NO MORE THAN TWO WORDS AND / OR NUMBERS
from the
passage for each answer.
Q1. According to the writers, what might the use of spices in cooking help people to avoid?
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Q2. What proportion of bacteria in food do four of the spices tested destroy?
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Q3. Which food often contains a spice known as ‘quatre epices’?
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Q4. Which types of country use the fewest number of spices in cooking?
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Q5. What might food aversions often be associated with?
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Q6. Apart from spices, which substance is used in all countries to preserve food?
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QUESTION-TYPE BASED TESTS
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TEST 2 – Tower of Strength
A.
Of all the Stories of art influencing science, tensegrity is one of the most far-reaching. On one
level, tensegrity is a system of creating architecture or sculptures involving rods in compression and wires in
tension. lt was invented by sculptor Kenneth Snelson at Black Mountain College, the hotbed of international
modernism, in 1948. At the time, Snelson was taking part in a summer school with the engineer
Buckminster Fuller, who pioneered the idea of applying geometric forms to architectural and engineering
innovation.
B.
Using an abstract sculpture as a starting point, Snelson then added tension wires to the free-
floating members. Fuller encouraged him and when they met up again in I949, Snelson had perfected a
concept in which stiff rods can be supported without touching by a network of wires. Although “tensegrity'
(from 'tensional integrity`) was coined by Fuller, the idea was entirely Snelson's, and he went on to make
many more tensegrity sculptures, the most famous of which is the sixty-foot high Needle Tower (1968), now
at the Hirshhorn Museum and Sculpture Garden, Washington DC.
C.
Basic tensegrity structures can be made from three drinking straws, six paper clips, and nine
rubber bands. When the structure is wired up, you can see that none of the rods actually touch; they`re held
in equilibrium by the rubber bands. Even this simplest model has very interesting properties. Although
drinking straws are weak, with a tendency to buckle, the tension bands hold them in such a way that the
compressive force is always directed straight down the tube and buckling doesn`t happen. The first thing
you notice if you make one is that it is immensely fiddly to assemble pieces keep falling apart — but once
the last band is secured, you can fling the object around, squash it, and it seems indestructible. The structure
isn`t symmetrical in its properties. In one direction, it squashes flat and bounces back. In the other direction,
it resists the pressure. If you wanted to create versatile 3D structures out of nothing much, tensegrity
would take some beating.
D.
It is strange that architects and engineers didn`t discover the principle before 1948, since the
benefits of structures held in tension over traditional building techniques had been known since the
invention of the suspension bridge in 1796. And the great maverick biologist D`Arcy Thompson in On
Growth and Form (19l?) had extensively analyzed the principles of tension and compression both in nature
and engineering. Kenneth Snelson believed that tensegrity was a pure art and that it would never be really
useful architecturally. It took some time to prove him wrong, but in the 1980s, tensegrity architecture began
to appear. The key protagonist was David Geiger and the first important structure was his Gymnastics Hall
at the Korean Olympics in 1988.
E.
Five years later, its significance in quite a different field became apparent when scientists
described the tensegrity model of cell structure, and this is where the principle is now making waves. What
is it that prevents living things from collapsing to a blob of jelly on the floor? Unsurprisingly, it is likely to
be tensegrity. For a long time, biologists ignored the mechanical properties of cells: they were just `elastic
bags` full of interesting chemicals. But there has to be an architecture; tissue is tough, resilient stuff that
keeps its shape.
F.
The human body is certainly a tensegrity structure; it consists of 206 bones tensegrity rods that do
not touch, held together by tendons and muscles. And the tension of living cells seems to be maintained by
tensegrity structures within the cell; microfilaments play the role of the rubber bands and stiff microtubules
are the rods. Donald lngber, at the Harvard Medical School, researches how cells move and stick to each
other, and he believes that tensegrity offers ‘the most unified model of cell mechanics’. It explains some
basic properties of cells very well.
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