Is the pOH Calculator free?

Yes, pOH Calculator is totally free :)

Can I use the pOH Calculator offline?

Yes, you can install the webapp as PWA.

Is it safe to use pOH Calculator?

Yes, any data related to pOH Calculator only stored in your browser (if storage required). You can simply clear browser cache to clear all the stored data. We do not store any data on server.

What is pOH and how is it calculated?

pOH is the negative base-10 logarithm of the hydroxide ion concentration: pOH = −log₁₀[OH⁻]. It quantifies the basicity of an aqueous solution. A lower pOH indicates a higher [OH⁻] and a more basic solution. At 25°C, pOH and pH always sum to 14 (the pKw of water).

What is the relationship between pH and pOH?

At any temperature, pH + pOH = pKw, where pKw is the negative logarithm of water's ion-product constant. At 25°C, pKw ≈ 14.00, so pH + pOH = 14. This means a solution with pOH 3 has pH 11. As temperature increases, pKw decreases, shifting the neutral point below pH 7.

How does temperature affect pOH calculations?

Temperature changes the autoionisation equilibrium of water. At 0°C, pKw ≈ 14.94, while at 37°C (body temperature) pKw ≈ 13.62, and at 100°C pKw ≈ 12.29. This calculator uses the empirical formula pKw ≈ 4470.99/T − 6.0875 + 0.01706·T (T in Kelvin) to adjust all results for temperatures between 0°C and 100°C.

How is the pOH of a weak base calculated?

For a weak base B with dissociation constant Kb and initial concentration C₀, the equilibrium Kb = x²/(C₀ − x) is solved using the full quadratic formula: x = (−Kb + √(Kb² + 4·Kb·C₀)) / 2. The resulting x is [OH⁻], from which pOH = −log₁₀(x). The calculator also reports the percentage dissociation: ([OH⁻] / C₀) × 100.

What is the difference between pOH and pH?

pH measures acidity (hydrogen ion concentration), while pOH measures basicity (hydroxide ion concentration). Both use the same logarithmic scale. An acidic solution has a high pH (low pOH), while a basic solution has a low pOH (high pH). At 25°C, a neutral solution has both pH and pOH equal to 7.

What concentration units does this calculator support?

The calculator accepts hydroxide ion concentrations in mol/L (M), mmol/L (mM), and μmol/L (μM). All values are automatically converted to mol/L internally before calculations. Results are always displayed in mol/L using scientific notation for clarity.

pOH Calculator – pH, [OH⁻] & Basicity Solver

🧪 pOH Calculator – Complete Guide to Basicity, pH, and Hydroxide Concentration

The pOH Calculator is a comprehensive chemistry tool for students, laboratory scientists, and engineers who need to analyse the basicity of aqueous solutions. By entering a hydroxide ion concentration, a pH value, a direct pOH value, or weak-base dissociation parameters, you can instantly obtain every key quantity — pOH, pH, [OH⁻], [H⁺], and pKw — adjusted for any temperature between 0 °C and 100 °C.

What Is pOH?

pOH is defined as the negative base-10 logarithm of the molar hydroxide ion concentration:

pOH = −log₁₀[OH⁻]

It is the basicity analogue of pH (which measures acidity). A lower pOH means a higher [OH⁻] and a more basic (alkaline) solution. The scale conventionally runs from 0 (strongly basic) to 14 (strongly acidic) at 25 °C, mirroring the pH scale in reverse.

The pH–pOH Relationship

In any aqueous solution, hydrogen ions and hydroxide ions are related by the water autoionisation equilibrium:

Kw = [H⁺][OH⁻]

Taking negative logarithms of both sides gives the fundamental identity:

pH + pOH = pKw

At 25 °C, Kw = 1.01 × 10⁻¹⁴, so pKw ≈ 14.00 and pH + pOH = 14. This means a solution with pOH 3 has pH 11 and is strongly alkaline.

Temperature Dependence of pKw

Water's ion-product constant changes significantly with temperature. At 0 °C, pKw ≈ 14.94, while at 37 °C (body temperature) pKw ≈ 13.62, and at 100 °C pKw ≈ 12.29. This means the neutral point of water is not always pH 7 — it shifts to 6.81 at body temperature. The calculator uses the empirical formula:

pKw(T) ≈ 4470.99/T − 6.0875 + 0.01706·T   (T in Kelvin)

to calculate the exact pKw at your chosen temperature, ensuring all derived quantities (pH, [OH⁻], [H⁺]) are accurate.

Temperature Tip

When working with biological or environmental samples, always specify the measurement temperature. A solution measured at 37 °C with pH 6.9 is actually slightly basic — not acidic — because the neutral pH at body temperature is approximately 6.81.

Calculating pOH from Weak Base Dissociation

For a weak base B with dissociation constant Kb and initial concentration C₀:

B + H₂O ⇌ BH⁺ + OH⁻
Kb = x² / (C₀ − x)

When Kb is small and C₀ is large (x ≪ C₀), the simplified approximation x ≈ √(Kb × C₀) gives adequate accuracy. However, for large Kb values or dilute concentrations, the full quadratic formula is required:

x = (−Kb + √(Kb² + 4·Kb·C₀)) / 2

This calculator always uses the exact quadratic solution and reports the percentage dissociation — the fraction of weak base that has reacted — which is a key quality indicator for buffer solutions.

Four Input Modes Explained

This calculator supports four starting-point modes:

[OH⁻] Concentration — Enter the known hydroxide ion concentration in mol/L, mmol/L, or μmol/L. Supports physical concentrations from 10⁻¹⁵ to 10 mol/L.
pH Value — Enter the measured pH. The calculator derives pOH = pKw − pH and all other quantities. A warning is shown for pH values outside 0–14.
pOH Value — Enter a known pOH directly and compute [OH⁻], pH, and [H⁺].
Weak Base Dissociation — Enter Kb and the initial base concentration. The quadratic equilibrium solver calculates [OH⁻] precisely. Eight common weak base presets (ammonia, methylamine, aniline, etc.) are available for quick setup.

Real-World Applications

Environmental chemistry: Assessing the alkalinity of wastewater effluent before discharge; monitoring river water pH and corresponding basicity levels.
Pharmaceutical formulation: Buffer solutions for injectable medications must maintain precise pH (and hence pOH) to prevent degradation and ensure patient safety.
Industrial quality control: Caustic cleaning solutions, electroplating baths, and cement slurries all require accurate [OH⁻] monitoring.
Education: Students in general chemistry, analytical chemistry, and biochemistry use pOH calculations in acid-base equilibrium, buffer design, and titration exercises.
Food and beverage production: Lye (NaOH) baking processes (pretzels, ramen noodles) rely on high [OH⁻], and calculating the pOH ensures safe, consistent product alkalinity.

Common Weak Bases and Their Kb Values

The built-in preset library includes common weak bases encountered in general and organic chemistry labs:

Ammonia (NH₃): Kb = 1.8 × 10⁻⁵ — the most common weak base in introductory chemistry, used in cleaning products and buffer solutions.
Methylamine (CH₃NH₂): Kb = 4.4 × 10⁻⁴ — stronger than ammonia, found in fish decomposition and certain pharmaceutical syntheses.
Aniline (C₆H₅NH₂): Kb = 4.3 × 10⁻¹⁰ — a very weak base used in dye manufacturing and polymer chemistry.
Pyridine (C₅H₅N): Kb = 1.7 × 10⁻⁹ — a common organic solvent and reagent in synthetic chemistry.

Understanding the Visual Outputs

The calculator provides two visual elements to aid interpretation:

pH Scale Bar: A colour-gradient bar (red = acidic, green = neutral, blue = basic) with an animated pin showing the solution's exact pH position and a white marker indicating the neutral pH at the selected temperature.
Circular Gauges: Complementary circular progress indicators showing pH and pOH filling in opposite directions, visually demonstrating how their sum equals pKw.

Accuracy Note

The pKw approximation formula is valid for pure water between 0 °C and 100 °C. For ionic solutions (high salt concentrations), activity corrections are needed. Use the activity coefficient input for non-ideal solutions when high accuracy is required.

Step-by-Step Calculation Panel

Every calculation includes a numbered derivation showing each formula applied with intermediate values. This is particularly useful for students who need to verify their manual calculations or understand the reasoning behind each result. Expand the Step-by-Step Solution accordion after any calculation to see the full working.

pKw at Different Temperatures — Quick Reference

The reference table below the results shows pKw, Kw, and the neutral pH for common temperatures. The row closest to your selected temperature is highlighted in blue for easy identification. This helps when working in non-standard conditions such as cryogenic samples (near 0 °C) or high-temperature industrial processes.

pOH Calculator

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