Calculate enthalpy using H = U + PV. Find enthalpy change, formation enthalpies, and combustion enthalpies with unit conversions and reference data.
The **Enthalpy Calculator** computes enthalpy (H) using the fundamental thermodynamic relationship H = U + PV, where U is internal energy, P is pressure, and V is volume. Enthalpy is one of the most important state functions in thermodynamics, representing the total heat content of a system at constant pressure.
Enthalpy changes accompany virtually every process in nature and engineering — from chemical reactions and phase transitions to fluid flow and combustion. When you heat water on a stove, the enthalpy increases. When natural gas burns in a furnace, the enthalpy of combustion tells you how much heat is released. Engineers use enthalpy to design power plants, refrigeration systems, and chemical reactors.
This calculator handles both H = U + PV calculations and direct enthalpy inputs, with full unit conversion support. A reference table of standard enthalpies of formation and combustion for common substances helps with thermochemistry problems. Check the example with realistic values before reporting.
Enthalpy calculations are fundamental to chemical engineering, HVAC design, power generation analysis, and chemistry coursework. This calculator provides instant results with multiple unit systems and a built-in reference table of formation enthalpies.
Whether you are solving thermodynamics homework, designing a heat exchanger, or analyzing a chemical process, having enthalpy values and unit conversions at your fingertips saves time and reduces errors.
Enthalpy: H = U + PV Where: - H = enthalpy (J) - U = internal energy (J) - P = pressure (Pa) - V = volume (m³) - PV = pressure-volume work term For enthalpy change: ΔH = ΔU + Δ(PV) At constant pressure: ΔH = Q_p (heat at constant pressure)
Result: 171.7 kJ
With U = 2,088 J, P = 101.325 kPa, V = 1.673 m³: PV = 101,325 × 1.673 = 169,517 J. H = 2,088 + 169,517 = 171,605 J ≈ 171.6 kJ. The PV work term dominates for gases at standard pressure.
Hess's Law states that the total enthalpy change of a reaction is independent of the pathway. This allows chemists to calculate reaction enthalpies from tabulated formation enthalpies: ΔH°rxn = Σ nΔHf°(products) − Σ nΔHf°(reactants). This principle is the basis of thermochemistry and enables prediction of heat release or absorption for reactions that are difficult to measure directly.
Bond enthalpy provides another approach: ΔH ≈ Σ bonds broken − Σ bonds formed. While less precise than formation enthalpies, this method gives quick estimates and helps explain why certain reactions are exothermic or endothermic based on bond strength differences.
**Steam Tables:** Power plant engineers rely on steam tables listing specific enthalpy at various temperatures and pressures. The enthalpy difference between superheated steam entering a turbine and the exhaust determines the work extracted per kilogram of steam.
**Refrigeration Cycles:** HVAC engineers use pressure-enthalpy (P-h) diagrams to analyze refrigeration cycles. The enthalpy change across the evaporator determines cooling capacity, while the compressor work is the enthalpy rise during compression.
**Combustion Analysis:** The enthalpy of combustion determines how much heat a fuel releases. Natural gas (CH₄) releases 890 kJ/mol, while hydrogen releases 286 kJ/mol. These values are essential for furnace sizing, engine design, and energy cost analysis.
Enthalpy is the total heat content of a system. At constant pressure, the change in enthalpy equals the heat added or removed. It is the most practical energy measure for processes occurring at atmospheric pressure.
Most processes occur at constant pressure (open to atmosphere). Enthalpy automatically includes the PV work done expanding or compressing against atmospheric pressure, making energy accounting simpler.
The enthalpy change when one mole of a compound forms from its elements in their standard states (25°C, 1 atm). By convention, elements in their standard state have ΔHf° = 0.
Yes — enthalpy depends only on the current state, not the path taken. This means ΔH for a reaction is the same regardless of whether it happens in one step or multiple steps (Hess's Law).
Negative ΔH means the process releases heat to the surroundings (exothermic). Positive ΔH means it absorbs heat (endothermic). Combustion reactions always have negative ΔH.
The Gibbs free energy combines both: ΔG = ΔH − TΔS. A process is spontaneous when ΔG < 0. Enthalpy (heat) and entropy (disorder) together determine whether a process naturally occurs.