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{{infoboxinfobox1
|title=Higgs Force
|author=Nicholas Mee
|borrow=Yes
|isbn=978-0718892753
|pages=33o
|publisher=The Lutterworth Press
|date=January 2012
|website=http://www.higgsforce.co.uk/
}}
Most books introducing the complexities of particle physics inevitably have a somewhat steep learning curve. Dr Mee handles this by dispensing, as far as possible, with complex mathematics and makes excellent use of interesting diagrams. He also inserts some problems for readers that prompt engagement in the text. These are good for the brain and make it a most suitable text for sixth formers and first year undergraduates.
The first third of '''Higgs Force''' is an introduction to basic atomic theory, symmetry, and the creation of elements during the evolution of stars. Our bodies, containing carbon, oxygen and hydrogen, amongst other elements, were formed in nuclear reactions in the high temperatures in stellar interiors. We are all literally composed of this star dust.
Our knowledge of the conditions in stars is largely derived from the study of spectra from the light emitted from them. This 'barcode' is explained in terms of the theory of quantum mechanics. This theory was developed by Bohr, Heisenberg and Erwin Schrödinger. Heisenberg's discovery of the Uncertainty Principle, and his putative work for the Nazis on the Bomb, and indeed his intense arguments with Bohr are featured in Michael Frayn's remarkable play, ''Copenhagen''. Nicholas Mee, however, remarks how Heisenberg's matrix mechanics in the early 1930s could be proved equivalent to Schrödinger's wave mechanics and explains the 'barcode' spectra of the hydrogen atom and much else besides. In the next chapter on quantum electrodynamics (QED), Dr Mee shows how the weak interactions between electrons and virtual photons were independently explained by the complex mathematics of Julian Schwinger, on the tiny magnetic field of spinning electrons, and the more intuitive diagrams of his fellow New York scientist, the brilliant Richard Feynman. Two Englishmen also feature in this story, in a manner that retains human interest, the strange Paul Dirac from Bristol-his father was actually French- and the talented mathematician and eloquent expositor, Freeman Dyson. Thus the essential underlying concepts of this type of physics; symmetry, equivalence and symmetry breaking are all explained in an accessible manner.
'''Higg's Force''' neatly balances theory with an account of experimental techniques for creating high energy collisions and the resulting observed particles by means of detectors. There is a neat account of how neutrinos were originally discovered and the instrumentation then refined. The description of the injection of the initial protons into the Main Ring of the CERN accelerator captures the excitement of the very first experiments at Geneva, some 40 years ago now. Computer techniques for the sifting and analysis of experimental data are indicated and notably, the development by Sir Timothy Berners-Lee of what was to become the world-wide Web, doubtless the best known spin-off from the biggest internet node in Europe. The notable gigantic ATLAS detector with its hadron calorimeter and shielding is explained using cut-away diagrams.
Perhaps, the author might have added some magnificent coloured plates but this would have added considerably to the cost. Clear diagrams explain the patterns of the leptons, quarks and their respective anti-particles; these constitute the so-called Standard Model. The mechanism by which the Higgs particle breaks the symmetry of the electro-weak forces is indicated and the connection with the now famous Mexican hat diagram. A useful appendix which contains more algebra indicates the role the Higgs particle has in relation to the force field which is responsible for the creation of mass. Confirmation of this Higgs mechanism could be with us during this year and with it a more complete understanding of the earliest fraction of a second following the big bang.
Dr Mee has provided us with an exposition which repays close reading in the fine tradition of books like P.C.W. Davies, ''The Forces of Nature'' and Frank Close's classic on quarks, ''The Cosmic Onion''. However, should it turn out that photons really do travel faster than light, then yet another scientific revolution may take place and the whole physics community will be back to ruminating on the shifting paradigms like Viktor Jakob, the proponent in that marvellous fictional account by Mccormack entitled, ''Night Thoughts of a Classical Physicist''!
Many thanks are due to the Lutterworth Press for providing this volume for consideration.
[[Quantum Theory Cannot Hurt You by Marcus Chown]]
[[Gravity, Cracking the Cosmic Code by Nicholas Mee]] {{amazontext|amazon=0718892755}} {{waterstonestextamazonUStext|waterstonesamazon=8621265B00727LKW6}}
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