Back To The Future Of Skyscraper Design - IELTS Reading Answers & Explanations
From Cambridge IELTS 14 Academic Reading Test 2 · Part 2 · Questions 14–26
Reading Passage
Back to the future of skyscraper design
Answers to the problem of excessive electricity use by skyscrapers and large public buildings can be found in ingenious but forgotten architectural designs of the 19th and early-20th centuries
A
The Recovery of Natural Environments in Architecture by Professor Alan Short is the culmination of 30 years of research and award-winning green building design by Short and colleagues in Architecture, Engineering, Applied Maths and Earth Sciences at the University of Cambridge.
‘The crisis in building design is already here,’ said Short. ‘Policy makers think you can solve energy and building problems with gadgets. You can’t. As global temperatures continue to rise, we are going to continue to squander more and more energy on keeping our buildings mechanically cool until we have run out of capacity.’
B
Short is calling for a sweeping reinvention of how skyscrapers and major public buildings are designed – to end the reliance on sealed buildings which exist solely via the ‘life support’ system of vast air conditioning units.
Instead, he shows it is entirely possible to accommodate natural ventilation and cooling in large buildings by looking into the past, before the widespread introduction of air conditioning systems, which were ‘relentlessly and aggressively marketed’ by their inventors.
C
Short points out that to make most contemporary buildings habitable, they have to be sealed and air conditioned. The energy use and carbon emissions this generates is spectacular and largely unnecessary. Buildings in the West account for 40-50% of electricity usage, generating substantial carbon emissions, and the rest of the world is catching up at a frightening rate. Short regards glass, steel and air-conditioned skyscrapers as symbols of status, rather than practical ways of meeting our requirements.
D
Short’s book highlights a developing and sophisticated art and science of ventilating buildings through the 19th and earlier-20th centuries, including the design of ingeniously ventilated hospitals. Of particular interest were those built to the designs of John Shaw Billings, including the first Johns Hopkins Hospital in the US city of Baltimore (1873-1889).
‘We spent three years digitally modelling Billings’ final designs,’ says Short. ‘We put pathogens* in the airstreams, modelled for someone with tuberculosis (TB) coughing in the wards and we found the ventilation systems in the room would have kept other patients safe from harm.
—————
* pathogens: microorganisms that can cause disease
E
‘We discovered that 19th-century hospital wards could generate up to 24 air changes an hour – that’s similar to the performance of a modern-day, computer-controlled operating theatre. We believe you could build wards based on these principles now.
Single rooms are not appropriate for all patients. Communal wards appropriate for certain patients – older people with dementia, for example – would work just as well in today’s hospitals, at a fraction of the energy cost.’
Professor Short contends the mindset and skill-sets behind these designs have been completely lost, lamenting the disappearance of expertly designed theatres, opera houses, and other buildings where up to half the volume of the building was given over to ensuring everyone got fresh air.
F
Much of the ingenuity present in 19th-century hospital and building design was driven by a panicked public clamouring for buildings that could protect against what was thought to be the lethal threat of miasmas – toxic air that spread disease. Miasmas were feared as the principal agents of disease and epidemics for centuries, and were used to explain the spread of infection from the Middle Ages right through to the cholera outbreaks in London and Paris during the 1850s. Foul air, rather than germs, was believed to be the main driver of ‘hospital fever’, leading to disease and frequent death. The prosperous steered clear of hospitals.
While miasma theory has been long since disproved, Short has for the last 30 years advocated a return to some of the building design principles produced in its wake.
G
Today, huge amounts of a building’s space and construction cost are given over to air conditioning. ‘But I have designed and built a series of buildings over the past three decades which have tried to reinvent some of these ideas and then measure what happens.
‘To go forward into our new low-energy, low-carbon future, we would be well advised to look back at design before our high-energy, high-carbon present appeared. What is surprising is what a rich legacy we have abandoned.’
H
Successful examples of Short’s approach include the Queen’s Building at De Montfort University in Leicester. Containing as many as 2,000 staff and students, the entire building is naturally ventilated, passively cooled and naturally lit, including the two largest auditoria, each seating more than 150 people. The award-winning building uses a fraction of the electricity of comparable buildings in the UK.
Short contends that glass skyscrapers in London and around the world will become a liability over the next 20 or 30 years if climate modelling predictions and energy price rises come to pass as expected.
I
He is convinced that sufficiently cooled skyscrapers using the natural environment can be produced in almost any climate. He and his team have worked on hybrid buildings in the harsh climates of Beijing and Chicago – built with natural ventilation assisted by back-up air conditioning – which, surprisingly perhaps, can be switched off more than half the time on milder days and during the spring and autumn.
Short looks at how we might reimagine the cities, offices and homes of the future. Maybe it’s time we changed our outlook.
Questions
Questions 14–18 Matching Information
The Reading Passage has nine section, A-I
Which section contains the following information?
Write the correct letter, A-I, in boxes on your answer sheet.
Questions 19–26 Summary Completion
Complete the summary below.
Choose ONE WORD ONLY from the passage for each answer.
Write your answers in boxes on your answer sheet.
Ventilation in 19th-century hospital wards
Professor Alan Short examined the work of John Shaw Billings, who influenced the architectural 19 of hospitals to ensure they had good ventilation. He calculated that 20 in the air coming from patients suffering form 21 would not have harmed other patients. He also found that the air in 22. In hospitals could change as often as in a modern operating theatre. He suggests that energy use could be reduced by locating more patients in 23 areas.
A major reason for improving ventilation in 19th-century hospitals was the demand from the 24 for protection against bad air, known as 25. These were blamed for the spread of disease for hundreds of years, including epidemics of 26 in London and Paris in the middle of the 19th century.
Answers & Explanations Summary
| # | Answer | Evidence | Explanation |
|---|---|---|---|
| Q14 | F | Foul air, rather than germs, was believed to be the main driver of ‘hospital fever’, leading to disease and frequent death. The prosperous steered clear of hospitals. | Excerpt/Passage Explanation: The passage explains that in the past, people thought bad air, not germs, caused illnesses in hospitals. This belief caused some wealthy individuals to avoid hospitals. Answer Explanation: The answer means section F of the passage contains the information about why some individuals avoided hospitals during the 19th century. Reason For Correctness: The correct answer is F because it directly addresses the reason for people avoiding hospitals in the 19th century, as mentioned in the excerpt. It states that the belief in foul air causing diseases in hospitals was a significant factor in people choosing to stay away from them. |
| Q15 | C | Short regards glass, steel and air-conditioned skyscrapers as symbols of status, rather than practical ways of meeting our requirements. | Excerpt/Passage Explanation: The passage talks about how short buildings see tall skyscrapers made of glass, steel, and with air-conditioning as symbols of social status rather than practical solutions to our needs. Answer Explanation: The answer choice 'C' contains a suggestion that tall buildings are connected to prestige. Reason For Correctness: The correct answer is 'C' because the excerpt explicitly mentions that tall buildings are seen as symbols of status, aligning with the idea that the popularity of tall buildings is linked to prestige. |
| Q16 | E | We discovered that 19th-century hospital wards could generate up to 24 air changes an hour – that’s similar to the performance of a modern-day, computer-controlled operating theatre | Excerpt/Passage Explanation: The passage talks about how air circulation in 19th-century hospital wards was similar to that in modern-day operating theatres. Answer Explanation: The answer E corresponds to the section that discusses the comparison between the air circulation in a 19th-century building and modern standards. Reason For Correctness: The correct answer is E because the passage directly mentions the comparison between the air circulation in a 19th-century hospital ward and a modern-day operating theatre, which aligns with the information provided in the question. |
| Q17 | D | ‘We put pathogens* in the airstreams, modelled for someone with tuberculosis (TB) coughing in the wards and we found the ventilation systems in the room would have kept other patients safe from harm. | Excerpt/Passage Explanation: The passage talks about a test where Short and his team introduced pathogens into the airflow to simulate a person with tuberculosis coughing in a 19th-century building. Answer Explanation: The answer is D. Reason For Correctness: The correct answer is D because it mentions the testing of the circulation of air in a 19th-century building through the simulation of TB pathogens in the airflow to study the impact on other patients' safety. |
| Q18 | B | the widespread introduction of air conditioning systems, which were ‘relentlessly and aggressively marketed’ by their inventors | Excerpt/Passage Explanation: The passage talks about how air conditioning systems were heavily promoted by their creators. Answer Explanation: The answer points to a section that implies advertising played a role in the significant increase in the use of air conditioning. Reason For Correctness: The correct answer is 'B' because the excerpt mentioning the aggressive marketing of air conditioning systems suggests a direct link between advertising and the rise in their usage, aligning with the implication specified in the question. |
| Q19 | design / designs | Short’s book highlights a developing and sophisticated art and science of ventilating buildings through the 19th and earlier-20th centuries, including the design of ingeniously ventilated hospitals. Of particular interest were those built to the designs of John Shaw Billings | Excerpt/Passage Explanation: The passage talks about the design aspect in ventilating buildings, specifically hospitals, during the 19th and early-20th centuries. John Shaw Billings' designs for hospitals are highlighted as being ingeniously ventilated. Answer Explanation: The answer 'design' refers to the architectural plans and layouts of buildings, particularly in this context, the hospitals constructed with a focus on effective ventilation. Reason For Correctness: The correct answer 'design' aligns with the mention of John Shaw Billings' designs for hospitals in the excerpt. This highlights the emphasis on the architectural aspect of ventilation in hospitals during the mentioned time period. |
| Q20 | pathogens | We put pathogens* in the airstreams | Excerpt/Passage Explanation: The passage mentions putting pathogens, which are harmful germs or microorganisms that can cause diseases, into the airstreams. Answer Explanation: The answer 'pathogens' refers to harmful germs or microorganisms that can cause disease. Reason For Correctness: The correct answer is 'pathogens' because it directly relates to the harmful microorganisms mentioned in the context of the passage, which can be spread through the air in hospitals and lead to the demand for improved ventilation for protection against these disease-causing agents. |
| Q21 | tuberculosis | modelled for someone with tuberculosis | Excerpt/Passage Explanation: The passage is talking about designing hospital wards to ensure good ventilation specifically for patients with tuberculosis. Answer Explanation: The answer 'tuberculosis' refers to a disease that affects the lungs and can spread through the air when infected people cough or sneeze. Reason For Correctness: The correct answer is 'tuberculosis' because it is mentioned in the passage that the air coming from patients suffering from tuberculosis was considered not harmful to other patients in terms of ventilation calculations. |
| Q22 | wards | 19th-century hospital wards could generate up to 24 air changes an hour | Excerpt/Passage Explanation: The passage talks about how hospital wards in the 19th century could have good ventilation due to the air changing up to 24 times in an hour. Answer Explanation: The answer 'wards' refers to specific areas within hospitals, like rooms where patients are housed. Reason For Correctness: The correct answer is 'wards' because the excerpt mentions '19th-century hospital wards' specifically, indicating the focus on these areas within hospitals for ventilation improvements. |
| Q23 | communal | Communal wards appropriate for certain patients – older people with dementia, for example – would work just as well in today’s hospitals, at a fraction of the energy cost | Excerpt/Passage Explanation: The passage suggests that communal wards, which were suitable for some patients like older people with dementia, would be effective in today's hospitals at a lower energy cost. Answer Explanation: The answer is 'communal' which refers to shared spaces where patients can be located. Reason For Correctness: The correct answer is 'communal' because the passage mentions that locating patients in communal areas would be beneficial in reducing energy use. |
| Q24 | public | Much of the ingenuity present in 19th-century hospital and building design was driven by a panicked public | Excerpt/Passage Explanation: The passage explains that much of the clever design in hospitals in the 19th century was influenced by the worries of the general population. Answer Explanation: The answer refers to the general population, which means ordinary people as a whole. Reason For Correctness: The correct answer matches the context of the passage where Professor Alan Short studied the influence of John Shaw Billings on hospital design based on the concerns of the public regarding ventilation and air quality in hospitals. |
| Q25 | miasmas | protect against what was thought to be the lethal threat of miasmas | Excerpt/Passage Explanation: The passage talks about protecting against what was believed to be dangerous bad air. Answer Explanation: The answer 'miasmas' refers to these harmful or toxic vapors or gases from decomposing organic matter believed to cause disease. Reason For Correctness: The correct answer is 'miasmas' because it directly relates to the concept of harmful bad air that was thought to spread disease in the 19th century, as mentioned in the excerpt. |
| Q26 | cholera | the spread of infection from the Middle Ages right through to the cholera outbreaks in London and Paris during the 1850s | Excerpt/Passage Explanation: The passage talks about how diseases like cholera have been spreading for a long time, even causing outbreaks in major cities like London and Paris in the 1850s. Answer Explanation: The answer 'cholera' refers to a serious disease that caused epidemics in London and Paris. Reason For Correctness: The correct answer is 'cholera' because the excerpt mentions outbreaks of this disease in London and Paris in the middle of the 19th century. Cholera was a significant health concern during that time, and improving ventilation in hospitals was crucial to prevent the spread of this deadly disease. |