Calculate the degree of unsaturation (DoU / IHD) from a molecular formula. Determine double bonds, triple bonds, and rings.
The degree of unsaturation (DoU), also known as the index of hydrogen deficiency (IHD) or double bond equivalent (DBE), is a fundamental concept in organic chemistry that tells you how many degrees of unsaturation exist in a molecule based solely on its molecular formula. Each double bond and each ring reduces the hydrogen count by two relative to the fully saturated formula, contributing one degree of unsaturation. A triple bond contributes two degrees.
This powerful tool allows organic chemists to narrow down possible structures before ever running a spectroscopic analysis. If a compound with formula C₆H₆ has a DoU of 4, you immediately know it could be benzene — with three double bonds and one ring contributing 4 total degrees. This structural insight is invaluable when interpreting IR, NMR, and mass spectrometry data.
The calculator handles molecules containing carbon, hydrogen, nitrogen, oxygen, and halogens, using the standard DoU formula. Enter atom counts directly or paste a molecular formula for automatic parsing. Preset buttons for common molecules let you explore how well-known compounds map to their unsaturation degrees.
Calculating DoU by hand for complex formulas is error-prone. This calculator instantly determines the unsaturation level and provides structural interpretation, making it essential for organic chemistry students and researchers interpreting spectral data. This degree of unsaturation calculator helps you compare outcomes quickly and reduce avoidable mistakes when making day-to-day care decisions. Use the estimate as a planning baseline and confirm final decisions with a qualified professional when risk is high.
DoU = (2C + 2 + N − H − X) / 2, where C = carbon, H = hydrogen, N = nitrogen, X = halogens. Oxygen and sulfur do not appear in the formula because they are divalent and don't affect the hydrogen count.
Result: DoU = 4
DoU = (2×6 + 2 − 6) / 2 = (14 − 6) / 2 = 4. Benzene (C₆H₆) has 3 C=C double bonds and 1 ring, totaling 4 degrees of unsaturation.
The maximum hydrogen count for a saturated acyclic molecule is 2C + 2 (CₙH₂ₙ₊₂ for alkanes). Each nitrogen adds one potential hydrogen (amines follow CₙH₂ₙ₊₃N), while each halogen replaces one hydrogen. The DoU formula compares the actual hydrogen count to this theoretical maximum and divides by 2 because each degree of unsaturation removes two hydrogens.
Structure elucidation workflows typically begin by calculating DoU from the molecular formula (obtained via mass spectrometry). A DoU of 0 means a saturated, acyclic compound. DoU = 1 suggests one double bond or one ring. DoU = 4 immediately flags a possible benzene ring. This narrows the search space dramatically before examining IR, ¹H NMR, and ¹³C NMR spectra.
The DoU formula assumes standard valencies: C = 4, H = 1, N = 3, O = 2, halogens = 1. Elements with variable valency (like phosphorus in phosphates) require modified calculations. Charged species and radicals can produce fractional DoU values. For most organic compounds encountered in coursework and routine analysis, the standard formula works perfectly.
Oxygen is divalent like carbon, so replacing a CH₂ group with O doesn't change the hydrogen count. The same applies to sulfur.
Each halogen replaces one hydrogen, so halogens are subtracted from the formula just like hydrogen: DoU = (2C + 2 + N − H − X) / 2. This keeps planning practical and lowers the chance of preventable errors.
The molecule is fully saturated with no rings or multiple bonds, like hexane (C₆H₁₄). This keeps planning practical and lowers the chance of preventable errors.
A half-integer DoU indicates the molecular formula is unusual (e.g., a radical). For stable organic molecules, DoU is always a whole number.
DoU alone cannot distinguish them. You need spectroscopic data — IR shows C=C and C=O stretches, while NMR can reveal ring structures.
A benzene ring contributes 4 DoU: 3 from the C=C double bonds and 1 from the ring closure. This keeps planning practical and lowers the chance of preventable errors.