CHEMISTRY GLOSSARY

Results 1–5 of 5 for Haber, Fritz

Haber, Fritz → Haber, Fritz

Fritz Haber (1868-1934) is German physical chemist, winner of the Nobel Prize for Chemistry (1918) for his development of a method of synthesizing ammonia. With Carl Bosch, he invented a process for the large-scale production of ammonia for use in nitrogen fertilizer.

Haber process → Haberov proces

Haber process is an industrial process for producing ammonia by reaction of nitrogen with hydrogen:

N₂ + 3H₂ →← 2NH₃

The reaction is reversible and exothermic, so that a high yield of ammonia is favoured by low temperature. However, the rate of reaction would be too slow for equilibrium to be reached at normal temperatures, so an optimum temperature of about 450 °C is used, with a catalyst of iron containing potassium aluminium oxide promoters. The higher the pressure the greater the yield, although there are technical difficulties in using very high pressures. A pressure of about 250 atmospheres is commonly employed. The removal of ammonia from the batch as soon as it is formed ensures that an equilibrium favouring product formation is maintained. The nitrogen is obtained from air. Formerly, the hydrogen was from water gas and the water-gas shift reaction (the Bosch process) but now the raw material (called synthesis gas) is obtained by steam reforming natural gas.

The process is of immense importance for the fixation of nitrogen for fertilisers and explosives. It was developed in 1908 by German chemist Fritz Haber (1868-1934) and was developed for industrial use by Carl Bosch (1874-1940), hence the alternative name Haber-Bosch process.

Born-Haber cycle → Born-Haberov kružni proces

Born-Haber cycle is a cycle of reactions used for calculating the lattice energies of ionic crystalline solids. For a compound MX, the lattice energy is the enthalpy of the reaction

M⁺(g) + X^-(g) → M⁺X^-(s) ΔH_L

The standard enthalpy of formation of the ionic solid is the enthalpy of the reaction

M(s) + 1/2X₂(g) → M⁺X^-(s) ΔH_f

The cycle involves equating this enthalpy (which can be measured) to the sum of the enthalpies of a number of steps proceeding from the elements to the ionic solid. The steps are:

1) Atomization of the metal

M(s) → M(g) ΔH₁

2) Atomization of the nonmetal

1/2X₂(g) → X(g) ΔH₂

3) Ionisation of the metal

M(g) → M⁺(g) + e^- ΔH₃

This is obtained from the ionisation potential.

4) Ionisation of the nonmetal

X(g) + e^- → X^-(g) ΔH₄

This is electron affinity.

5) Formation of the ionic solids

M⁺(g) + X^-(g) → M⁺X^-(s) ΔH_L

Equation of the enthalpies gives

ΔH_f = ΔH₁ + ΔH₂ + ΔH₃ + ΔH₄ + ΔH_L

from which ΔH_L can be found.

Haber-Bosch process → Haber-Boshov postupak

See Haber process

gas washing bottle → boca ispiralica

Gas washing bottle or Drechsel bottle provide an inexpensive but effective method for washing or drying gases. The gas enters the bottle through the top of the central vertical tube, the lower end of which is below the surface of the washing medium. To maximize surface area contact of the gas to the liquid, a gas stream is slowly blown into the vessel through the fritted glass tip so that it breaks up the gas into many tiny bubbles. After bubbling through the medium, the gas rises to the top and exits through the side tube. It is named after the German chemist Edmund Drechsel (1843-1897).

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Citing this page:

Generalic, Eni. "Haber, Fritz." Croatian-English Chemistry Dictionary & Glossary. 29 June 2022. KTF-Split. {Date of access}. <https://glossary.periodni.com>.

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