An avid and methodical experimenter, Jöns Jakob Berzelius (1779–1848) conducted pioneering experiments in electrochemistry and established the law of constant proportions, which states that the elements in inorganic substances are bound together in definite proportions by weight. He is considered one of the founders of modern chemistry.

Berzelius was an accomplished experimenter in many fields, including electrochemistry and atomic and molecular theory. He was a contemporary and rival of Humphry Davy, another electrochemical pioneer, but unlike Davy, Berzelius was much more systematic: he was given to running programs of hundreds of experiments and then deriving organized generalizations from them.


Berzelius was born into a well-educated Swedish family, but he experienced a difficult childhood because first his father and then his mother died. While in medical school at the University of Uppsala, he read about Alessandro Volta’s “electric pile”—an early type of battery—and immediately constructed one for himself. His thesis for his medical degree was on the effect of electric shock on patients with various diseases. Even though he reported no improvement in his patients, his interest in electrochemical topics continued. In 1807 he was made a professor at the Medical College in Stockholm, which soon after became the Karolinska Institute. A year later he began his long association with the Royal Swedish Academy of Sciences.


The “hungry” Berzelius. Presumed to be a portrait of Berzelius at some time between 1800 and 1810.

Royal Swedish Academy of Sciences

The Law of Constant Proportions and Other Discoveries

In preparing a chemistry textbook for his medical students (Lärboki Kemien, vol. 1, 1808), Berzelius began the series of experiments for which he became most famous—those definitively establishing that the elements in inorganic substances are bound together in definite proportions by weight (the law of constant proportions). His interest in all sorts of compounds led to his discovery of a number of new elements, including cerium, selenium, and thorium. Students working in his laboratory also discovered lithium, vanadium, and several rare earths. Using his experimental results, he determined the atomic weights of nearly all the elements then known. Dealing with so many elements in so many compounds motivated his creation of a simple and logical system of symbols—H, O, C, Ca, Cl, and so forth—which is basically the same as the system we use today, except that the combining proportions of the atoms of elements in a compound were indicated as superscripts instead of our subscripts.

Berzelius also applied his organizing abilities to mineralogy, where he classified minerals by their chemical composition rather than by their crystalline type, as had previously been done.


Portrait of Berzelius. Edgar Fahs Smith Collection, Kislak Center for Special Collections, Rare Books and Manuscripts, University of Pennsylvania

Portrait of Berzelius. Frontispiece in Jac. Berzelius: själfbiografiska anteckningar. Utgifna af Kongl. Svenska vetenskapsakademien/genom H.G. Söderbaum (Stockholm: P. A. Norstedt and Söner, 1901).

Edgar Fahs Smith Collection, Kislak Center for Special Collections, Rare Books and Manuscripts, University of Pennsylvania

Electrochemical Dualism

The major intellectual synthesis of Berzelius’s career was “dualism”—a line of thinking that could be traced back to the original electrochemical investigations both he and Davy had made. Because compounds were decomposed by an electrical current and released elements were formed at the poles in an electrolytic cell, he assumed that atoms were charged and chemical combination resulted from the mutual neutralization of opposite charges. Dualistic thinking worked quite well, except in the emerging realm of organic chemistry.

Berzelius was also a great organizer of men and institutions. As the Permanent Secretary of the Royal Swedish Academy of Sciences in Stockholm from 1818 to 1848, he revived what had become a moribund organization. He continued to write textbooks, which were widely translated, and in 1822 he began a series of annual reports on the status of chemistry in Europe, which were also made available in other languages.

The information contained in this biography was last updated on December 1, 2017.