Scitero UV Spectroscopy Calculator, scitero.com)."
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Beer-Lambert

Solve for any variable — absorbance, concentration, molar absorptivity or path length.

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Type in either field — Transmittance ↔ Absorbance converts as you type.

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⚠️ Verify before use: Beer-Lambert assumes dilute solutions with no scattering or chemical interactions affecting absorbance. Double-check critical results independently, especially near the edges of your instrument's linear range.
✔ Formulas last verified against primary references: March 2025  ·  Report an error
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Beer-Lambert law: practical application in analytical labs

Beer-Lambert law (A = εcl) is the foundation of UV-Vis spectrophotometry. To apply it: measure absorbance at the analyte's wavelength maximum, use a 1 cm path length cuvette, and know ε from literature or a calibration curve. Linear range is typically A = 0.05–1.0; above A = 1.0 stray light causes detector non-linearity. For nucleic acids: DNA at 260 nm, ε ≈ 6600 L mol−1 cm−1 per base pair. LOD = 3.3σ/S and LOQ = 10σ/S per ICH Q2(R1), where σ is the residual standard deviation of the regression and S is the slope.