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Reaction Energetics & Electrochemistry

Calculate ΔH of a reaction, activation energy, and electrode potentials calculation

Select what you want to calculate.

Periodic Data, Molecular Formula, Isotope Dating

Activation Energy (Arrhenius equation)

Use the Arrhenius relationship to calculate activation energy or rate constants.

Calculate activation energy (Eₐ) Calculate rate constant (k₂)

Rate constant at T₁ (k₁) Temperature T₁ (K) Temperature T₂ (K)

Activation energy Eₐ (kJ·mol⁻¹)

Rate constant at T₂ (k₂)

Result

Electrochemistry — Standard Cell Potential (E°cell)

Calculate the standard cell potential from standard electrode potentials (25 °C).

Cathode (reduction)

Half-reaction (optional) Standard potential E° (V)

Anode (oxidation)

Half-reaction (optional) Standard potential E° (V)

Result

Electrochemistry — Nernst Equation

Non-standard conditions (Q ≠ 1) at any temperature (T).

Standard cell potential E°cell (V) Temperature T (K) Number of electrons transferred (n) Reaction quotient Q

Result

Electrochemistry — ΔG and E Relationship

Relate Gibbs free energy change and cell potential.

Cell potential (V) Number of electrons transferred (n) Gibbs free energy change (kJ·mol⁻¹)

Result

ΔH of a reaction (from standard enthalpies of formation)

Uses: ΔH°rxn = ΣνΔH°f(products) − ΣνΔH°f(reactants)

Reactants

Products

Result

Electrolysis — Faraday’s Laws

Relate current, time, charge, and amount of substance produced or consumed.

Current I (A) Time t

Number of electrons transferred (z) Molar mass M (g·mol⁻¹) (optional)

Result

Faraday’s Laws — Time or Current Required

Calculate the time or current needed to produce a given amount.

Amount of substance n (mol) OR mass m (g) Molar mass M (g·mol⁻¹) Number of electrons transferred (z) Current I (A) (leave blank to calculate) Time t (leave blank to calculate)

Competition at Electrodes (Aqueous, Inert Electrodes)

The species discharged is the one with the highest priority in the electrochemical order.

Cathode: Discharge order (reduction) Anode: Discharge order (oxidation)

Water Electrolysis — Gas Volume Ratio

Overall: 2H₂O → 2H₂ + O₂, so H₂ : O₂ = 2 : 1 (moles and volumes at same T,P).

Half-reactions (reference)

Cathode: 2H₂O + 2e⁻ → H₂ + 2OH⁻ Anode (acidic/neutral): 2H₂O → O₂ + 4H⁺ + 4e⁻ Overall: 2H₂O → 2H₂ + O₂ Ratio: n(H₂):n(O₂) = V(H₂):V(O₂) = 2:1

Optional calculator (from charge)

Charge Q (C) (leave blank to use I and t) Current I (A) (leave blank if using Q) Time t

Molar gas volume Vₘ (L·mol⁻¹)

Molecular / Empirical formula from mass percent

Enter element symbols and mass percentages. Add rows as needed. Molecular weight is optional.

Molecular weight (g·mol⁻¹) (optional)

Result

Fill in at least two elements and their percentages.

Radioactive Isotope Dating

Determine the age of a sample from radioactive decay using half-life.

Parent isotope Half-life (years) Fraction of parent remaining (%)