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Weight of K2SO4 Calculator

Calculate the weight of 1 mole of K2SO4 (Potassium Sulfate) and other molar quantities instantly.

Amount of Substance (Moles)

Enter the number of moles (default is 1 for Molar Mass).

Please enter a valid positive number.

Atomic Weight Precision Standard (K=39.10, S=32.07, O=16.00) High Precision (IUPAC)

Choose the precision level for atomic masses.

Total Weight (Mass)

174.259 g

Formula: 1 mol × 174.259 g/mol

Potassium (K) Mass

78.197 g

Sulfur (S) Mass

32.065 g

Oxygen (O) Mass

63.996 g

Mass Contribution Breakdown

Mass contribution by element for K2SO4

Atomic Breakdown Table

Table 1: Detailed breakdown of the atomic components in Potassium Sulfate.
Element	Atoms per Molecule	Atomic Weight (g/mol)	Total Mass Contribution (g)

What is "calculate the weight of 1 mole of k2so4"?

When chemists or students need to calculate the weight of 1 mole of k2so4, they are essentially determining the molar mass of Potassium Sulfate. K2SO4 is a non-flammable white crystalline salt commonly used in fertilizers providing both potassium and sulfur.

Knowing the exact weight of 1 mole is crucial for stoichiometry in chemical reactions. Whether you are preparing a solution for a laboratory experiment or calculating the required dosage for agricultural soil amendment, accuracy in this calculation ensures the correct chemical proportions are used.

This calculator is designed for students, chemists, and agricultural professionals who need to quickly determine the mass of any given amount of Potassium Sulfate, eliminating the potential for manual arithmetic errors.

K2SO4 Formula and Mathematical Explanation

The process to calculate the weight of 1 mole of k2so4 is based on summing the standard atomic weights of all atoms present in the chemical formula.

Formula: Molar Mass = (2 × K) + (1 × S) + (4 × O)

Potassium Sulfate ($K_2SO_4$) consists of:

2 atoms of Potassium (K)
1 atom of Sulfur (S)
4 atoms of Oxygen (O)

Here are the atomic variables used in the calculation:

Table 2: Atomic weights used to calculate the weight of 1 mole of k2so4.
Variable / Element	Symbol	Atomic Weight (g/mol)	Role in Formula
Potassium	K	39.0983	Cation ($K^+$)
Sulfur	S	32.065	Central atom of Sulfate
Oxygen	O	15.999	Surrounding atoms in Sulfate

Practical Examples (Real-World Use Cases)

Example 1: Standard Laboratory Preparation

Scenario: A lab technician needs to prepare a 1 Molar solution of Potassium Sulfate in a 1-liter volumetric flask.

Input: 1 Mole
Calculation: $(2 \times 39.10) + 32.07 + (4 \times 16.00)$
Result: ~174.26 grams
Interpretation: The technician must weigh out exactly 174.26 grams of anhydrous K2SO4 powder and dissolve it in water to make 1 liter of solution.

Example 2: Agricultural Application

Scenario: An agronomist recommends adding 500 moles of K2SO4 to a specific plot of land to correct a potassium deficiency.

Input: 500 Moles
Calculation: $500 \times 174.26$ grams
Result: 87,130 grams (or 87.13 kg)
Interpretation: The farmer needs to purchase and spread approximately 87.13 kg of Potassium Sulfate fertilizer.

How to Use This K2SO4 Calculator

Enter Moles: Input the number of moles you have. The default is 1, as the primary goal is often to calculate the weight of 1 mole of k2so4.
Select Precision: Choose between "Standard" (textbook values) or "High Precision" (IUPAC values) depending on your needs.
View Results: The tool instantly displays the total weight in grams.
Analyze Breakdown: Review the intermediate values to see how much mass comes from Potassium, Sulfur, and Oxygen respectively.
Copy Data: Use the "Copy Results" button to save the calculation for your lab notebook or report.

Key Factors That Affect Molar Mass Results

While the theoretical calculation is straightforward, several factors can affect the practical weight measurement when you try to calculate the weight of 1 mole of k2so4 in a real-world setting:

Isotopic Variation: Standard atomic weights are averages. Samples from different geological sources might have slightly different isotopic ratios of Sulfur or Oxygen, slightly altering the molar mass.
Hydration State: K2SO4 is typically anhydrous, but if the sample has absorbed moisture (hygroscopic), the weighed mass will include water weight, skewing the mole calculation.
Purity Levels: Agricultural grade K2SO4 is not 100% pure. It may contain traces of Chloride or other salts. Calculations must assume 100% purity or be adjusted by a purity factor (e.g., 95% pure).
Measurement Precision: The precision of the balance used to weigh the substance affects the practical realization of "1 mole." Analytical balances offer higher precision than standard scales.
Atomic Weight Standards: Periodic tables vary slightly. Some round Oxygen to 16.00, while others use 15.999. This calculator offers both options to accommodate different textbook standards.
Experimental Error: Loss of material during transfer or weighing errors can result in a discrepancy between the calculated weight and the actual effective moles in a solution.

Frequently Asked Questions (FAQ)

1. What is the exact molar mass of K2SO4?

Using high-precision atomic weights, the molar mass is approximately 174.259 g/mol. Most textbooks round this to 174.26 g/mol.

2. Why do I need to calculate the weight of 1 mole of k2so4?

It is the fundamental constant required to convert between the mass of the substance (which you can measure on a scale) and the amount of substance in moles (which governs chemical reactions).

3. Is Potassium Sulfate the same as Potash?

Not exactly. "Potash" is a general term often referring to Potassium Chloride (KCl) or Potassium Carbonate. K2SO4 is specifically "Sulfate of Potash" (SOP), which is preferred for chloride-sensitive crops.

4. How does the percentage of Potassium affect the weight?

Potassium accounts for about 44.87% of the total mass of K2SO4. This high percentage makes it an efficient carrier for potassium in fertilizers.

5. Can I use this calculator for hydrated K2SO4?

No, this calculator assumes anhydrous (dry) K2SO4. If you have a hydrate, you must add the weight of the water molecules ($18.015 \text{ g/mol} \times \text{number of water molecules}$) to the total.

6. What if my input is in kilograms?

Convert your value to grams first (multiply kg by 1000) or remember that the result for 1 kilomole would be in kilograms.

7. Is K2SO4 acidic or basic?

Potassium Sulfate is a salt formed from a strong base (KOH) and a strong acid ($H_2SO_4$), making it roughly neutral in solution, though calculations here focus purely on mass, not pH.

8. Does temperature affect the molar mass?

No. Molar mass is a constant property of the molecule determined by nuclear physics (protons and neutrons), unaffected by temperature or pressure.

Related Tools and Internal Resources

General Molar Mass Calculator
Calculate the molar mass for any chemical formula instantly.
Stoichiometry Calculator
Balance chemical equations and calculate reactant requirements.
NPK Ratio Calculator
Determine the Nitrogen, Phosphorus, and Potassium balance for soil health.
Grams to Moles Converter
A simple tool to switch between mass and molar quantity.
Molarity Calculator
Calculate the concentration of aqueous solutions accurately.
Interactive Periodic Table
Explore atomic weights, electron configurations, and element properties.

// — VARIABLES & CONSTANTS — // Atomic weights (g/mol) var ATOMIC_WEIGHTS_HIGH = { K: 39.0983, S: 32.065, O: 15.999 }; var ATOMIC_WEIGHTS_STD = { K: 39.10, S: 32.07, O: 16.00 }; var COUNTS = { K: 2, S: 1, O: 4 }; // Global chart instance variable var massChart = null; // — MAIN CALCULATION FUNCTION — function calculateK2SO4() { var molesInput = document.getElementById('molesInput'); var precisionSelect = document.getElementById('precisionSelect'); var molesError = document.getElementById('molesError'); var molesVal = parseFloat(molesInput.value); var useHighPrecision = precisionSelect.value === 'high'; // Validation if (isNaN(molesVal) || molesVal < 0) { molesError.style.display = 'block'; resetToSafeDisplay(); return; } else { molesError.style.display = 'none'; } // Select Weights var weights = useHighPrecision ? ATOMIC_WEIGHTS_HIGH : ATOMIC_WEIGHTS_STD; // Calculate Component Masses per Mole var massK_mol = weights.K * COUNTS.K; var massS_mol = weights.S * COUNTS.S; var massO_mol = weights.O * COUNTS.O; var molarMass = massK_mol + massS_mol + massO_mol; // Calculate Totals based on Input Moles var totalMass = molarMass * molesVal; var totalK = massK_mol * molesVal; var totalS = massS_mol * molesVal; var totalO = massO_mol * molesVal; // Update DOM Elements document.getElementById('resultWeight').innerHTML = formatNum(totalMass) + " g"; document.getElementById('resK').innerHTML = formatNum(totalK) + " g"; document.getElementById('resS').innerHTML = formatNum(totalS) + " g"; document.getElementById('resO').innerHTML = formatNum(totalO) + " g"; document.getElementById('formulaExplanation').innerHTML = "Formula: " + molesVal + " mol × " + formatNum(molarMass) + " g/mol"; // Update Table updateTable(weights, molesVal); // Update Chart drawChart(totalK, totalS, totalO); } // — HELPER FUNCTIONS — function formatNum(num) { // Format to 3 decimal places for standard display return num.toLocaleString('en-US', { minimumFractionDigits: 3, maximumFractionDigits: 3 }); } function resetToSafeDisplay() { document.getElementById('resultWeight').innerHTML = "—"; document.getElementById('resK').innerHTML = "—"; document.getElementById('resS').innerHTML = "—"; document.getElementById('resO').innerHTML = "—"; } function updateTable(weights, moles) { var tbody = document.getElementById('breakdownTableBody'); var html = ""; var data = [ { name: "Potassium (K)", count: COUNTS.K, weight: weights.K, total: weights.K * COUNTS.K * moles }, { name: "Sulfur (S)", count: COUNTS.S, weight: weights.S, total: weights.S * COUNTS.S * moles }, { name: "Oxygen (O)", count: COUNTS.O, weight: weights.O, total: weights.O * COUNTS.O * moles } ]; for (var i = 0; i < data.length; i++) { html += ""; html += "" + data[i].name + ""; html += "" + data[i].count + ""; html += "" + data[i].weight + ""; html += "" + formatNum(data[i].total) + ""; html += ""; } tbody.innerHTML = html; } function resetCalculator() { document.getElementById('molesInput').value = "1"; document.getElementById('precisionSelect').value = "high"; calculateK2SO4(); } function copyResults() { var weight = document.getElementById('resultWeight').innerText; var k = document.getElementById('resK').innerText; var s = document.getElementById('resS').innerText; var o = document.getElementById('resO').innerText; var textToCopy = "Weight of K2SO4 Calculation:\n" + "Total Weight: " + weight + "\n" + "Potassium Mass: " + k + "\n" + "Sulfur Mass: " + s + "\n" + "Oxygen Mass: " + o; // Use temporary textarea for copy var tempInput = document.createElement("textarea"); tempInput.value = textToCopy; document.body.appendChild(tempInput); tempInput.select(); document.execCommand("copy"); document.body.removeChild(tempInput); // Simple visual feedback var btn = document.querySelector('.btn-copy'); var originalText = btn.innerText; btn.innerText = "Copied!"; setTimeout(function() { btn.innerText = originalText; }, 1500); } // — CHART DRAWING (Native Canvas) — function drawChart(k, s, o) { var canvas = document.getElementById('massChart'); if (!canvas.getContext) return; var ctx = canvas.getContext('2d'); // Clear canvas ctx.clearRect(0, 0, canvas.width, canvas.height); // Set dimensions if not set if (canvas.width === 0) { canvas.width = 300; canvas.height = 300; } // Fix High DPI scaling var dpr = window.devicePixelRatio || 1; var rect = canvas.getBoundingClientRect(); canvas.width = rect.width * dpr; canvas.height = rect.height * dpr; ctx.scale(dpr, dpr); var total = k + s + o; var data = [k, s, o]; var colors = ['#004a99', '#28a745', '#17a2b8']; // Blue (K), Green (S), Cyan/Teal (O) var labels = ['K', 'S', 'O']; var centerX = rect.width / 2; var centerY = rect.height / 2; var radius = Math.min(centerX, centerY) – 20; var startAngle = 0; for (var i = 0; i < data.length; i++) { var sliceAngle = (data[i] / total) * 2 * Math.PI; ctx.beginPath(); ctx.moveTo(centerX, centerY); ctx.arc(centerX, centerY, radius, startAngle, startAngle + sliceAngle); ctx.closePath(); ctx.fillStyle = colors[i]; ctx.fill(); startAngle += sliceAngle; } // Draw center hole (Doughnut style for modern look) ctx.beginPath(); ctx.arc(centerX, centerY, radius * 0.5, 0, 2 * Math.PI); ctx.fillStyle = '#ffffff'; ctx.fill(); // Update Legend HTML dynamically to match chart colors var legendDiv = document.getElementById('chartLegend'); legendDiv.innerHTML = '■ Potassium (' + Math.round(k/total*100) + '%) ' + '■ Sulfur (' + Math.round(s/total*100) + '%) ' + '■ Oxygen (' + Math.round(o/total*100) + '%)'; } // Initial Calculation on Load window.onload = function() { calculateK2SO4(); // Handle window resize for chart responsiveness window.addEventListener('resize', function() { var k = parseFloat(document.getElementById('resK').innerText.replace(' g', ").replace(/,/g, ")); var s = parseFloat(document.getElementById('resS').innerText.replace(' g', ").replace(/,/g, ")); var o = parseFloat(document.getElementById('resO').innerText.replace(' g', ").replace(/,/g, ")); drawChart(k, s, o); }); };

Calculate the Weight of 1 Mole of K2so4