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Understanding Chlorine from Salt Electrolysis — The Element That Purifies Water
Peter

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Peter

13. Mai 2026SE
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Understanding Chlorine from Salt Electrolysis — The Element That Purifies Water

Fortgeschritten

Anweisungen

1

Prepare Saturated Salt Brine

Dissolve 360 grams of sodium chloride in 1 liter of warm distilled water to create a saturated brine solution. At room temperature, water dissolves about 36% NaCl by weight. Stir until no more salt dissolves and a small amount of undissolved crystals remain at the bottom — this confirms saturation. Filter through paper to remove any insoluble impurities.

Materialien für diesen Schritt:

Distilled Water (1 Liter)Distilled Water (1 Liter)
Table SaltTable Salt

Benötigte Werkzeuge:

Heat-Resistant Glass Beaker (1 liter)Heat-Resistant Glass Beaker (1 liter)
Precision Scale (0.01g)Precision Scale (0.01g)
Borosilicate Glass RodBorosilicate Glass Rod
Filter Paper (fine pore)Filter Paper (fine pore)
2

Understand the Chlor-Alkali Principle

When electricity passes through brine, three products form simultaneously: chlorine gas (Cl₂) at the anode, hydrogen gas (H₂) at the cathode, and sodium hydroxide (NaOH) in solution. The key reaction: 2NaCl + 2H₂O → Cl₂ + H₂ + 2NaOH. This is the chlor-alkali process — one of the largest industrial electrochemical operations, consuming about 1% of global electricity.
3

Set Up a Small Electrolysis Cell

Place two carbon (graphite) electrodes in a beaker of saturated brine, spaced 5 cm apart. Carbon is essential — metal electrodes react with chlorine. Connect to a 6-12V DC power supply. The positive terminal (anode) will produce chlorine; the negative terminal (cathode) will produce hydrogen. Use alligator clips for electrode connections.

Materialien für diesen Schritt:

Graphite ElectrodeGraphite Electrode

Benötigte Werkzeuge:

Heat-Resistant Glass Beaker (1 liter)Heat-Resistant Glass Beaker (1 liter)
DC Power SupplyDC Power Supply
Safety GogglesSafety Goggles
4

Observe Gas Evolution at Both Electrodes

Apply 6V and watch bubbles form at both electrodes. At the anode (positive), greenish-yellow chlorine gas rises — it has a sharp, pungent odor detectable below 1 ppm. At the cathode, colorless hydrogen bubbles form. DANGER: Perform this ONLY in a well-ventilated fume hood or outdoors. Chlorine gas caused 90,000 casualties in World War I. Even small amounts irritate lungs severely.

Benötigte Werkzeuge:

P100/FFP3 Respirator with Acid Gas CartridgeP100/FFP3 Respirator with Acid Gas Cartridge
Chemical Splash GogglesChemical Splash Goggles
Chemical-Resistant GlovesChemical-Resistant Gloves
5

Test for Chlorine with Litmus Paper

Hold damp blue litmus paper near the anode — chlorine first turns it red (acidic), then immediately bleaches it white. This double reaction is chlorine's signature test: Cl₂ + H₂O → HCl + HOCl. The hypochlorous acid (HOCl) is the bleaching agent. No other common gas produces this red-then-white sequence on litmus.

Materialien für diesen Schritt:

Litmus PaperLitmus Paper
6

Collect Sodium Hydroxide from the Cathode

As electrolysis proceeds, the solution around the cathode becomes strongly alkaline — sodium hydroxide accumulates. Test with pH paper: it reads 13-14. Industrial membrane cells keep the anode and cathode compartments separate to prevent chlorine from reacting with NaOH, which would form sodium hypochlorite (bleach) instead of the desired separate products.

Materialien für diesen Schritt:

Litmus PaperLitmus Paper

Benötigte Werkzeuge:

Heat-Resistant Glass Beaker (1 liter)Heat-Resistant Glass Beaker (1 liter)
7

Understand Scheele's Discovery

Carl Wilhelm Scheele first produced chlorine in 1774 by reacting manganese dioxide with hydrochloric acid: MnO₂ + 4HCl → MnCl₂ + 2H₂O + Cl₂. He called it 'dephlogisticated muriatic acid air.' Humphry Davy proved in 1810 that it was an element, naming it 'chlorine' from Greek 'khloros' (pale green). Scheele had unknowingly handled one of the most dangerous elements barehanded.
8

Demonstrate Chlorine's Bleaching Power

Dissolve a tiny amount of chlorine in cold water to make chlorine water. Dip a strip of colored fabric or a flower petal into the solution — the color disappears within seconds as hypochlorous acid oxidizes the organic pigments. This bleaching action revolutionized textile manufacturing when Charles Tennant patented bleaching powder (calcium hypochlorite) in 1799.

Materialien für diesen Schritt:

Distilled Water (1 Liter)Distilled Water (1 Liter)

Benötigte Werkzeuge:

Chemical Splash GogglesChemical Splash Goggles
Chemical-Resistant GlovesChemical-Resistant Gloves
9

Map Chlorine's Role in Water Treatment

Since 1908, chlorination has been the primary method for making drinking water safe. Adding 0.2-0.5 ppm free chlorine kills bacteria, viruses, and protozoa. This single innovation has saved more lives than any medical advance in history. Chloramines (chlorine + ammonia) provide longer-lasting residual disinfection in distribution systems. Breakpoint chlorination eliminates ammonia contamination.
10

Explore PVC and Organochlorine Chemistry

Chlorine is essential for producing polyvinyl chloride (PVC) — the world's third most-produced plastic. Vinyl chloride monomer (CH₂=CHCl) polymerizes into pipes, window frames, flooring, and medical tubing. About 40% of all chlorine production goes to organic chemicals: solvents, pesticides, pharmaceuticals, and silicones. Hydrochloric acid production consumes another 30%.
11

Neutralize and Document Findings

After the experiment, neutralize any remaining chlorine by adding sodium thiosulfate solution to the brine — it converts chlorine to harmless chloride ions. Record observations: color of gas, bleaching effect, litmus test results, and NaOH pH readings. Chlorine's atomic number 17 places it in Group 17 (halogens), and its electronegativity of 3.16 makes it the third most electronegative element after fluorine and oxygen.

Materialien für diesen Schritt:

Distilled Water (1 Liter)Distilled Water (1 Liter)

Benötigte Werkzeuge:

Precision Scale (0.01g)Precision Scale (0.01g)

Materialien

4

Benötigte Werkzeuge

9

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