Ritchter-Wenzel Law Stories, Statements, and Examples

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David Holt
Ritchter-Wenzel Law Stories, Statements, and Examples

The Ritchter-Wenzel law or of the reciprocal proportions is one that establishes that the mass proportions between two compounds make it possible to determine that of a third compound. It is one of the laws of stoichiometry, together with Lavoisier's law (law of the conservation of mass); Proust's law (law of definite proportions); and Dalton's law (law of multiple proportions).

Ritcher enunciated his law in 1792 in a book that defined the fundamentals of stoichiometry, based on the research works of Carl F Wenzel, who in 1777 published the first equivalence table for acids and bases..

Reciprocity triangle. Source: Gabriel Bolívar

A simple way to visualize it is through a “triangle of reciprocity” (image above). If you know the masses of A, C and B that mix to form compounds AC and AB, you can determine how much of C and B mix or react to form compound CB.

In compounds AC and AB, element A is present in both, so dividing their mass proportions will find out how much C reacts with B.

Article index

  • 1 History and generalities of the law of reciprocal proportions
  • 2 Statements and consequences
  • 3 Examples
    • 3.1 Calcium chloride
    • 3.2 Sulfur oxides
    • 3.3 Iron sulfide and oxide
  • 4 References

History and generalities of the law of reciprocal proportions

Richter found that the weight ratio of the compounds consumed in a chemical reaction is always the same.

In this regard, Ritcher found that 615 parts by weight of magnesia (MgO) are required, for example, to neutralize 1000 parts by weight of sulfuric acid.

Between 1792 and 1794, Ritcher published a three-volume summary containing his work on the law of definite proportions. The abstract dealt with stoichiometry, defining it as the art of chemical measurements..

Noting, furthermore, that stoichiometry deals with the laws according to which substances unite to form compounds. However, Richter's research work was criticized for the mathematical treatment he used, even pointing out that he adjusted his results.

In 1802, Ernst Gottfried Fischer published the first table of chemical equivalents, which used sulfuric acid with the figure of 1000; similar to the value found by Richter, for the neutralization of sulfuric acid by magnesia.

However, it has been noted that Richter constructed a table of combination weights that indicated the rate at which a number of compounds reacted. For example, it is stated that 859 parts of NaOH neutralize 712 parts of HNO3.

Statements and consequences

The statement of the Richter-Wenzel Law is the following: the masses of two different elements that are combined with the same quantity of a third element, keep the same relationship as the masses of those elements when they are combined with each other.

This law allowed establishing the equivalent weight, or weight-equivalent-gram, as the amount of an element or compound that will react with a fixed amount of a reference substance.

Richter called combination weights relative to the weights of the elements that combined with each gram of hydrogen. The relative combination weights of Richter correspond to what is currently known as the equivalent weight of the elements or compounds..

In accordance with the previous approach, the Richter-Wenzel law can be stated as follows:

The combination weights of different elements that are combined with a given weight of a given element are the relative combination weights of those elements when combined with each other, or multiples or submultiples of these quantity relationships.

Examples

Calcium chloride

In calcium oxide (CaO), 40 g of calcium combine with 16 g of oxygen (O). Meanwhile, in hypochlorous oxide (CltwoO), 71 g of chlorine are combined with 16 g of oxygen. What compound would calcium make if combined with chlorine?

Using the triangle of reciprocity, oxygen is the common element for the two compounds. The mass proportions of the two oxygenates are first determined:

40g Ca / 16 gO = 5g Ca / 2g O

71g Cl / 16g O

And now dividing the two mass proportions of CaO and CltwoOr we will have:

(5g Ca / 2g O) / (71g Cl / 16g O) = 80g Ca / 142g Cl = 40g Ca / 71g Cl

Note that the law of mass proportions is fulfilled: 40 g of calcium react with 71 g of chlorine.

Sulfur oxides

Oxygen and sulfur react with copper to give copper oxide (CuO) and copper sulfide (CuS), respectively. How much sulfur would react with oxygen?

In copper oxide, 63.5 g of copper are combined with 16 g of oxygen. In copper sulfide, 63.5 g of copper binds to 32 g of sulfur. Dividing the mass proportions we have:

(63.5g Cu / 16g O) / (63.5g Cu / 32g S) = 2032g S / 1016g O = 2g S / 1g O

The 2: 1 mass ratio is a multiple of 4 (63.5 / 16), which shows that Richter's law is true. With this proportion, SO, sulfur monoxide is obtained (32 g of sulfur react with 16 g of oxygen).

If you divide this ratio by two, you will get 1: 1. Again, it is now a multiple of 4 or 2, and therefore it is about the SOtwo, sulfur dioxide (32g of sulfur reacts with 32g of oxygen).

Iron sulfide and oxide

Iron sulfide (FeS), in which 32 g of sulfur is combined with 56 g of iron, is reacted with ferrous oxide (FeO), in which 16 g of oxygen are combined with 56 g of iron. This item serves as a reference.

In the reacting compounds FeS and FeO, sulfur (S) and oxygen (O) relative to iron (Fe) are found in the ratio 2: 1. In sulfur oxide (SO), 32 g of sulfur are combined with 16 g of oxygen, so that sulfur and oxygen are in the ratio 2: 1.

This indicates that the law of reciprocal proportions or Richter's law is fulfilled..

The ratio found between sulfur and oxygen in sulfur oxide (2: 1), could be used, for example, to calculate how much oxygen reacts with 15 g of sulfur.

g of oxygen = (15g of S) ∙ (1g of O / 2g of S) = 7.5g

References

  1. Foist L. (2019). Law of Reciprocal Proportion: Definition & Examples. Study. Recovered from: study.com
  2. Cyber ​​Tasks. (2016, February 9). Reciprocal proportions or Richter-Wenzel law. Recovered from: cibertareas.infol
  3. Wikipedia. (2018). Law of reciprocal proportions. Recovered from: en.wikipedia.org
  4. J.R. Partington M.B.E. D.Sc. (1953) Jeremias Benjamin Richter and the law of reciprocal proportions.-II, Annals of Science, 9: 4, 289-314, DOI: 10.1080 / 00033795300200233
  5. Shrestha B. (June 18, 2015). Law of reciprocal proportions. Chemistry Libretexts. Recovered from: chem.libretexts.org
  6. Redefining Knowledge. (July 29, 2017). Law of reciprocal proportions. Recovered from: hemantmore.org.in

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