Precipitation Hardening

The Hall-Héroult process is the major industrial method for smelting aluminum. It involves dissolving alumina (aluminum oxide, Al₂O₃) in molten cryolite (Na₃AlF₆) and electrolyzing the molten salt bath. Aluminum metal is deposited at the cathode, while oxygen from the alumina reacts with the carbon anode, producing carbon dioxide. This process made aluminum widely available and affordable.

Exothermic welding, also known as thermite welding, is a technique that uses the superheated molten metal from an aluminothermic reaction to create a strong, permanent molecular bond between metal components. The process is self-contained, requiring no external power source. It is most famously used to join sections of railway track into continuous welded rail, creating a smoother and more durable track.

The properties of an oxy-acetylene flame are controlled by the volumetric ratio of oxygen to acetylene. A neutral flame (ratio ≈ 1.1:1) is standard for steel welding. A carburizing or reducing flame (ratio 1.1:1) has excess oxygen, is hotter, and is used for braze-welding.

Temper embrittlement is a reduction in the toughness of certain alloy steels caused by holding them in, or slowly cooling them through, a specific temperature range (approximately 375–575 °C). This phenomenon is driven by the segregation of impurity elements (e.g., phosphorus, tin, antimony) to the grain boundaries, which weakens the cohesion between grains and promotes intergranular fracture.

The chloralkali process is an industrial method for the electrolysis of sodium chloride (NaCl) solution, known as brine. It is the primary source for producing chlorine (Cl₂), sodium hydroxide (NaOH), and hydrogen (H₂), which are essential commodity chemicals. Modern methods use a membrane cell to separate the anode and cathode products, ensuring high purity and efficiency.

An empirical formula that describes how the available capacity of a battery decreases as the rate of discharge increases. The law is stated as \(C_p = I^k t\), where \(C_p\) is the capacity at a one-ampere discharge rate, \(I\) is the discharge current, \(t\) is the discharge time, and \(k\) is the Peukert constant, specific to the battery type. It quantifies the inefficiency at high loads.

Oxy-acetylene welding uses a flame produced by the combustion of acetylene (\(C_2H_2\)) with pure oxygen. The reaction occurs in two stages. The primary reaction in the inner, white-hot cone is incomplete, producing carbon monoxide and hydrogen: \(2C_2H_2 + 2O_2 \rightarrow 4CO + 2H_2\). These hot gases then react with atmospheric oxygen in the outer envelope, completing the combustion.

Oxy-fuel cutting, or flame cutting, severs ferrous metals by a rapid, exothermic oxidation process. First, a preheating flame raises the steel's surface to its kindling temperature (approx. 870 °C or 1600 °F). A high-pressure jet of pure oxygen is then directed at the spot, initiating a chemical reaction, \(3Fe + 2O_2 \rightarrow Fe_3O_4\), which forms molten iron oxide (slag) and releases heat.

Gas cylinders for oxy-fuel welding store gases or other industrial or medical gases, at very high pressures. A pressure regulator is essential to reduce this to a safe, usable working pressure. A two-stage regulator performs this reduction in two steps, providing a highly constant delivery pressure even as the cylinder pressure drops with use. This ensures a stable flow, thus a stable flame for consistent weld quality.

For materials that do not have a distinct yield point on their stress-strain curve, like aluminum or high-strength steel, 'proof stress' is the engineering equivalent. It is defined as the stress required to produce a small, specified amount of permanent (plastic) deformation, typically 0.2% of the original gauge length. This value, \(\sigma_{0.2}\), is used in design calculations as the material's practical elastic limit.