John Gribbin

Science: A History in 100 Experiments


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       100 THE COMPOSITION OF THE UNIVERSE

       EXPERIMENT 101

       REFERENCES

       INDEX

       ACKNOWLEDGEMENTS

       ABOUT THE AUTHORS

       ABOUT THE PUBLISHER

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      © NASA/Science Photo Library

      Astronaut working on the Hubble Space Telescope (HST) during a routine servicing mission.

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      © Caltech/MIT/Ligo Labs/Science Photo Library

      LIGO gravitational wave detector. Aerial photograph of the Livingston detector site for the Laser Interferometer Gravitational-Wave Observatory (LIGO). LIGO compares measurements between two detector sites 3000 kilometres apart, one near Hanford, Washington, USA, and the other near Livingston, Louisiana, USA. Each site is an L-shaped ultra-high vacuum system, four kilometres long on each side. Laser interferometers are used to look for small changes caused by gravitational waves. LIGO has been operating since 2002, with an advanced upgrade (aLIGO) operating since 2015. On 11 February 2016 it was announced that gravitational waves had been detected by LIGO. The signal was detected on 14 September 2015, and was the result of two black holes colliding.

      Science is nothing without experiments. As the Nobel Prize-winning physicist Richard Feynman said: ‘In general, we look for a new law by the following process: First we guess it; then we compute the consequences of the guess to see what would be implied if this law that we guessed is right; then we compare the result of the computation to nature, with experiment or experience [observation of the world], compare it directly with observation, to see if it works. If it disagrees with experiment, it is wrong. In that simple statement is the key to science. It does not make any difference how beautiful your guess is, it does not make any difference how smart you are, who made the guess, or what his name is — if it disagrees with experiment, it is wrong.’1

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      © Physics Today Collection/American Institute of Physics/Science Photo Library

      American physicist Richard Feynman (1918–1988).

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      © National Library of Medicine/Science Photo Library

      William Gilbert (1544–1603), English physician and physicist. In 1600 Gilbert published De Magnete (Concerning Magnetism), a pioneering study in magnetism, which contained the first description of the scientific method, and greatly influenced Galileo.

      In other words, if it disagrees with experiment, it is wrong. The reference to ‘great money expense’ also strikes a chord in the modern age, when scientific advances seem to require the construction of expensive instruments, such as the Large Hadron Collider at CERN, probing the structure of matter on the smallest scale, or the orbiting automatic observatories that reveal the details of the Big Bang in which the Universe was born. This highlights the other key to the relatively late development of science. It required (and requires) technology. There is, in fact, a synergy between science and technology, with each feeding off the other. Around the time that Gilbert was writing, lenses developed for spectacles were adapted to make telescopes, used to study, among other things, the heavens. This encouraged the development of better lenses, which benefited, among other things, people with poor eyesight.

      A more dramatic example comes from the nineteenth century. Steam engines were initially developed largely by trial and error. The existence of steam engines inspired scientists to investigate what was going on inside them, often out of curiosity rather than any deliberate intention to design a better steam engine. But as the science of thermodynamics developed, inevitably this fed back into the design of more efficient engines. However, the most striking example of the importance of technology for the advancement of science is one that is far less obvious and surprises many people at first sight. It is the vacuum pump, in its many guises down the ages. Without efficient vacuum pumps, it would have been impossible to study the behaviour of ‘cathode rays’ in evacuated glass tubes in the nineteenth century, or to discover that these ‘rays’ are actually streams of particles – electrons – broken off from the supposedly unbreakable atom. And coming right up to date, the beam pipes in the Large Hadron Collider form the biggest vacuum system in the world, within which the vacuum is more perfect than the vacuum of ‘empty’ space. Without vacuum pumps, we would not know that the Higgs particle (see here) exists; in fact, we would not have known enough about the subatomic world to even speculate that such an entity might exist.

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      © Science Source/Science Photo Library

      Robert Hooke’s hand-crafted microscope.

      But we know that atoms and even subatomic particles exist, in a much more fundamental way than the Ancient Greek philosophers who speculated about such things, because we have been able (and, equally significantly, we have been willing) to carry out experiments to test our ideas. The ‘guesses’ that Feynman refers to are more properly referred to as hypotheses. Scientists look at the world around them, and make hypotheses (guesses)