Why Icebergs Float: Exploring Science in Everyday Life
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About this ebook
From paintings and food to illness and icebergs, science is happening everywhere. Rather than follow the path of a syllabus or textbook, Andrew Morris takes examples from the science we see every day and uses them as entry points to explain a number of fundamental scientific concepts – from understanding colour to the nature of hormones – in ways that anyone can grasp. While each chapter offers a separate story, they are linked together by their fascinating relevance to our daily lives.
The topics explored in each chapter are based on hundreds of discussions the author has led with adult science learners over many years – people who came from all walks of life and had no scientific training, but had developed a burning curiosity to understand the world around them. This book encourages us to reflect on our own relationship with science and serves as an important reminder of why we should continue learning as adults.
Praise for Why Icebergs Float
'Asking questions is an important scientific skill and sometimes we can only understand something when we can find the language to ask the right questions; books like this can be really helpful in this respect....This book is one of UCL’s open access books. This means that it can be downloaded as a free PDF from the UCL Press website. The commitment to making scientific works such as this freely available is very welcome. This book is very accessible and deserves to reach a wide audience.'
School Science Review
'Morris says in the prologue: ‘If you come away from this book with a greater interest in science and enhanced confidence about tackling it, the book will have served its purpose.’ So, don’t be afraid of science and give Why Icebergs Float a chance. You will absolutely enjoy it.'
Chemistry World
'[Why Icebergs Float] draws on experiences and first-person narratives of adult learners who – out of genuine curiosity or embarrassment at their levels of scientific ignorance – have sought to catch-up on lost school science and get a better understanding of their surroundings as a result.'
Education Journal
'The approach illustrates beautifully the influence of language on understanding. The author makes clear how common language can be misleading when scientists have used everyday words but given them very specific meanings.’
Physics Education
‘I had fun reading this book. If it makes science more accessible to more people, that’s surely a good thing.‘Speculative Stories
Andrew Morris
Andrew Morris has been running science discussion groups since 2002. Originally a science teacher, he studied physics at University College London and completed a doctorate in molecular biophysics at the University of Leeds. His 2015 book is titled Getting to Grips with Science: A Fresh Approach for the Curious.
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Why Icebergs Float - Andrew Morris
Introduction
This book is not about a particular area of science – genetics, gravity or chemical reactions, for example. It is about ideas that interest ordinary people, drawn from any area of science. The ideas come in response to questions people ask about the world around them. These questions rarely lead neatly into the traditional pattern of school subjects – physics, chemistry and biology – so the scientific material is presented in a quite different way. As there is no formal syllabus, a query about depression, for example, may lead into aspects of biochemistry and neuroscience as well as psychology and pharmacology. A structured scientific discipline helps you to learn a subject systematically by moving in carefully planned steps through an argument, but many people find the topics remote from everyday experience. This book takes the opposite tack: it focuses on issues of relevance to everyday life, sacrificing the orderly build-up of knowledge within one subject.
As a result each chapter explores a quite distinct area of science – from hormone action to tidal flows. Each is a story in itself and can be read at any point; later ones do not depend on points made in earlier ones. However, the stories have been arranged so that the content of one links to that of the next. The format of each chapter is similar, first presenting questions arising from the world around and then some of the scientific ideas that flow from them. As further questions arise the pattern repeats, forming a type of dialogue that blends science with everyday observations.
You might well wonder how the kind of questions and observations that interest ordinary people can possibly be captured by an author trained in the scientific disciplines; how can an authentic dialogue be constructed? This is a fair point and an important one. It is only too easy for a trained professional to forget how a subject looks to someone new to it: the terminology, the assumptions, the strangeness of unfamiliar ideas. In this book all the material is derived from actual discussions that have taken place with groups of people with scarcely any background in science. They meet every month in the informal setting of a wine bar to raise questions and make comments on things they have noticed that caught their interest. No topic is out of bounds and no rules constrain the path the discussion might take. The aim is to reach into scientific concepts only after questions have been raised spontaneously and people’s initial thoughts and conceptualisations expressed.
The format of the stories that follow reflects this approach. Points raised by participants in discussion groups form the starting point and their thoughts and ideas are expressed first, mainly using verbatim quotes. Once the underlying scientific theme has been identified, explanation follows which itself leads into a further round of questions and observations. As the initial query is satisfied new questions, more numerous than the original ones, proliferate as fascination with the topic takes hold. At some point, after several iterations, a truce has to be called to avoid mental collapse! The stories, like the discussions upon which they are based, are brought to an end, often leaving further questions hanging in the air. Such is the fate of curiosity-driven discussions.
The approach, designed specifically for non-specialist readers, is intended to make learning more effective as well as to attract and motivate. Research on learning suggests that before trying to teach a new concept it is important to bring out the prior ways of thinking to which a person has become accustomed. For example, when children are first taught that the Earth they live on is round it conflicts with their prior understanding. As a result they are liable to feel uncomfortable and may reject the unfamiliar idea, inwardly at least. The concept of a flat Earth needs to be discussed first, to reveal the strengths and weaknesses of their deeply held conviction before persuading them to take on the strange new one with all its apparent absurdities.
Of course there are many other challenges in trying to learn about science in addition to understandable resistance to strange new ideas. It is known from research about science education that the way in which language is used can be a barrier. Unfamiliar terms and complicated, formal modes of expression may appear off-putting. If you find yourself struggling with a complicated new concept it may be best to read through it lightly, overlooking things you don’t completely understand, or even to skip it and then continue where the going is easier. You can then come back to the complex section later on and see if it is more comprehensible second time round. In this book efforts have been made to use plain English; much of the text is drawn directly from the words used by people in discussion groups upon which it is based. Mathematics is not used; the emphasis throughout is on developing conceptual understanding, often through use of metaphor and visual images.
As a consequence it is important to make clear that this book does not convey a complete sense of what science is. Like any great endeavour science has many aspects: practical, mathematical, historical, as well as conceptual. By missing out on mathematical argument this book is unable to convey the true elegance of some theories. In the same way it does not give a sense of how the ideas it outlines were arrived at. It misses out on the nature of the experiments and observations that led up to the concepts we have inherited. Nor does it convey much of the human story that lies behind the historical development of scientific understanding. Fortunately, there is today a huge offering of excellent books that do cover these aspects. It is also true that the chapters do not convey a complete introduction to a given topic – they do not intend to. By following the path of actual discussions led by lay people, some aspects that may seem important to a scientist will be missed. For readers who wish to follow up with a fuller account of a topic, good, readable books are available in many areas of popular science (see Further Resources section).
With these reservations in mind, it may be helpful to set out reasonable expectations of what you, the reader, may get from the book. Its humble aim is to help you put science on an equal footing with other subjects that you are likely to have encountered in your adult life. Simply by being citizens we engage to some extent with topics in political science: we learn about voting and parliaments, governments and laws. Through our workplaces and newspapers we get some insight into economics – the way income and taxation, investment and borrowing work. Literature enters our lives through drama and novels, sociology through our engagement in communities and families, history through books and local interest groups. By these means we pick up concepts – about child-rearing, political parties, environmental issues, for example – and gain a certain amount of subject knowledge simply through living our lives. Yet this happens less easily and less often in the realm of science. Many people feel at a loss when it comes to explaining how electricity gets to their kettle or why leaves turn yellow and fall from the trees.
It is reasonable to expect that this book will help begin to set this right. People in discussion groups report on how the experience builds their confidence about scientific ideas so they feel more inclined to respond to scientific articles and broadcasts and to engage more freely in discussions. Some are surprised to see how they have sometimes been deceived by the bluster of others who purport to understand science. A few choice questions can soon remedy this. It is not likely that the book will fill you with factual knowledge that you will retain indefinitely. Life is not like that, nor is factual recall the ultimate reward of science. Most of the facts revealed in discussion groups are found after the event by searching in books and websites. The important gain from talking and reading about scientific ideas is a slowly developing repertoire of major concepts that gradually connect up. Rather like discovering a new city, you get to know a few specific areas first then gradually see how they are related.
Fundamental concepts such as the structure of molecules, the nature of gravity or the make-up of cells emerge from particular inquiries into ice or tides or ’flu. Once grasped they serve ever after in explaining a host of further phenomena – medical conditions, the strength of glues or the origin of the universe. Of course in a single book only a few of the fascinating areas of science can be opened up. This one introduces some, but leaves so many others untouched – genes and evolution, earthquakes and tectonics and the origins of Homo sapiens, for example. Fortunately the records of discussion upon which this book is based cover a vast range of scientific topics. With some 232 records available at the time of writing (and still growing), there’s plenty of scope for many more chapters to come.
To bring the stories to life, actual words used by people in discussion groups are retained wherever possible. The names given to the characters are fictitious, and occasionally the contributions of participants have been adapted to make the reading simpler. The characterisation of individuals conveys something of the spirit of discussions and of the nature of the dialogue, but does not represent accurately any particular individual in the groups. Most of the participants are women, and they come from many walks of life. Some work in the media, some in the arts, several in charities, one or two in IT and some in the NHS and other therapeutic services. Their ages range from 25 to 75 and they come from various cultural and ethnic backgrounds. By definition they all place a high value on education in adult life and have gone out of their way to pursue it in an area they mostly missed out on earlier in their lives. I am grateful to them for all they have contributed to this book, and hope their voices help you and others enjoy the exploration of unfamiliar scientific ideas.
1
Foods We Love and Hate
Sally works in the lively office of a children’s charity in central London. She had been chatting with her colleagues over lunch one day about which foods they liked and disliked. Her own pet hate was mushrooms, something she had always disliked, especially the musty old smell of the things. That evening Sally was due to meet up with her fellow enthusiasts in a science discussion group at a local wine bar. She decided to bring up this topic to see what others in the group felt and to discuss the underlying science together.
A fascinating exchange of experiences and thoughts ensued, leading to an exploration of the varied substances that flavour our food and the ways in which our bodies respond to them. Everyone seemed to have something to say about their food preferences. Dominic, a retired journalist, had disliked avocados until he was about 30, at which point he had unexpectedly developed a taste for them. Amy, a young woman in her mid-20s, had noticed that some foods you come to like as an adult, such as olives, may seem horribly bitter when you are young. Helen, who had had a lifelong aversion to cheese, had a personal theory about how this had come about: unhappy memories of having the ghastly stuff forced on her when she was a child.
This brief skirmish with likes and dislikes threw up some interesting ideas about how these preferences might have arisen – possible patterns and causes. Growing older seemed to play a part and this chimes with recent research. A lot of people do appear to become less fussy as they get older, perhaps because it can be socially awkward to reject certain foods as an adult. Another theory is that we tend to be cautious about foods that are new to us and, of course, for a young child many things are new. Talking of young children prompted Amy to comment on how unrestrained children tend to be in their demands for sweet things, often pestering their parents to the point of exhaustion for unhealthy kinds of snacks and fizzy drinks. Her suggestion was that perhaps there may have been some kind of evolutionary explanation for this. Hadn’t she heard that it was in the interests of early humans to feast on sweet things as soon as they encountered them because there was no certainty about when they might next find any? Didn’t sweet berries and fruits provide a highly valuable source of sugar in a time when it was scarce?
Evolution
Sugar is indeed one of the foods that yield plentiful energy when digested. In the time before agriculture, when chance played a major part in what foods you might stumble upon, sweet things would certainly have been very beneficial, though much scarcer than today. Darwin’s idea of evolution through natural selection means that individuals best fitted to their environment would become more and more numerous in the population – not through any design intention, but simply by surviving longer and reproducing more. The high energy content of sweet foods may well have conferred an evolutionary advantage to those who sought them out.
So attraction to sweet things would have developed over millennia as a common human trait – a perfectly reasonable and successful feeding strategy, at a time when sugar remained in relatively short supply. For better or worse, the situation today is quite different. Sugar supplies are plentiful in highly processed forms, but we continue to express these ancient preferences, although they are no longer so advantageous for our survival – quite the reverse in many parts of the world. Evolution proceeds at a much slower pace than human cultural development. Celia summarised our modern predicament succinctly, based no doubt on personal experience: ‘Isn’t it odd,’ she observed, ‘that however full you feel after a hearty roast, you always have room for something sweet?’
Sarah wondered whether evolution might have played another role in the development of taste: signalling to the brain which kinds of food to avoid. As Amy had noted earlier, olives are not too popular with children; the love of their slightly bitter taste seems to develop later in life. Could this tendency also have evolved because bitter fruits may also be poisonous fruits? Has our sensitivity to what we perceive as bitterness evolved as a protection against accidentally eating poisons? Are poisons usually bitter in fact?
Bitterness
Fortunately there are places where tastes and smell are investigated scientifically. A study at one of them, the Monell Centre in Philadelphia, has investigated a long-held assumption among scientists that a bitter taste evolved as a defence mechanism to detect potentially harmful toxins in plants. Subjects in the study were genetically tested and then asked to rate various vegetables for taste. The evidence suggests that we are able to detect bitter toxins with our sense of taste, and genetic differences in our bitter taste receptors affect how we recognise foods containing a particular set of toxins.
This evidence bears out some of the speculative thoughts of the group: that the bitter sensation we associate with olives or broccoli appears to have developed over evolutionary time to help protect us from potential toxins. It also throws light on why individuals respond differently to a particular food, by linking taste to genetic differences. But as so often when we encounter scientific evidence, satisfying one inquiry, far from closing down a subject, seems to provoke even more questioning. If the molecules in our taste buds have evolved to detect molecules from toxic plants, what is it that gives us the actual sensation of bitterness? What is it that translates the presence of some particular chemicals in the taste buds into a subjective feeling – something that, at least when we are young, tends to turn us off such foods?
The chemistry of taste
With talk of bitterness and taste buds, the conversation turns naturally to what is actually happening in the mouth when we taste something. The idea that four principle tastes are associated with different regions of the tongue seems to be one of those pieces of information that actually stick from biology lessons at school, however long ago: salt, sweet, sour and bitter. Dominic, whose journalistic career had taken him around the world, raised the question of a fifth taste, umami. Well known in Chinese cuisine, this is associated with monosodium glutamate, an additive used to boost the meaty flavour in dishes. It occurs naturally in a wide range of foods that contain glutamate, including fish, cured meat, mushrooms and breast milk.
What those around the table did not know is what is happening chemically when each of the tastes is being experienced. It turns out that each of the five basic tastes is associated with an entirely distinct category of substance in the food. Different kinds of chemical trigger off different kinds of receptor molecule in the taste buds (explained later in the chapter). These receptors in turn send different kinds of signal to the brain. No prizes for guessing that it is sugar molecules that trigger the sensation of sweetness. No great surprise either to learn that sourness is felt when acids are detected in food. In fact the very word ‘acid’ derives from the Latin acidus, meaning sour.
More of a revelation is that the sensation of saltiness is simply the result of metal ions in food and drink hitting the palate. Ions are individual atoms, rather than the more complex molecules, which have gained a slight electric charge by losing or acquiring extra electrons in their internal structure (every electron carries a small negative charge). It is normal for the atoms in salts such as sodium chloride, for example, to separate out as ions in this way as they dissolve in water. Typical ions in food are sodium, potassium and iodine – all vital for the functioning of our nerves and other systems.
The bitter taste found in wine, beer and many vegetables corresponds to a class of chemicals called alkaloids which are present in many foods. Caffeine, nicotine, strychnine and morphine are examples of well-known alkaloids. It seems that these substances evolved as toxins in many plants precisely because they deterred herbivorous animals from eating them. Strangely this didn’t seem to put us humans off coffee for long!
Finally we turn to umami, formally recognised in 1985 as a fifth distinct basic taste after it was found to be associated with a distinct receptor in the mouth. Umami is simply the taste buds’ response to the naturally occurring substance glutamate, found in a very wide range of foods. It is frequently described as the ‘meatiness’ taste.
The psychology of taste
This introduction to the chemical basis of taste seemed interesting to people in the discussion group, if a little daunting. As often with chemistry, the number of unfamiliar terms can be off-putting. How do you get a feeling for a word such as ‘alkaloid’ if it has played no part in your life and doesn’t connect with anything you know? The discussion took off from the basic chemistry of food and led to a more specific question: what is it in the tongue that actually picks up these various chemical sensations – the acids, the metal ions, the sugars? What are these so-called ‘taste buds’ we talk so loosely about?
Before a foray into the biology of the tongue could even begin, however, Helen – never one to let things hang – interrupted to bring us back to her earlier point about childhood experiences. ‘Surely psychology has a crucial part to play in all this?’ she rightly asked, reminding the group of her enduring memory of having been made to eat cheese as a youngster. Talk of childhood memories inspired others to chip in with recollections of a favourite children’s story book. Hadn’t Babar the Elephant sadly died after eating a poisonous mushroom? An interesting point for Dominic, who had spent much of his life abroad, was that the author of the Babar books was French. Given that hunting for wild fungi was a normal part of life in rural France, he wondered aloud whether the books had a hidden purpose: to warn children of the dangers of eating mushrooms indiscriminately? Talk of early years’ reading reminded Amy of her lifelong antipathy to Turkish Delight, with its strange colours and wobbly texture. Could this have been linked subconsciously to its role in The Lion, the Witch and the Wardrobe, where the sweet is used maliciously to entice a young boy?
Our emotional responses to food do not seem to be limited to our memories of experiences in childhood. As the Turkish Delight discussion suggests, maybe other perceptions play a part too: the colour of food for example. As Helen realised, you don’t see many blue foods – apart from a few kinds of berry. In fact she recalled sitting in a restaurant once under a blue light and feeling distinctly uneasy about tucking into her rice dish. Could it be that the colour blue is associated with mould, which is sometimes poisonous, she speculated?
This turn of discussion about the psychological aspects of food preferences led Julie to raise an even bigger question, particularly in relation to sugar: ‘What about addiction? Is this a psychological matter or does biology play a part?’ This is, as you might expect, an active area of neuroscience research. The Oregon Research Institute has used MRI scanning to conclude that sugar stimulates the same brain regions as drugs such as cocaine. Furthermore, heavy users of sugar develop tolerance (needing more and more to feel the same effect), which is a symptom of substance dependence.
It looks as though our current understanding of addiction is based on both psychological and biological research. Certain studies suggest that addiction is genetic, but environmental factors, such as being brought up by someone with an addiction, are also thought to increase the risk. As we find so often in trying to understand the science behind the way we behave, the nature versus nurture argument fails to get us very far. Our upbringing and other environmental factors play a part, but so do biological factors, including those we inherit. The balance will of course vary from individual to individual, as you might expect given the marked variation we see in our responses to sugar (or any other ingredient) in our diet.
Diabetes and hormones
Talk of sugar stirred Dominic to explain something of the nature of diabetes, a condition he had acquired later in life. In this type of diabetes (known as Type II) the level of glucose (a kind of sugar) in your blood is no longer properly regulated as a result of failings in your body’s insulin system. Insulin is a naturally occurring substance manufactured in the pancreas, an organ 15 cm long that lies close to the stomach. It is a large molecule, one of many hormones in our bodies, whose particular job is to regulate the amount of glucose circulating in the blood.
Sugars are a class of substances that include fructose, lactose and sucrose (table sugar) as well as glucose. In the bonds that bind together the atoms in sugar molecules lies the energy that we need to keep our bodies ticking over. Too little glucose and our metabolism simply switches off: too much and damage ensues in organs such as the kidneys or retina, and to the cardiovascular system. For people such as Dominic, dealing with Type II diabetes means regulating the amount of sugar in their diet and taking other practical measures such as increasing physical exercise and losing weight. The other kind of diabetes, Type I, is the result of the cells that produce insulin in the pancreas actually being destroyed in an autoimmune response – that is, the body actually attacks itself. The ultimate cause of this is not known. People living