Muslim scientist
Islamic Golden Age |
|
15th-century European portrait of "Geber", Codici Ashburnhamiani 1166, Biblioteca Medicea
Laurenziana, Florence
|
| Name: |
Jabir ibn Hayyan |
| Title: |
Geber |
| Birth: |
721 CE |
| death: |
c. 815 CE |
| Main interests: |
Alchemy and Chemistry, Astronomy,
Astrology, Pharmacy, Philosophy, Physics, Physician |
| works: |
Kitab al-Kimya, Kitab al-Sab'een,
Book of the Kingdom, Book of the Balances ,
Book of Eastern Mercury, etc |
| Influences: |
Ja'far al-Sadiq |
| Influenced: |
Chemistry |
- "Jabir ibn Hayyan" and "Geber" were also pen names of an anonymous 14th century
Spanish alchemist: see Pseudo-Geber. For the crater, see Geber (crater).
Abu Musa Jābir ibn Hayyān (Arabic: جابر بن حيان) (c. 721–c. 815), known also by his Latinised name
Geber, was a prominent Muslim polymath: a
chemist and alchemist, astronomer and
astrologer, engineer,
philosopher, pharmacist and
physician, and physicist and scientist. He has been widely referred to as the
"father of chemistry". Although most sources state that he was an Arab,[1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] other sources describe
him as Persian.[17][18][19][20]
Ibn Hayyan is widely credited with the introduction of the experimental method in
alchemy, and with the invention of numerous important processes still used in modern chemistry
today, such as the syntheses of hydrochloric and nitric acids,
distillation, and crystallisation. His original
works are highly esoteric and probably coded, though nobody today knows what the code is. On
the surface, his alchemical career revolved around an elaborate chemical numerology based on
consonants in the Arabic names of substances and the concept of takwin, the artificial creation of life in the alchemical laboratory.
Biography
An artistic depiction of Geber
Jabir was born in Tus, Khorasan, in Iran, then under the rule of the Umayyad Caliphate; the date of his birth is
disputed, but most sources give 721 or 722[citation needed]. He was the son of Hayyan al-Azdi, a
pharmacist of the Arabian Azd
tribe who emigrated from Yemen to Kufa (in present-day
Iraq) during the Umayyad Caliphate. Hayyan had supported the Abbasid revolt against the Umayyads, and
was sent by them to the province of Khorasan (in present Iran) to gather support for their
cause. He was eventually caught by the Ummayads and executed. His family fled back to Yemen,[21] where Jabir grew up and studied the Koran, mathematics and other subjects
under a scholar named Harbi al-Himyari.[21] After the Abbasids took power, Jabir went back to Kufa, where he spent
most of his career.
Jabir's father's profession may have contributed greatly to his interest in alchemy. In Kufa
he became a student of the celebrated Islamic teacher and sixth Imam Ja'far al-Sadiq. He began his career practising medicine, under the patronage of the Barmakid Vizir of Caliph Haroun
al-Rashid. It is known that in 776 he was engaged in alchemy in Kufa.
His connections to the Barmakid cost him dearly in the end. When that family fell from grace in 803, Jabir was placed under house arrest in Kufa, where he remained until his death. The date of his death is given
as c.815 by the Encyclopædia Britannica, but as 808 by other sources.
Contributions to chemistry
Jabir is mostly renowned for his contributions to the modern discipline of chemistry, though at the time it was pre-alchemy.
He emphasised systematic experimentation, and did much to free alchemy from superstition and turn it into a science. He is credited with the invention
of many types of now-basic chemical laboratory equipment, and with the discovery and description of many now-commonplace chemical
substances and processes – such as the hydrochloric and nitric acids,
distillation, and crystallisation – that have
become the foundation of today's chemistry and chemical
engineering.
He also paved the way for most of the later Islamic alchemists, including Razi,
Tughrai and al-Iraqi, who lived in the 9th, 12th and 13th
centuries respectively. His books strongly influenced the medieval European alchemists and justified their search for the
philosopher's stone.
He clearly recognised and proclaimed the importance of experimentation. "The first essential in chemistry", he declared, "is
that you should perform practical work and conduct experiments, for he who performs not practical work nor makes experiments will
never attain the least degree of mastery."
Jabir is also credited with the invention and development of several chemical instruments that are still used today. By
distilling various salts together with sulfuric acid, Jabir discovered hydrochloric acid (from salt) and nitric acid (from saltpeter). By combining the two, he invented
aqua regia, one of the few substances that can dissolve gold.
Besides its obvious applications to gold extraction and purification, this discovery would fuel the dreams and despair of
alchemists for the next thousand years. He is also credited with the discovery of citric
acid (the sour component of lemons and other unripe fruits), acetic acid (from vinegar), and tartaric acid (from wine-making
residues).
Jabir applied his chemical knowledge to the improvement of many manufacturing
processes, such as making steel and other metals, preventing rust, engraving gold, dyeing and waterproofing cloth, tanning leather, and
the chemical analysis of pigments and other substances. He developed the use of manganese
dioxide in glassmaking, to counteract the green tinge produced by iron — a
process that is still used today. He noted that boiling wine released a flammable vapor, thus
paving the way to Al-Razi's discovery of ethanol.
The seeds of the modern classification of elements into metals and non-metals could be seen in
his chemical nomenclature. He proposed three categories:[22]
- "Spirits" which vaporise on heating, like arsenic (realgar,
orpiment), camphor, mercury, sulfur, sal ammoniac,
and ammonium chloride.
- "Metals", like gold, silver, lead, tin, copper, iron, and khar-sini;
- Non-malleable substances, that can be converted into powders, such as stones.
In the Middle Ages, Jabir's treatises on alchemy were translated into Latin and became
standard texts for European alchemists. These include the Kitab
al-Kimya (titled Book of the Composition of Alchemy in Europe), translated by
Robert of Chester (1144); and the Kitab al-Sab'een by Gerard of Cremona (before 1187). Marcelin Berthelot translated some of his books under the
fanciful titles Book of the Kingdom, Book of the
Balances, and Book of Eastern Mercury. Several technical terms introduced by
Jabir, such as alkali, have found their way into various European languages and have
become part of scientific vocabulary.
Contributions to alchemy
Jabir became an alchemist at the court of Caliph Harun
al-Rashid, for whom he wrote the Kitab al-Zuhra ("The Book of Venus", on "the noble art of alchemy").
Jabir states in his Book of Stones (4:12) that "The purpose is to baffle and lead into
error everyone except those whom God loves and provides for". His works seem to have been deliberately written in highly esoteric
code (see steganography), so that only those who had been initiated into his alchemical
school could understand them. It is therefore difficult at best for the modern reader to discern which aspects of Jabir's work
are to be read as symbols (and what those symbols mean), and what is to be taken literally. Because his works rarely made overt
sense, the term gibberish is believed to have originally referred to his writings (Hauck, p.
19).
Jabir's alchemical investigations ostensibly revolved around the ultimate goal of takwin — the artificial creation of life. The Book of Stones includes several recipes for creating
creatures such as scorpions, snakes, and even humans in a laboratory environment, which are subject to the control of their creator. What Jabir meant by these
recipes is today unknown.
Jabir's interest in alchemy was probably inspired by his teacher Ja'far al-Sadiq.
Rumours of him being a Sufi is mostly fabricated for the main reason that no such school (i.e., Sufism) existed during that era
of Islamic history. Ibn Hayyan was deeply religious, and repeatedly emphasizes in his works that alchemy is possible only by
subjugating oneself completely to the will of Allah and becoming a literal instrument of Allah on
Earth, since the manipulation of reality is possible only for Allah. The Book
of Stones prescribes long and elaborate sequences of specific prayers that must be performed without error alone in the
desert before one can even consider alchemical experimentation. Alchemy had a long relationship with Shi'ite mysticism; according to the first Imam, Ali ibn Abi Talib,
"alchemy is the sister of prophecy".
In his writings, Jabir pays tribute to Egyptian and Greek alchemists Hermes
Trismegistus, Agathodaimon, Pythagoras, and
Socrates. He emphasises the long history of alchemy, "whose origin is Arius ... the first man
who applied the first experiment on the [philosopher's] stone... and he declares that man possesses the ability to imitate
the workings of Nature" (Nasr, Seyyed Hossein, Science and Civilization of Islam).
Jabir's alchemical investigations were theoretically grounded in an elaborate numerology
related to Pythagorean and Neoplatonic systems. The
nature and properties of elements was defined through numeric values assigned the Arabic
consonants present in their name, ultimately culminating in the number 17.
To Aristotelian physics, Jabir added the four properties of hotness, coldness, dryness, and
moistness (Burkhardt, p. 29). Each Aristotelian element was characterised by
these qualities: Fire was both hot and dry, earth cold and dry, water cold and moist, and air hot and moist. This came from the
elementary qualities which are theoretical in nature plus substance. In metals two of these qualities were interior and two were
exterior. For example, lead was cold and dry and gold was hot and moist. Thus, Jabir theorised, by rearranging the qualities of
one metal, based on their sulfur/mercury content, a different metal would result. (Burckhardt, p. 29) This theory appears to have
originated the search for al-iksir, the elusive elixir that would make this transformation
possible — which in European alchemy became known as the philosopher's stone.
Jabir also made important contributions to medicine, astronomy/astrology, and other sciences. Only a few of his books have been edited and published,
and fewer still are available in translation. The Geber crater, located on the
Moon, is named after him.
Popular Culture
Quote
- "My wealth let sons and brethren part. Some things they cannot share: my work well done, my noble heart — these are mine own
to wear."[24]
What others have said about Jabir
- Max Meyerhoff: "His influence may be traced throughout the whole historic course of European
alchemy and chemistry."[25]
Writings by Jabir
The writings of Jabir Ibn Hayyan can be divided into four categories:
- The 112 Books dedicated to the Barmakids, viziers of Caliph Harun al-Rashid. This group includes the Arabic version of the Emerald Tablet, an ancient work that is the foundation of the Hermetic or "spiritual" alchemy. In the Middle Ages it was translated into Latin (Tabula Smaragdina) and
widely diffused among European alchemists.
- The Seventy Books, most of which were translated into Latin during the Middle Ages. This group includes the Kitab
al-Zuhra ("Book of Venus") and the Kitab Al-Ahjar ("Book of Stones").
- The Ten Books on Rectification, containing descriptions of "alchemists" such as Pythagoras, Socrates, Plato and
Aristotle.
- The Books on Balance; this group includes his most famous 'Theory of the balance in Nature'.
Some scholars suspect that some of these works were not written by Jabir himself, but are instead commentaries and additions
by his followers. In any case, they all can be considered works of the 'Jabir' school of alchemy.
Translations of Jabir
- E. J. Holmyard (ed.) The Arabic Works of Jabir ibn Hayyan, translated by
Richard Russel in 1678. New York, E. P. Dutton (1928); Also Paris,
P. Geuther.
- Syed Nomanul Haq, Names, Natures and Things: The Alchemists Jabir ibn Hayyan and
his Kitab al-Ahjar (Book of Stones), [Boston Studies in the Philosophy of Science p. 158] (Dordrecht: Kluwer Academic
Publishers, 1994).
- Donald R. Hill, 'The Literature of Arabic Alchemy' in Religion: Learning and
Science in the Abbasid Period, ed. by M.J.L. Young, J.D. Latham and R.B. Serjeant (Cambridge University Press, 1990) pp.
328-341, esp. pp 333-5.
- William Newman, New Light on the Identity of Geber, Sudhoffs Archiv, 1985, Vol.69, pp. 76-90.
References
- ^ History of Analytical Chemistry By Ferenc Szabadváry,P 11,ISBN
2881245692.
- ^ The Historical Background of Chemistry By Henry Marshall Leicester,P
63.
- ^ Alchemy,Eric John Holmyard,P 68.
- ^ Dragon's Brain Perfume an Historical Geography of Camphor, Robin Arthur
Donkin, P 137.
- ^ The Grand Contraption The World as Myth, Number, and Chance, David Allen
Park, P 229.
- ^ Cosmology in Gauge Field Theory and String Theory, By David Bailin,
Alexander Love, P 181.
- ^ The New Book of Knowledge, ISBN 0717205177, Page 446.
- ^ The Biology of Alcoholism, By Benjamin Kissin, Henri Begleiter,P 576.
- ^ Medieval Science, Technology, and Medicine,By Thomas F. Glick, Steven John
Livesey,Faith Wallis,ISBN 0415969301,P 280
- ^ A History of Chemistry By Forris Jewett Moore,P 15.
- ^ E. J. Brill's First Encyclopaedia of Islam, 1913-1936 By M. Th. Houtsma,
E. van Donzel,ISBN 9004082654,P 989.
- ^ In Old Paris,By Robert W. Berger,P 164,ISBN 0934977666.
- ^ Chemical Essays By Richard Watson,P 68
- ^ Jabir, Columbia Encyclopedia, Sixth Edition,
2001-2005.
- ^ Jabir, Columbia Encyclopedia, Sixth
Edition, 2004.
- ^ Jabir, Columbia Encyclopedia, Sixth
Edition, 2007.
- ^ A Dictionary of the History of Science by by Anton Sebastian - p.
241
- ^ The Alchemical Body By David Gordon - p. 366
- ^ The Structure and Properties of Matter by Herman Thompson Briscoe - p.
10
- ^ The Tincal Trail: A History of Borax by Edward John Cocks, Norman J.
Travis - p. 4
- ^ a b E. J. Holmyard (ed.) The
Arabic Works of Jabir ibn Hayyan, translated by Richard Russel in 1678. New York, E. P. Dutton (1928); Also Paris, P. Geuther.
- ^ Georges C. Anawati, "Arabic alchemy", in R. Rashed (1996), The
Encyclopaedia of the History of Arabic Science, Vol. 3, p. 853-902 [866].
- ^ Coelho, Paulo. The Alchemist. ISBN 006112416, p. 82.
- ^ Holmyard, Eric John. Alchemy. Page 82
- ^ Ḥusain, Muẓaffar. Islam's Contribution to Science.
Page 94.
External links
See also
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