Plus Blog
May 9, 2007
Wednesday, May 09, 2007
Live maths  tangled DNA, the Big Bang and musical superstringsTwisting, Coiling, Knotting: Maths and DNA ReplicationThe proportions of a DNA molecule in a human cell are equivalent to a 2000milelong rope packed inside the Millennium Dome. When DNA replicates, it spins at an astonishing 10 turns per second. Therefore, it is hardly surprising that DNA can become highly twisted, supercoiled and even knotted! To understand this phenomenon, the molecular biologist must grapple with the mathematical concepts of twisting, writhing and knotting. In this highlyillustrated talk Professor Michael Thompson FRS will experiment with strings and rubber bands (bring your own!) to explore the geometrical rules which underlie the transmission our genetic code. When: Thursday 24th of May 2007, 5pm  6pm Dinner@Dana: Back to the Big BangIn honour of the Large Hadron Collider, the Dana Centre is holding an evening dinner and discussion attended by the expert James Gillies from CERN. There'll be slide shows and photographs and a twocourse meal inspired by particle physics. When: 15th of May 2007, 6.30pm  8.30pm Also the Science Museum in London has put on an exhibition in honour of the Large Hadron Collider. The exhibition is free and will run until the 7th of October 2007. Superstrings  a Musical Journey through Time and SpaceYou probably knew that Einstein was a great scientist, but did you also know that he played the violin? In this unique double act a virtuoso violinist and the head of the department of particle physics at Oxford University combine the electricity of a live musical performance with an insight into the deepest corners of the Universe. The lecture explores Einstein's life, both in science and in music, from his theories that shaped space and time, to modern ideas in particle physics. When: 18th of May 2007 5pm7pm posted by Plus @ 10:03 AM 0 Comments: 
May 3, 2007
Thursday, May 03, 2007
Mathematical formIn the Imaging maths series Plus explored how to visualise, transform and unfold strange geometric objects like the Klein bottle or the Möbius strip. Now Plus has come across a British artist who does just that, but without the aid of computers. John Pickering bases his work on one simple mathematical transformation, the inversion in a circle. His works are beautifully intricate 3D objects made up of 2D slices, with each slice and its relationship to the others worked out using honest and rigorous coordinate geometry. Unfortunately, Pickering's work can't be seen on the web, so if you're interested in mathematical art, keep an eye out for one of his exhibitions. Alternatively, there is a book on Pickering's art called Mathematical form: John Pickering and the architecture of the inversion principle, published by the Architectural Association. posted by Plus @ 8:46 AM 0 Comments: 
April 16, 2007
Monday, April 16, 2007
Happy birthday, Leonhard Euler!Leonhard Euler, born on the 15th of April 1707 in Basel, Switzerland, would have turned 300 yesterday! In the current issue Plus kicks of a celebratory series of articles with Robin Wilson's "Read Euler, read Euler, he is the master of us all.". Here is a taster of Wilson's article. Euler was the most prolific mathematician of all time. He wrote more than 500 books and papers during his lifetime — about 800 pages per year — with an incredible 400 further publications appearing posthumously. His collected works and correspondence are still not completely published: they already fill over seventy large volumes, comprising tens of thousands of pages. Euler worked in an astonishing variety of areas, ranging from the very pure — the theory of numbers, the geometry of a circle and musical harmony — via such areas as infinite series, logarithms, the calculus and mechanics, to the practical — optics, astronomy, the motion of the Moon, the sailing of ships, and much else besides. Indeed, Euler originated so many ideas that his successors have been kept busy trying to follow them up ever since. Not surprisingly, many concepts are named after him: Euler's constant, Euler's polyhedron formula, the Euler line of a triangle, Euler's equations of motion, Eulerian graphs, Euler's pentagonal formula for partitions, and many others. Euler's career took him from his native Basel to the Academy at St Petersburg, where he eventually became Professor of Mathematics, to the Berlin Academy, on invitation from Prussia's Frederick the Great, and finally back to St Petersburg. He fathered thirteen children, of whom only five survived to adolescence, and reportedly carried out mathematical researches with a baby on his lap. He died in St Petersburg on the 18th of September 1783. In a eulogy by the Marquis de Condorcet, we read about his final afternoon: On the 7th of September 1783, after amusing himself with calculating on a slate the laws of the ascending motion of air balloons, the recent discovery of which was then making a noise all over Europe, he dined with Mr Lexell and his family, talked of Herschel's planet (Uranus), and of the calculations which determine its orbit. A little after, he called his grandchild, and fell a playing with him as he drank tea, when suddenly the pipe, which he held in his hand, dropped from it, and he ceased to calculate and to breathe. The Plus article "Read Euler, read Euler, he is the master of us all." gives a broad overview of Euler's life and work, but you can also find out more in the following articles: posted by Plus @ 9:05 AM 0 Comments:
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March 28, 2007
Wednesday, March 28, 2007
Sad news: Paul Cohen diesThe distinguished mathematician Paul Cohen sadly died on Friday the 23rd of March 2007, just a few days before his 73rd birthday. Cohen worked on a range of topics, but is bestknown for his work on set theory. His work in this area cuts right down to the foundations of mathematics. The mathematician David Hilbert famously believed that it should be possible to phrase all of mathematics in a single and completely formal theory. Based on a collection of axioms — predetermined facts that are so selfevident they do not themselves need to be proved — and the rules of logic, it should be possible to formally prove every mathematical truth and to arrive at a complete theory that is free from contradiction. Set theory provides a language in which such a formal system might be phrased. In maths a set is simply a collection of objects. The objects themselves are allowed to remain abstract and so you can talk about all mathematical objects — whether they are functions, numbers or anything else — in terms of sets. In the beginning of the twentieth century, mathematicians laid down a list of axioms and rules of logic that resulted in a formal and rigorous theory of sets. The system is known as ZF theory, after Ernst Zermelo and Abraham Fraenkel. On the face of it, sets are simple objects. But once you allow them to have an infinite number of elements, things become complicated. If you take the set of whole numbers, for example, and compare it to the set of all numbers, you'll notice that although both sets are infinite, they are fundamentally different from each other. The set of whole numbers consists of isolated objects, whereas you can think of all the numbers as merging together to give a continuum. In some sense, the set of all numbers is "bigger" than the set of whole numbers, so we need a notion of size for infinite sets also. The mathematician Georg Cantor (1845  1918) formalised such a notion, called cardinality, and in doing so came up with a conjecture that became known as the continuum hypothesis: that there is no set that is "larger" than the set of whole numbers and "smaller" than the set of all numbers. However, a proof of this fact illuded Cantor and the continuum hypothesis became the first on Hilbert's list of mathematical challenges for the 20th century. When it comes to the axioms of set theory, things aren't all that clearcut either. Some axioms are clear as day, for example the one which states that two sets are the same if all their elements are the same. Others are more controversial though, and one of them is the axiom of choice. It states that if you have a collection of sets, then you can form a new set by picking one element from each. Again, this is clearly possible when you've got a finite collection of sets, but if there are infinitely many, it's not clear that a mechanism for picking an element from each always exists. Although the majority of mathematicians accept the axiom of choice, there is a school of thought which doubts it. Paul Cohen proved two significant — and to the Hilbert school of thought disappointing — results in this area. He showed that neither the continuum hypothesis nor the axiom of choice can be proved from the axioms of ZF theory. Together with results previously proved by Kurt Gödel, this means that neither can be proved to be either true or false within ZF theory. Within ZF theory, the continuum hypothesis will forever remain a mystery. As far as the axiom of choice is concerned, the result means that there's no clear indication as to whether you should include it or its negation as one of your initial axioms of set theory. In both cases you come up with a sound system, so the decision whether to include it or not has to be made on different grounds. In proving these results, Cohen not only contributed to the philosophical debate about the foundations of maths, but also developed a whole new set of tools to deal with questions on what can and cannot be proved within formal mathematical systems. His work was honoured with a Fields medal in 1966. The world of maths has lost one of its most distinguished members. posted by Plus @ 10:27 AM 0 Comments: 
March 27, 2007
Tuesday, March 27, 2007
Careers magazines from Arberry PinkWe have recently come across a great range of career magazines for students and graduates from different backgrounds. KAL (for ethnic minority university students and graduates), Number Ten (for female university students and graduates), The Arberry Profile (for disabled university students and graduates), Spectrum (for ethnic minority secondary school students) and Mint (for female secondary school students) are produced by the people at Arberry Pink. Each magazine contains information about different areas of employment, with interviews with people working in these fields and information on employers. The latest issue of Spectrum has a feature on science and engineering, which talks to people from the British Antarctic Survey, a space mission scientist, and a geochemist. Also the magazines are all written and edited by a team of students, in collaboration with the staff at Arberry Pink. So if you are looking for experience in journalism why not consider getting involved? posted by Plus @ 12:43 PM 0 Comments: 
March 21, 2007
Wednesday, March 21, 2007
Say hello to Plus!As part of the Cambridge Science Festival, the Centre for Mathematical Sciences (home of Plus) is having an open day on Saturday 24 March. You can come and meet some of the Cabridge mathematicians who work on everything from gravity and black holes to climate change, disease dynamics and how bacteria swim. There will be handson activities, demonstrations, computer models and displays share some of the wonders of mathematics and theoretical physics. And the Plus team will be there so come and say hello to us at the MMP stand! When: Saturday 24th March 2007, 12.00  4.00 pm And while you there, why not catch one of these talks. No ticket is necessary, just turn up in good time to secure a seat. CURVED SURFACES  Popular lecture by Prof Alan Beardon. Every point of an orange can be in contact with a table top; why is the same not true of a banana? Why is it more difficult to wrap a football in paper than it is to wrap a box in paper? How do we represent the curved surface of the earth on a flat piece of paper? How do we navigate around the surface of the earth? Saturday 24th March 2007, 12.15  1.15 pm AVALANCHE!  Popular lecture by Dr Jim McElwaine More than a million avalanches happen throughout the world every year. Most fall harmlessly, but the largest can destroy whole towns and kill thousands. This nontechnical multimedia talk describes one mathematician's efforts to understand snow avalanches, from investigating disasters in the Japanese mountains to dropping half a million pingpong balls down a ski jump. Saturday 24th March 2007, 2.00  3.00 pm posted by Plus @ 2:05 PM 0 Comments: 