Which paragraph contains the following information?
Seven questions per unit. Identify the type of information described, then scan the passage for it. You may use the same paragraph letter more than once. After checking, the passage highlights exactly where each answer was.
Choose a unit above to begin
Each unit has 7 questions about the same passage used in your Headings, Multiple Choice and T/F/NG exercises.
The Atlantic Greyhounds: the age of the ocean liner
An account of the rise, fall and afterlife of the great transatlantic passenger ships
The Atlantic Greyhounds: the age of the ocean liner
An account of the rise, fall and afterlife of the great transatlantic passenger ships
For roughly seventy years, from the 1890s to the late 1950s, the great passenger liners of the North Atlantic were the largest and most complex moving objects ever built. Historians continue to study this period closely, and with good reason. The story of the liners is also the story of mass migration to the Americas, of rapid advances in engineering, and of intense rivalry between nations, for whom a record-breaking ship was a floating symbol of prestige. Examining how the shipping lines rose, competed and eventually collapsed offers lessons that reach far beyond maritime history, touching on economics, technology and social change.
By the early twentieth century, the crossing between Europe and New York was effectively in the hands of a small group of companies: Cunard and White Star in Britain, HAPAG and North German Lloyd in Germany, and the French Line. These firms did not merely operate ships; they controlled almost every stage of the journey. They owned the piers, employed networks of ticket agents deep in the European countryside, ran the trains that delivered emigrants to the ports, and even built hostels where passengers waited for departure. A traveller could buy a single ticket in a small Polish town and remain inside one company’s system until stepping ashore in Manhattan. Newcomers found it nearly impossible to break into a market that was sealed at every point.
With several giants offering the same basic service, each line worked hard to appear unlike its rivals. Cunard promoted speed, pouring money into engines so that its ships could claim the Blue Riband, the unofficial trophy for the fastest crossing. White Star deliberately abandoned the speed race and sold comfort instead: wider cabins, grand staircases and restaurants copied from Paris hotels. The French Line marketed cuisine and elegance, boasting that its dining rooms were the finest French restaurants in the world, while the Germans emphasised size and technical ambition. In their advertising posters, each company cultivated a distinct personality that passengers recognised instantly.
The industry also proved remarkably quick to absorb new inventions. Sail gave way to coal-fired steam, coal to oil, and piston engines to steam turbines, each change cutting crossing times and running costs. When wireless telegraphy appeared, liners were among the first commercial adopters, allowing passengers to send messages in mid-ocean and captains to receive ice warnings. In the 1930s, ships such as the Normandie incorporated radically new hull designs tested in laboratory tanks, while air conditioning, telephones in cabins and on-board cinemas appeared within a few years of their invention on land. Far from resisting change, the great lines treated every technological novelty as a competitive weapon.
The collapse, when it came, arrived from two directions at once. In October 1958, the first jet airliners began scheduled Atlantic services, crossing in seven hours instead of five days; within a single year, more people were flying the Atlantic than sailing it. At the same moment, the liners’ own costs were rising sharply. Fuel prices climbed, and the large crews required to staff floating hotels became increasingly expensive as wages rose in the post-war economy. Squeezed between vanishing passengers and growing expenses, even the most famous companies could not survive on the old model, and one by one the great ships were withdrawn, scrapped or laid up during the 1960s.
Yet the ocean liner did not so much die as change its purpose. Shipping lines discovered that vessels which could no longer compete as transport could prosper as destinations in themselves, sailing warm-water circuits where the voyage, not the arrival, was the product. The modern cruise industry, now carrying tens of millions of passengers a year, grew directly out of this reinvention, and it borrowed the liners’ traditions wholesale, from captains’ dinners to deck games. A handful of the original ships even survive: the Queen Mary, permanently moored in California as a hotel, still welcomes more visitors each year than she ever carried across the Atlantic.
The rise of the coffeehouse
How a single drink reshaped conversation, commerce and public life
The rise of the coffeehouse
How a single drink reshaped conversation, commerce and public life
Coffee drinking as we know it began not in Europe but in the highlands of Ethiopia and the ports of Yemen. By the fifteenth century, Sufi monks in southern Arabia were brewing the roasted bean to stay awake during long night-time prayers, and it is from these religious communities that the habit spread outward. Traders carried the beans north to Mecca and Cairo, where the first public places to drink coffee appeared. The drink's earliest home, then, lay firmly in the Muslim world of the Red Sea, long before it reached the West.
From these Arabian beginnings, coffee travelled with astonishing speed along the trade routes of three continents. Ottoman merchants brought it to Istanbul, Venetian ships carried it into Italy, and within a few decades the beans had reached London, Paris and Vienna. Dutch and later French traders established plantations in their tropical colonies to feed the growing demand. In little more than a hundred years, a drink confined to one corner of Arabia had become a genuinely global commodity.
Wherever coffee arrived, a new kind of public space arrived with it, and the coffeehouse quickly became a centre of ideas. Unlike taverns, these establishments were sober, and for the price of a cup a customer could read newspapers, hear the latest news and join in debate. In London they were nicknamed 'penny universities', because a penny bought entry to conversation as valuable as a lecture. Merchants, writers and scientists gathered in them, and the coffeehouse earned its lasting reputation as a marketplace not just of goods but of thought.
Not everyone welcomed the new institution, and coffee soon attracted determined opposition. Rulers grew nervous about places where citizens gathered freely to exchange opinions, fearing they bred rumour and rebellion. In 1675 the King of England tried to close London's coffeehouses altogether, and similar bans were attempted in Mecca and Istanbul. Religious authorities in several regions also questioned whether the stimulating drink was lawful at all. Coffee, in short, was treated by those in power as a potential threat to public order.
Behind the sociable image of the coffeehouse lay a hard commercial reality, for coffee was above all an object of trade. As European demand soared, colonial powers cleared vast tracts of land in the Caribbean, Brazil and Java to grow it, often relying on forced labour. Fortunes were made and lost on the price of the bean, and whole economies came to depend on a single export crop. The story of coffee is therefore inseparable from the history of global commerce and empire.
In our own time, coffee culture has been transformed once again by the arrival of the international chain. Beginning in the late twentieth century, companies such as Starbucks turned the local cafe into a standardised brand found on high streets worldwide, offering a familiar menu from Seattle to Shanghai. More recently a 'third wave' of small independent roasters has pushed back, treating coffee as a craft product to rival fine wine. The modern coffee shop, whether global chain or artisan bar, remains a flourishing descendant of those first Arabian houses.
Light in the deep: the science of bioluminescence
How living organisms make their own light, and why it matters
Light in the deep: the science of bioluminescence
How living organisms make their own light, and why it matters
Bioluminescence — the production of light by living organisms — is far more widespread in nature than most people imagine. Although fireflies are its most familiar example on land, the overwhelming majority of light-making species live in the ocean, where an estimated three-quarters of animals below a certain depth can glow. From bacteria to fish, the ability has evolved independently dozens of separate times. Rather than a curiosity, then, biological light is one of the most common forms of communication on the planet.
At its heart the phenomenon depends on a simple chemical reaction. A light-emitting molecule, generically called luciferin, reacts with oxygen in the presence of an enzyme known as luciferase, and the energy released escapes as light rather than heat. Because almost none of the energy is wasted warming the surroundings, the glow is often described as 'cold light'. Different organisms use slightly different luciferins, but the underlying process is everywhere the same: a fuel, an enzyme and oxygen combine to produce a cool, efficient light.
For the creatures that possess it, this light serves a remarkable range of purposes. Many deep-sea fish dangle a glowing lure to attract prey towards their jaws, while others release a bright cloud to blind a predator and escape. Some squid match the faint light filtering from above so that no shadow betrays them to hunters below, a trick known as counter-illumination. Fireflies, meanwhile, flash coded patterns to find a mate. Whatever the setting, bioluminescence has been shaped into a versatile tool for survival.
Studying these faint lights in their natural home has always posed severe practical problems. The deep ocean is utterly dark, crushingly high in pressure and difficult to reach, so early researchers could do little more than examine dead specimens hauled to the surface. The bright lights and clumsy movements of traditional submersibles frightened animals away before they could be observed. Only with the recent development of quiet, low-light cameras and remotely operated vehicles have scientists begun to watch these organisms behaving naturally. Technology, in other words, long stood in the way of understanding.
That same natural chemistry has proved unexpectedly useful in the laboratory. Scientists have learned to insert the genes responsible for light production into other cells, so that a cell glows only when a particular gene is active. This turns bioluminescence into a kind of switch that reveals otherwise invisible processes, from the spread of cancer cells to the activity of nerves. Medical researchers now rely on the trick to track disease in living tissue. Borrowed from the deep sea, biological light has become a powerful instrument of modern science.
Yet the natural spectacle that inspired all this study may now be under threat. Along many coastlines, artificial lighting from cities and ships is flooding the night with a glow bright enough to drown out the faint signals on which luminous animals depend. Fireflies, whose numbers are falling in many regions, may struggle to see one another's flashes, and disoriented marine larvae can lose their way. Conservationists warn that unless light pollution is controlled, one of the planet's oldest forms of communication could fall silent.
The story of paper
From an imperial secret to the material that carried civilisation
The story of paper
From an imperial secret to the material that carried civilisation
Paper as we know it was invented in China around two thousand years ago. Tradition credits a court official named Cai Lun, who in about 105 CE presented a method of soaking plant fibres, beating them into pulp and pressing the mixture into thin sheets. Earlier writing surfaces such as bamboo strips and silk were either heavy or costly, and the new material was neither. From a single workshop in the Han court, paper set out on a journey that would eventually reach every corner of the world.
For centuries the technique remained a jealously guarded secret. The Chinese state understood the value of its invention and forbade the export of the knowledge, so that for some seven hundred years papermaking stayed within China's borders. Only in 751 CE, when Chinese prisoners captured after a battle in Central Asia were said to have revealed the method, did the craft escape westward. From Samarkand it passed to Baghdad, then across North Africa and into Spain. What had been an imperial monopoly slowly became a shared human technology.
The arrival of paper in Europe transformed the way knowledge was stored and shared. Before it, books were written on parchment made from animal skin, so costly that a single Bible could require the hides of an entire herd. Paper was far cheaper, and it made the written word available to a far wider public. When Gutenberg's printing press appeared in the fifteenth century, it was paper, not parchment, that fed it. The cheap sheet, in short, was the foundation on which mass literacy was built.
Making paper by hand, however, was slow and laborious work. Each sheet had to be lifted individually from a vat of pulp on a wire frame, pressed and hung to dry, and the raw material — chiefly old linen rags — was often in short supply. A skilled crew could produce only a few thousand sheets a day, nowhere near enough to satisfy a printing industry that was growing explosively. The craft methods that had served for centuries were becoming a bottleneck.
The solution came with mechanisation. In 1799 a French inventor designed a machine that produced paper in a continuous roll rather than as separate sheets, and improved versions were soon built in England. Output rose from thousands of sheets a day to miles of paper an hour. When manufacturers later learned to make pulp from wood rather than scarce rags, the last limit on supply disappeared. Industrial machinery turned paper from a precious commodity into one of the cheapest materials on earth.
Today paper faces a rival it never expected: the screen. Many predicted that computers would bring about the 'paperless office' and make the printed page obsolete. In practice the picture is more complicated. Office paper use has indeed begun to fall as documents move online, yet global demand for packaging and tissue continues to climb, driven by online shopping and rising populations. Paper has not vanished so much as changed its role, proving as adaptable in the digital age as it was two thousand years ago.
Cities in bloom: the rise of the green roof
Why builders are turning bare rooftops into living landscapes
Cities in bloom: the rise of the green roof
Why builders are turning bare rooftops into living landscapes
Covering a building's roof with living plants is a far older idea than it might appear. The famous Hanging Gardens of ancient Babylon were an early vision of greenery raised above the ground, and for centuries the turf roofs of Scandinavia kept farmhouses warm through bitter winters. What is new is not the concept but its scale and purpose. Today the green roof has been rediscovered as a deliberate tool of modern city planning, rather than a folk tradition or a royal luxury.
The most immediate benefit of a planted roof is the way it manages rainwater. In a conventional city, rain runs straight off hard surfaces into drains, overwhelming sewers and causing floods during heavy storms. A green roof, by contrast, acts like a sponge: its soil and plants soak up a large share of the rainfall and release it slowly, easing the pressure on drainage systems. A single planted roof can absorb well over half the water that lands on it. For flood-prone cities, this alone can justify the investment.
Green roofs also help to cool the overheated city. Dense urban areas suffer from what scientists call the 'heat island effect', in which concrete and asphalt absorb the sun's warmth and release it long after dark, raising temperatures several degrees above the surrounding countryside. Plants counter this by shading surfaces and by releasing moisture as they transpire, a natural form of air conditioning. Buildings beneath a green roof stay cooler in summer and need less energy for cooling. In a warming world, that cooling power is increasingly valuable.
Beyond water and temperature, these roofs offer a refuge for wildlife in places where nature has been squeezed out. A patch of meadow high above the street can support bees, butterflies and ground-nesting birds, creating stepping-stones of habitat across an otherwise hostile landscape of glass and stone. Some famous examples, such as the roof of a car factory in Michigan, have attracted rare insects thought to have vanished from the region. The rooftop, it turns out, can become a small but genuine wilderness.
For all these advantages, green roofs are not without their drawbacks. Living roofs are heavier than bare ones, so buildings must be strong enough to bear the extra load of wet soil, which adds to construction costs. They require waterproof membranes and regular maintenance, and a poorly designed roof can leak or dry out. The initial expense is significantly higher than that of a conventional roof. These practical obstacles help explain why adoption has been slower than enthusiasts once hoped.
Increasingly, however, governments are deciding that the public benefits are worth encouraging. Cities from Toronto to Copenhagen now require green roofs on many new buildings by law, while others offer grants or reductions in local taxes to those who install them. Supporters argue that the wider savings — in flood damage avoided, energy conserved and health improved — far outweigh the private cost. Through regulation and reward alike, the living roof is steadily being written into the rules of the twenty-first-century city.
The Silk Road: a network that shaped the world
Trade routes that carried goods, ideas and disease across a continent
The Silk Road: a network that shaped the world
Trade routes that carried goods, ideas and disease across a continent
The Silk Road was never a single road at all. The name, coined by a German geographer only in the nineteenth century, describes a shifting web of overland and sea routes that linked China with Central Asia, India, the Middle East and ultimately Europe. Goods rarely travelled the whole distance in one journey; instead they passed from merchant to merchant across thousands of miles. To picture a single highway is therefore misleading: the Silk Road is better understood as a vast and changing network.
Silk gave the network its name, but a startling variety of goods moved along it. From China came not only silk but paper, gunpowder and porcelain; from the West travelled gold, glassware, wool and horses. Spices from India, precious stones from Central Asia and furs from the northern forests all found their way into the caravans. Because the distances were so great and the risks so high, only luxuries valuable enough to justify the journey were usually carried. The Silk Road, in short, was a highway of high-value trade.
Yet the most important cargoes were not objects but ideas. Along the same routes travelled religions, technologies and knowledge that reshaped whole civilisations. Buddhism spread from India into China along the caravan tracks; papermaking and later printing moved westward; astronomical and medical learning passed in every direction. Merchants and missionaries carried these ideas as surely as they carried silk. The lasting legacy of the network, many historians argue, lay less in its goods than in this exchange of thought.
The network could not have functioned without the great cities that grew up along it. Oasis towns such as Samarkand, Bukhara and Kashgar became wealthy hubs where caravans rested, goods were traded and travellers found lodging. In these cosmopolitan marketplaces, people of many languages and faiths mingled, and the towns grew rich enough to build magnificent mosques, libraries and observatories. Far from being mere stopping points, these cities were the beating heart of the whole system.
Not everything that travelled the Silk Road was welcome. The same routes that carried silk and ideas also carried disease. In the fourteenth century, the plague known as the Black Death is thought to have moved westward along these trade paths, spreading from Central Asia to the Middle East and Europe and killing perhaps a third of Europe's population. The very connections that had enriched the world also left it dangerously exposed. Trade and contagion, it turned out, travelled together.
By the sixteenth century the ancient overland routes were falling into decline. As European sailors opened direct sea passages to Asia, goods could be carried by ship more cheaply and safely than by long desert caravans, and the great inland cities lost their trade. The land routes never entirely disappeared, but their golden age was over. In recent years, however, talk of a 'new Silk Road' of railways and pipelines has revived interest in these old connections between East and West.
Why we sleep
New science on a third of our lives that was long taken for granted
Why we sleep
New science on a third of our lives that was long taken for granted
For most of history, sleep was regarded as little more than a nightly pause, an empty stretch of time when the body simply shut down. Scientists now know that nothing could be further from the truth. Far from being idle, the sleeping brain is intensely active, cycling through carefully ordered stages and carrying out tasks it cannot perform while we are awake. Sleep, in other words, is not the absence of activity but a busy and essential process in its own right.
A night's sleep is built from repeating cycles, each divided into distinct stages. Over roughly ninety minutes the brain descends from light sleep into deep, slow-wave sleep and then rises into a curious phase called REM, in which the eyes dart about and most dreaming occurs. This sequence repeats four or five times before morning, with deep sleep dominating early in the night and REM later on. Understanding these ordered stages is the foundation of all modern sleep science.
One of the clearest functions of sleep is to strengthen memory. During the day the brain gathers a flood of new information, but it is chiefly at night that this material is sorted, stabilised and filed away for the long term. Experiments consistently show that people who sleep after learning a task remember it far better than those kept awake. Deep sleep in particular seems to move fresh memories into more permanent storage. A good night's rest, it appears, is when learning is truly secured.
Sleep does more than tidy the mind; it also cleans the brain physically. Researchers have discovered that during deep sleep the spaces between brain cells widen, allowing fluid to wash through and flush out waste products that build up during waking hours. Among these wastes are proteins linked to Alzheimer's disease. This nightly cleaning may help explain why chronic sleep loss is associated with declining brain health. The sleeping brain, it seems, runs its own overnight maintenance.
Given all this, it is troubling that people in modern societies sleep less than they once did. Artificial light, shift work and glowing screens have pushed bedtimes later and shortened the hours of rest, so that many adults now run on far less sleep than their bodies need. The blue light of phones is especially disruptive, tricking the brain into thinking it is still daytime. Widespread sleep deprivation has quietly become one of the health problems of the age.
The consequences of losing sleep reach into almost every corner of health. Sustained sleep loss has been linked to weakened immunity, weight gain, heart disease and impaired judgement, and drowsy driving causes thousands of accidents each year. Yet the message from researchers is ultimately hopeful: unlike many risk factors, poor sleep can often be corrected. By treating rest as a priority rather than a luxury, most people can reclaim its many benefits.
Drawing the world: a short history of maps
How human beings learned to picture the places they could not see
Drawing the world: a short history of maps
How human beings learned to picture the places they could not see
The urge to map the world is almost as old as humanity itself. Long before writing, people scratched simple charts of rivers, hunting grounds and the night sky onto bone, rock and clay. The oldest surviving maps, pressed into Babylonian tablets thousands of years ago, show fields and canals in careful detail. From the very beginning, then, the map was one of the basic tools with which human beings tried to make sense of their surroundings.
Early maps, however, were as much about belief as about geography. Medieval European maps often placed Jerusalem at the centre of the world and filled the unknown edges with monsters and paradise, reflecting religious ideas rather than measured distances. Chinese and Islamic mapmakers produced their own richly symbolic images of the world. For these societies a map was not merely a practical guide but a statement about the order of creation. Accuracy, as we understand it, was not always the point.
Everything changed with the great voyages of exploration. As European ships ventured across unknown oceans from the fifteenth century onwards, sailors brought home records of coastlines never before charted, and mapmakers scrambled to fit the new discoveries onto the page. The map of the world was redrawn again and again within a few generations. Exploration, in short, turned mapmaking from a settled art into a rapidly changing science.
This new demand for accuracy forced mapmakers to confront a deep problem: the earth is round, but a map is flat. Squeezing the curved surface of a globe onto a flat sheet inevitably distorts something — either the shape of the land, its size or the distances between places. In 1569 Gerardus Mercator devised a famous solution that kept directions true for navigation, though it made regions near the poles look far larger than they really are. No flat map, it turned out, could ever be perfectly faithful to the round world.
For centuries maps were also instruments of power. To draw a boundary on a map was to make a claim, and empires used cartography to divide territory, assert ownership and control distant lands. Colonial powers mapped continents they barely understood, imposing straight borders across deserts and forests that ignored the people already living there. Some of those arbitrary lines still cause conflict today. A map, far from being neutral, could be a weapon of empire.
In the twenty-first century, mapmaking has undergone its greatest revolution yet. Satellites now photograph the entire planet, and the map has migrated from the paper sheet to the glowing screen in every pocket. Digital services track our position in real time, guide our journeys turn by turn and update themselves constantly. The map has become interactive, personal and alive. What began as scratches on bone has become one of the most used technologies on earth.
The rainforests of the sea: coral reefs under pressure
Why the ocean's richest habitats are also among its most fragile
The rainforests of the sea: coral reefs under pressure
Why the ocean's richest habitats are also among its most fragile
Coral reefs are among the most crowded habitats on the planet. Though they cover less than one per cent of the ocean floor, they shelter around a quarter of all marine species, from tiny shrimp to sharks. This extraordinary richness has earned them the nickname 'the rainforests of the sea'. For sheer variety of life packed into a small space, few places on earth can rival a healthy reef.
Behind this abundance lies a remarkable partnership. The coral animal, a tiny relative of the jellyfish, builds the hard stony skeleton of the reef, but it cannot feed itself alone. Living inside its tissues are microscopic algae that use sunlight to make food, sharing it with their host and giving the coral its brilliant colour. In return the coral offers the algae shelter and nutrients. This close cooperation between two very different organisms is the engine that builds the entire reef.
That partnership, unfortunately, is easily broken by heat. When the surrounding water grows just a degree or two too warm for too long, the stressed coral expels the algae living inside it, losing both its colour and its main source of food. The reef turns a ghostly white, an event known as bleaching. A bleached coral is not yet dead and can recover if conditions improve, but if the heat persists it will starve. Rising sea temperatures, therefore, strike at the very heart of the reef.
Warming is far from the only danger. As the oceans absorb more of the carbon dioxide humans release, the water is slowly turning more acidic, which makes it harder for corals to build their stony skeletons in the first place. Pollution from farms and cities feeds smothering blankets of algae, while destructive fishing and careless tourism break the fragile structures directly. The reef, in short, faces not one threat but a whole array of them at once.
The loss of reefs would be felt far beyond the water's edge. Hundreds of millions of people depend on reefs for the fish they eat and sell, and healthy reefs act as natural sea walls, absorbing the force of storms before they reach the shore. Reef tourism supports whole national economies, and coral organisms are even yielding new medicines. Protecting reefs, then, is not only a matter of saving beautiful scenery but of safeguarding human livelihoods.
For all these pressures, the outlook is not entirely bleak. Scientists are breeding corals that can tolerate warmer water, growing young colonies in nurseries and transplanting them onto damaged reefs. Marine protected areas, where fishing is limited, have allowed some reefs to recover strongly. None of this can succeed, however, unless the warming of the oceans is slowed. With determined action, researchers believe, many reefs can still be saved.
The machine that moved the world: a history of the bicycle
How a simple two-wheeler changed travel, society and the city
The machine that moved the world: a history of the bicycle
How a simple two-wheeler changed travel, society and the city
The bicycle did not arrive fully formed but evolved through a series of strange experiments. Its earliest ancestor, built in 1817, was a wooden two-wheeler with no pedals that the rider pushed along with the feet. Later came machines with pedals fixed directly to an enormous front wheel, the famous and dangerous 'penny-farthing'. Only in the 1880s did the 'safety bicycle', with two equal wheels and a chain drive, bring the design close to what we ride today. The modern bicycle was the product of decades of trial and error.
When the safety bicycle arrived, it spread with extraordinary speed. Affordable, reliable and easy to ride, it set off a genuine craze in the 1890s, as hundreds of thousands of people in Europe and America took to two wheels. Factories sprang up to meet demand, and prices tumbled as production grew. Within a single decade the bicycle had changed from an expensive novelty for daring young men into a mass form of transport for ordinary people.
For many, the most profound effect of the bicycle was on the lives of women. At a time when respectable women were expected to stay close to home, the bicycle offered a cheap and independent means of travel that needed no horse, carriage or male escort. It also helped to loosen restrictive fashions, as long skirts gave way to practical clothing. One leading campaigner declared that cycling had done more to free women than anything else. The humble machine, in short, became an unlikely engine of social change.
The bicycle's dominance, however, did not last. As the motor car became cheaper in the early twentieth century, it captured the public imagination and the bicycle came to be seen, in wealthy countries at least, as a machine for children or the poor. Roads were redesigned around the automobile, and cycling for transport declined sharply for several decades. The invention that had once symbolised freedom and progress was pushed to the margins.
In recent years, though, the bicycle has enjoyed a remarkable return to favour. Concern about traffic, pollution and health has led many cities to rediscover cycling as a clean and efficient way to move people through crowded streets. Governments have built protected bike lanes and launched public hire schemes, and in places such as the Netherlands and Denmark cycling has become a normal part of daily life once more. The bicycle, long dismissed, is once again taken seriously.
This revival matters because the bicycle answers so many modern problems at once. It takes up little space, produces no pollution, keeps its rider healthy and costs a fraction of a car to run. In crowded cities struggling with congestion and dirty air, a machine invented two centuries ago is proving unexpectedly well suited to the future. Simple, cheap and green, the bicycle may yet be one of the most important vehicles of the coming century.
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