Science and Islam: Challenging History
This blog entry was submitted by Sabour Al-Kandari, the new YorkMSA Blogmaster.
The history of science has always been based upon the cooperation and disclosure of ideas between mankind. Every notable scientist and every remarkable achievement has always been grounded upon the work of predecessors. As Isaac Newton, the father of physics and calculus said, “If I have seen further than others it is because I have stood on the shoulders of giants.” These “giants” that Newton spoke of are recognized to be the pioneers of the scientific revolution, which is known to have began with Copernicus and continued through brilliant minds such as Galileo, Kepler and Descartes. These men are all known to have set the stage for Newton to end the revolution with an exclamation mark and shape modern science in the way it is known today.[1] The flaw with this historical model is that it fails to address the shoulders of the giants from the Islamic world whom Copernicus himself had stood upon. The contributions of Muslim scientists were so ground-breaking from previous global traditions and such foundational keystone ideas that the true revolution of science began in the Islamic world, and the incorrectly named revolution by Europeans was in fact an extension of their effort.
Before one can argue why the work of Muslim scientists changed the entire realm of science one must understand what modern science has become and what it had previously been, thus defining what can be classified as revolutionary. Without such a criterion to judge by, any advancement throughout history can be argued as a part of the scientific revolution all the way back to the invention of the wheel. One must understand that the scientific method today is built upon empiricism, which includes measurements, observations, experimentally testable hypotheses and at the very core mathematical models. This equipment allows for scientists to make their aim mathematically accurate and descriptive theories whose truth can be evaluated with more measurements, observations and experiments. The entire realm of physics is based upon the application of the precision and tools of calculus to describe the observable world. Chemistry is essentially the application of the models derived from physics, and in extension biology is the application of the rules governing chemistry. So in essence, mathematics is the ultimate tool from which all disciplines of science are built. This along with empirical observations and paired with the experimental design allow for initial discovery, constant critique of ideas and reshaping of theories to fit the perceivable world. Theories that are found to be more accurate than previous ideas may be seen as innovative, but these are simply the fruits that are gained from the more important methodology. Even today, centuries after the “revolution” in Europe, there are many breathtaking mysteries and inconsistencies with our scientific models, thus correctness cannot be the heart of what shapes modern science.[2] The ultimate quintessence of science is this scientific approach itself, and the pinnacle of revolutionary insight is what has molded it to take its present form.
The work of the medieval Greeks, Chinese, Persians and Indians however do not contain this rigorous empiricism and mathematization of the world which is characteristic of modern science. In fact, the predecessors of Muslim revolutionaries vehemently opposed the idea of a mathematically describable universe. The Greeks, despite their massive advancements in the field of geometry, were of the Aristotelian view that the powerful math they were already aware of was divorced from the real world. They felt that the world of geometry was an abstract realm composed of perfect shapes of squares, circles and triangles and that the natural world was filled with imperfection and irregular, odd shapes.[3] This Aristotelian view was so widespread and globally accepted that even with Islamic philosophers and scientists it was the dominant view. Also, the scientific theories themselves describing the natural world were not proposed in the form of an experimental and empirical approach, but were tightly knit with philosophical ideas and mythical traditions. Philosophers had created their own personal metaphysical ideas about the nature of the universe and then attempted to fit their observations into this understanding, rather than use observations to shape their understanding of the universe.[4] Such crippling ideas were so far off from a fruitful analytical approach and stood as a complete roadblock eclipsing the true scientific methodology.
Even if the philosophy of the Greeks did not tamper with the worldview of the relationship between science and math, they did not have the tools necessary to unite the two fields. The math required to describe the world relies heavily on the manipulation of equations and the usage of multiple variables – algebra. The term algebra has notable Arabic etymology; its original pronunciation would be Al-Jabr, meaning restoration. The name was coined and the discipline first established by the 7th century Muslim scientist Muhammad ibn Musa al-Khwarizmi in his book, Al-Kitab al-mukhtaṣar fi hisab al-gabr wa’l-muqabala, “The Compendious Book on Calculation by Completion and Balancing.” Because of the massive translation movement pioneered by the Abbasid caliph Al-Ma’mun, a massive wealth of knowledge was brought directly into the Islamic world from all over the globe.[5] This along with the centrality of the Islamic empire in the known world allowed for Al-Khwarizmi to learn the intuitive geometry necessary from the Greeks and pair that knowledge with the precise arithmetic of the Indians. The Greeks themselves could not advance their arithmetic to the level of the Indians because of the clunky nature of their Roman numeral system. The Indians however had established the immensely useful decimal (base ten) system of numerals and were able to quickly speed through multiplications, divisions, additions and subtractions in a few simple steps that would require the Greeks pages of work. Yet at the same time, important geometric calculations and properties of shapes were unheard of for them. Al-Khwarizmi did not simply just put the two together, but it required a very ingenious and revolutionary way of thinking to make use of the two disciplines and create an entirely new one. Beforehand, mathematicians would simply state something such as the square root of one hundred was ten, and ten multiplied by itself was one hundred and then go through the same process with more and more numbers. All of a sudden, Al-Khwarizmi came along with a completely different thought process that the number itself did not matter, and was indeed the least exciting part of the math. The most important part of math would be the usage of all the techniques necessary on the path to the final calculation of an unknown. Now the thought had become something such as any number, regardless of magnitude, would be equal to itself if the root was taken of it and then squared. This, as one can recognize, is also the basis of a very simple algorithm.[6] The name itself algorithm is a failed Latin translation of Al-Khwarizmi’s name and the idea of an algorithm has become the foundation for all of the techniques of algebra, calculus, and even modern computer science.
At first hand, one may not fully grasp the immenseness of this discovery, and the massive centrality of algebra in every aspect of science. With the power of Al-Khwarizmi’s book, scientists finally had the tools necessary to use logical mathematics to describe the behavior of nature. One was able to use geometry to establish precise models based on several variables for the previously thought irregular universe and then seek out and make a few simple observations to grasp hold of a much larger and previously unattainable description of the world. The easiest example for someone to truly appreciate the wonder at hand would be to imagine how a scientist would measure something as impossible as the size of the Earth. Without algebra, the only silly and unfeasible method for determining such a value would be to stick ruler after ruler across the entire world. Using algebra however, the 9th century Muslim scientist Al-Biruni was able to calculate the size of our massive planet using four, and only four, simple measurements that can be replicated within ten minutes. Three angles were measured using a normal astrolabe and one distance using a ruler. With some quick trigonometry and algebra, Al-Biruni was able to calculate the radius of the Earth to awe-inspiring precision, less than one percent off from the known value today![7] This revolutionary idea of being able to describe immensity and complexity previously beyond our reach using mathematical simplicity is truly the endeavor of modern physics. The fruits of this groundbreaking algebra are witnessed with countless marvels throughout time such as Einstein’s famous e=mc², an algebraic equation so simple it only contains two measurable variables and one constant, yet so powerful that mankind can use it to create nuclear weaponry capable of destroying the entire planet.
Along with Al-Biruni, many other Muslim scientists began to separate themselves from the Greek wavelength of thinking. The idea attributed to Copernicus for introducing mathematical models and empiricism was in fact already being developed centuries before him in the Islamic world by the 9th century Muslim scientist Ibn Al-Haytham. He, not Copernicus, originated the revolution of doubt, or shukook in Arabic, of Greek science and philosophy and pioneered the fusion of mathematics, empiricism and experimentation into science. Copernicus is also credited for his fearless challenge of the previously unshakable idea of the geocentric orbit, originated by the Greek Claudius Ptolemaist in the 2nd century. However, evidence from Al-Haytham’s work shows that he was historically the first person to be so heavily critical of Ptolemaist. In one of his books, Al-Haytham challenges the geocentric orbit by saying “Ptolemaist assumes an arrangement that cannot exist.”[8] Although he did not have the observations and mathematical equations necessary to publish a definitive piece destroying Ptolemaist, he was the initiator of future discovery by challenging scientists to do more research and make more observations regarding this illogical geocentric system. The scientists in the Islamic world who would take on this challenge from Al-Haytham would later be the same scientists whose ideas influenced Copernicus.
Along with the revolution of shukook, Al-Haytham is also accredited for being the first man to design the scientific method for experimentation. His ground-breaking work on shukook of Greek optics was not published in the same manner that scientific work was previously published in. Instead of simply presenting his ideas and expecting his readers to believe him, he encouraged reproducibility and analysis of the way he carried out his procedures. He provided testable hypotheses and then sought to prove or disprove them, followed by discussing the results and formulating a conclusion.[9] Such a procedure has become the complete foundation for all the work of science. Every single lab report and scientific research paper is written in the format which Al-Haytham designed. Future scientists in Europe would be so strongly influenced by this methodology that they would use this approach that Al-Haytham had provided them with to carry on their own investigations, leading to the wealth new ideas flowing out of Europe.
As one can see, the fundamental concepts of the scientific approach, mathematization and empiricism, were revolutionized and brought forth out of the crippling style of medieval science originally in the Islamic world and then shared with Europeans. These truly modernizing ideas were poured into Europe through later translations of Arabic work and through the interaction of Muslims and Europeans in Venice, Italy. The strong Islamic influence on Venice can be easily noticed even today with its close similarity to Middle Eastern architecture, notably in the House of the Camel. Shakespeare himself speaks of “merchants and Moores,” Moores being an almost derogatory term for Muslims arriving from the Islamic world to do trade.[10] Texts have been found which show instructions for prospective European merchants looking to travel to the Islamic world to work with Muslims, teaching them how to conduct themselves and even how European’s could attain respect by growing their beards. Many of the foundational works of Muslim scientists were translated into Latin, with Al-Khwarizmi’s book of algebra arriving in the 12th century, approximately 500 years after its initial publishing. The work of another Muslim scientist, Al-Battani, who recorded rigorous observations of celestial bodies in the 8th century, was translated in this time period as well. Even the work of the most famous and influential Muslim physician, Ibn Sina, was translated in the 15th century.[11] At this point, Europeans had the means to acquire knowledge from the beginning of the true scientific revolution in the Islamic world, and they were able to continue this tradition of change with their own magnificent contributions.
Perhaps the most compelling evidence for the continuation of the Muslim scientific revolution through to Europe can be seen within Copernicus’s work itself. In his book which is claimed to have begun the revolution in the 14th century, De revolutionibus orbium coelestium, “On the Revolutions of the Celestial Spheres,” Copernicus made massive use of the observational data tables provided by Al-Battani almost 700 years prior. Even if the modern historical account cannot accept Copernicus to be the intellectual heir of Muslims, Copernicus himself quotes Al-Battani and mentions his great debt to him.[12] As if the influence of rigorous observations and the algebraic methodology was not enough, there is also even pejorative evidence that Copernicus had directly copied, possibly even plagiarized, the work of another Muslim scientist, Nasir al-Din Al-Tusi, without any recognition. Al-Tusi was the leader of the first observatory used as a center for scientific research in the world during the period of the Mongol invasion in the 11th century, and there he made countless observations and rigorous measurements of the motion of heavenly bodies. Most notably however, he is known for his correction of many problems in Ptolemaist’s geocentric model by proposing the mechanism known as the Tusi couple. In his work, he uses geometric and algebraic diagrams to express how planets move in the form of circles embedded within other circles. When compared to Copernicus’ work, one can see an illustration in which there is an exact replica of the diagram Tusi used in his book to explain the Tusi couple. The diagram Copernicus uses is so alike, that even the variables Al-Tusi made use of in Arabic such as “alif, dal, jum” and so on correspond to the exact same sounding letters in Latin, “A, D, G” and so on in precisely the same spots Tusi used in his own diagram.[13] Such decisive proof shows that Copernicus, the “father” of the scientific revolution, was indeed firmly based on the shoulders of previously established Muslim scientific endeavors.
With so many keystone and groundbreaking ideas stemming out of the Islamic world which had direct influence on Europe, one cannot help but question the modern historical account of the scientific revolution. As stated previously, the contributions of Islamic scientists were so crucial because they directly shaped modern science itself, and they were so radically different from previous thought, that the Islamic scientists must belong to the scientific revolution. The revolution more accurately begins with Al-Khwarizmi’s development of algebra, the essence which gives all science possibility. This revolution then continued through many, many notable scientists in the Middle East such as Al-Haytham, Al-Biruni and Al-Tusi. The intellectual movement then bridged to Europe through Copernicus, and continued from there through the ingenious minds of Galileo, Kepler and Descartes for the revolution to be finalized and the shape of modern science to be completed by Isaac Newton. To truly honor the work of pioneers, there is a tradition within science to name units of measurement and new discoveries after past scientists, such as the newly discovered element 112 Copernicium. Since Al-Khwarizmi is still technically recognized with algorithm, it is proposed for scientists to remain true to their historical heritage and upon discovery of element 113, grant it the name Haythamium.
“The bulk of the research for this essay is credited to this very entertaining documentary, which can easily be found online. Al-Khalili, Jim. “Science and Islam” on BBC Four. (Oxford Scientific Films), 2009.
1 Thomas Kuhn, The Copernican Revolution (Cambridge: Harvard Univ. Pr., 1957), 142.
2 Henry P. Stapp, ”Mindful Universe: Quantum Mechanics and the Participating Observer,” Springer, 2007, 145-146.
3 J. Al-Khalili, “Science and Islam” on BBC Four, (Oxford Scientific Films), 2009.
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about 10 months ago
Jazakallahu enjoyed the Read. Didn’t know that much about the critical role Al-Khwarizmi.
The essay uses the word “keystone” I think I know who wrote this!
about 10 months ago
One follow up question though. Why did Muslims stop advancing scientifically and are so behind? Was the advancement related to simply ingenious individuals or due to an atmosphere or system where these were the by-product from their way of life?
about 10 months ago
LOL I only used keystone twice! You have an excellent memory, mash’Allah.
Excellent question, and I think this is an entire discussion in and of itself.
I would argue that the Muslim world isn’t as behind as it’s made out to be. It definitely isn’t leading, but I think this “they are so messed up” paradigm is partially from a very Euro-centric worldview from previous generations and part of the propaganda of our generation to sort of dehumanize and justify occupations. If you sift through some scientific journals you can find a lot of published work coming out of universities in the Middle East. One very notable example and despite it’s immaturity, Saudi Arabia’s research-focused KAUST is showing a lot of promise as a player on the world stage.
Even a generation ago in Afghanistan, my dad has a degree from University of Kabul in physics and math, and he got a letter from UofT telling him his degree is the equivalent of a BSc. from an Ontario University. I’m sure there a ton of examples from all over of highly educated immigrants from the Muslim world.
With that being said, my personal opinion is that a huge cause of the decline from being on top is the Mongolian invasion. The Golden Age of Islam is commonly dated to have ended the day of the sack of Baghdad in 1258, and that event had such traumatic effects that I don’t think the Ummah every really recovered from. You’ll notice how Nasir al-Din Al-Tusi was one of the “bridges” into Copernicus, and he was living during the invasion. He only really got to continue his work because he convinced his Mongolian overlords that his observatory could help them (I think it had something to do with astrology).
There’s a lot of really amazing technology we’ve uncovered from that time (fire-proof suits, above-water torpedo’s), you can really only imagine all of the things that we may never know about permanently lost after being ravaged so heavily. I’ve heard of some legendary tales from Baghdad like pre-ice age world maps and electrochemistry, but they’re just stories without hard evidence. Even if they are true, all the books were probably burnt.
Now imagine a post-invasion recovering Islamic world where Europeans had now taken the lead. I think I remember your essay on the abandonment of ijtihad being another contributing factor. The Islamic science goes into Europe and they build upon it, but it’s a one way street. The new European science can get labeled as “kufr knowledge”, especially in a world where a lot of Muslims are blaming the philosophers for incurring Divine punishment. Things like the printing press aren’t accepted either, so it becomes very difficult to catch up and I guess things just sort of stayed that way. Another key point, science goes where the money goes. And an economically challenged world can’t produce the same results as a flourishing country free from political turmoil.
So to answer your question, it’s all about the atmosphere and system. Politics play a huge role in how science and technology develops. Einstein was German, but he sent a letter to a US president initiating the Manhattan Project for nuclear weapons.
about 10 months ago
I will say this though, I think the way Muslims spread out all over the world in our generation has similar consequences to Harun al-Rashid’s Bayt al-Hikma that started the whole revolution. The difference is instead of world knowledge coming to us, we’ve gone to the rest of the world.
There are huge amounts of practicing Muslim men and women that are educated with Bachelors, Masters and PhD’s from prestigious world universities. I was reading a recent debate about the niqab in Canada and the woman supporting the niqab had a PhD from Harvard in chemical physics. I can think of another write for MuslimMatters, a niqabi herself, who has a masters in mechanical engineering.
So all this history doesn’t seem so far off from us anymore. You just have to ask around our own MSA prayer hall and see how many brothers/sisters are doing their masters/PhD, mash’Allah.
=D}
about 10 months ago
JazâkAllâh khayr for the blog entry. I’m happy to have you as Blogmaster and look forward to perhaps more blog entries from you.
On a side note, I hope no one gets intimidated by the length or research put into this. Although, as mentioned in the guidelines, there will be a minimum standard when it comes to quality, blog submissions do not have to be this long or this well-written, mâ shâ Allâh, to be accepted. =-)
about 10 months ago
Wa iyyakum,
Thanks for bringing that up, this is actually freakishly large for a blog post. It’s really an essay I wrote for a course last year.
2 birds < 1 stone, hah!
about 10 months ago
Great reading! It’s sad to see how the Muslim scientists who played a role in the scientific revolution hardly get mentioned or acknowledged.
about 10 months ago
Jazak’Allah khair sister,
Part of the issue is that for any country the core education system tends to focus on the history of the country itself i.e. you’re not very likely to learn about Canadian Aboriginals in Germany. As for science class, I have actually been taught by a number of my teachers/professors about science from the Muslim world, but since the physics/chemistry/biology is mostly Newtonian and onward, it doesn’t really make sense to spend a lot of class time on previous work. If there were any classes just on scientific history there would be a lot more mentioning there.
If you do a bit of snooping, you’ll see there are a number of really great docs around praising the work of Muslim scientists. This essay is heavily based on the 3-hour documentary “Science and Islam” by Professor Jim Al-Khalili (non-Muslim). And I also think we all remember the huge “Sultans of Science” exhibit at the Science Center a while back.
So there really is a TON of content out there, it’s just up to us and everyone else to tune in to them.
about 2 months ago
I enoyed this blog and the discussions that followed, I taught you well young grasshopper (Sabour)
about 1 month ago
MashAllah, good stuff. I admit I was one of those who were afraid to get into the article thinking it was too much lol, but I’m definitely glad I pressed on and read it. Like Quadri mentioned a fruitful discussion occurred after, which was beneficial just as the article was. I expect to see more history stuff coming from you inshAllah!