Paragraph 1

"Creativity is at once our most precious resource and our most inexhaustible one."

Explanation: Creativity is both extremely valuable and something we never run out of.

"As anyone who has ever spent any time with children knows, every single human being is born creative; every human being is innately endowed with the ability to combine and recombine data, perceptions, materials and ideas, and devise new ways of thinking and doing."

Explanation: Just like we observe in children, all humans naturally have the ability to think in new ways and come up with original ideas.

"What fosters creativity? More than anything else: the presence of other creative people."

Explanation: The best way to encourage creativity is by being around other creative individuals.

"The big myth is that creativity is the province of great individual geniuses."

Explanation: It's a common misconception that only a few brilliant individuals possess creativity.

"In fact creativity is a social process."

Explanation: Actually, creativity often happens when people interact with one another.

"Our biggest creative breakthroughs come when people learn from, compete with, and collaborate with other people."

Explanation: The most significant innovations usually result from people sharing ideas, challenging each other, and working together.

Paragraph 2

"Cities are the true fonts of creativity..."

Explanation: Cities are the main sources or origins of creative energy.

"With their diverse populations, dense social networks, and public spaces where people can meet spontaneously and serendipitously, they spark and catalyze new ideas."

Explanation: The mix of different people, close connections, and random social interactions in cities help generate new ideas.

"With their infrastructure for finance, organization and trade, they allow those ideas to be swiftly actualized."

Explanation: Cities also have the systems—like finance and business—that help quickly turn ideas into reality.

Paragraph 3

"As for what staunches creativity, that’s easy, if ironic."

Explanation: What stops creativity is clear, and it’s ironically tied to what was supposed to support it.

"It’s the very institutions that we build to manage, exploit and perpetuate the fruits of creativity — our big bureaucracies, and sad to say, too many of our schools."

Explanation: Institutions like large bureaucracies and many schools, which should support creativity, often end up suppressing it.

"Creativity is disruptive; schools and organizations are regimented, standardized and stultifying."

Explanation: Creativity challenges the norm, while schools and organizations tend to be rigid, uniform, and dull, making them unfriendly to creative thought.

Paragraph 4

"The education expert Sir Ken Robinson points to a 1968 study reporting on a group of 1,600 children who were tested over time for their ability to think in out-of-the-box ways."

Explanation: Sir Ken Robinson refers to a 1968 study that measured the creativity of 1,600 children over several years.

"When the children were between 3 and 5 years old, 98 percent achieved positive scores."

Explanation: Almost all young children (aged 3–5) showed high levels of creativity.

"When they were 8 to 10, only 32 percent passed the same test, and only 10 percent at 13 to 15."

Explanation: As the children grew older, their creativity levels dropped sharply.

"When 280,000 25-year-olds took the test, just 2 percent passed."

Explanation: Among adults, creativity was nearly gone—only a tiny fraction showed out-of-the-box thinking.

"By the time we are adults, our creativity has been wrung out of us."

Explanation: The system drains creativity from people as they grow up.

Paragraph 5

"I once asked the great urbanist Jane Jacobs what makes some places more creative than others."

Explanation: The author consulted urban planning expert Jane Jacobs about why some places are more creative than others.

"She said, essentially, that the question was an easy one."

Explanation: Jacobs believed the answer to this question was simple.

"All cities, she said, were filled with creative people; that’s our default state as people."

Explanation: She believed that everyone is naturally creative, and cities are full of such people.

"But some cities had more than their shares of leaders, people and institutions that blocked out that creativity. She called them 'squelchers.'"

Explanation: However, in some cities, people and institutions suppress creativity; she labeled them “squelchers.”

Paragraph 6

"Creativity (or the lack of it) follows the same general contours of the great socio-economic divide - our rising inequality - that plagues us."

Explanation: Creativity is unevenly distributed across society, much like wealth and opportunity.

"According to my own estimates, roughly a third of us across the United States, and perhaps as much as half of us in our most creative cities - are able to do work which engages our creative faculties to some extent, whether as artists, musicians, writers, techies, innovators, entrepreneurs, doctors, lawyers, journalists or educators - those of us who work with our minds."

Explanation: The author estimates that only about a third to half of people in the U.S. work in jobs that use their creativity—mainly in knowledge or idea-based professions.

"That leaves a group that I term ‘the other 66 percent,’ who toil in low-wage rote and rotten jobs — if they have jobs at all — in which their creativity is subjugated, ignored or wasted."

Explanation: The remaining majority work in low-paying, repetitive jobs that don’t make use of their creative potential.

Paragraph 7

"Creativity itself is not in danger."

Explanation: Creativity as a human trait is not going away.

"It’s flourishing is all around us - in science and technology, arts and culture, in our rapidly revitalizing cities."

Explanation: We see creativity thriving in many fields and places, such as tech, art, and modern cities.

"But we still have a long way to go if we want to build a truly creative society that supports and rewards the creativity of each and every one of us."

Explanation: However, we still need to do a lot more to ensure that everyone's creative potential is recognized and encouraged.

Paragraph 1

"Keeping time accurately comes with a price."

Explanation: Being precise in timekeeping has an associated cost or consequence.

"The maximum accuracy of a clock is directly related to how much disorder, or entropy, it creates every time it ticks."

Explanation: The more accurate a clock is, the more entropy it generates with each tick.

"Natalia Ares at the University of Oxford and her colleagues made this discovery using a tiny clock with an accuracy that can be controlled."

Explanation: Natalia Ares and her team at Oxford discovered this relationship using a specially designed clock whose accuracy could be adjusted.

"The clock consists of a 50-nanometre-thick membrane of silicon nitride, vibrated by an electric current."

Explanation: The clock is made from an ultra-thin silicon nitride membrane, which vibrates when electricity is applied.

"Each time the membrane moved up and down once and then returned to its original position, the researchers counted a tick, and the regularity of the spacing between the ticks represented the accuracy of the clock."

Explanation: A single oscillation of the membrane was considered one tick, and how evenly spaced the ticks were indicated the clock’s accuracy.

"The researchers found that as they increased the clock’s accuracy, the heat produced in the system grew, increasing the entropy of its surroundings by jostling nearby particles."

Explanation: When the clock’s accuracy was increased, it emitted more heat, creating more disorder (entropy) in its environment.

"“If a clock is more accurate, you are paying for it somehow,” says Ares."

Explanation: Ares suggests that high precision in clocks has an inevitable cost.

"In this case, you pay for it by pouring more ordered energy into the clock, which is then converted into entropy."

Explanation: Here, the cost is more input energy that becomes disorder (entropy) as the clock runs.

"“By measuring time, we are increasing the entropy of the universe,” says Ares. The more entropy there is in the universe, the closer it may be to its eventual demise."

Explanation: Measuring time contributes to the universe’s entropy, and growing entropy could lead to the universe’s end.

"“Maybe we should stop measuring time,” says Ares. The scale of the additional entropy is so small, though, that there is no need to worry about its effects, she says."

Explanation: Ares jokes that maybe timekeeping should stop, though the actual increase in entropy is too minor to matter practically.

Paragraph 2

"The increase in entropy in timekeeping may be related to the “arrow of time”, says Marcus Huber at the Austrian Academy of Sciences in Vienna, who was part of the research team."

Explanation: Marcus Huber suggests that this entropy from timekeeping may relate to the concept of time only moving forward.

"It has been suggested that the reason that time only flows forward, not in reverse, is that the total amount of entropy in the universe is constantly increasing…"

Explanation: One theory explains the forward direction of time through the continual increase of entropy.

"…creating disorder that cannot be put in order again."

Explanation: This irreversible growth of disorder explains why time moves in one direction.

Paragraph 3

"The relationship that the researchers found is a limit on the accuracy of a clock, so it doesn’t mean that a clock that creates the most possible entropy would be maximally accurate…"

Explanation: The finding sets a boundary but doesn’t imply that generating more entropy means higher accuracy.

"…hence a large, inefficient grandfather clock isn’t more precise than an atomic clock."

Explanation: So, inefficient clocks like grandfather clocks aren’t more accurate just because they use more energy.

"“It’s a bit like fuel use in a car. Just because I’m using more fuel doesn’t mean that I’m going faster or further,” says Huber."

Explanation: Huber compares it to fuel efficiency—more energy use doesn’t guarantee better performance.

Paragraph 4

"When the researchers compared their results with theoretical models developed for clocks that rely on quantum effects, they were surprised to find that the relationship between accuracy and entropy seemed to be the same for both."

Explanation: They were surprised to see that the same accuracy-entropy relationship applies to quantum clocks as well.

"We can’t be sure yet that these results are actually universal, though, because there are many types of clocks for which the relationship between accuracy and entropy haven’t been tested."

Explanation: It’s still unclear if the accuracy-entropy rule applies to all clocks, as not every type has been studied.

Paragraph 5

"“It’s still unclear how this principle plays out in real devices such as atomic clocks, which push the ultimate quantum limits of accuracy,” says Mark Mitchison at Trinity College Dublin in Ireland."

Explanation: Mark Mitchison notes that it’s uncertain how this relationship applies to ultra-precise devices like atomic clocks.

"Understanding this relationship could be helpful for designing clocks in the future, particularly those used in quantum computers and other devices where both accuracy and temperature are crucial, says Ares."

Explanation: Ares believes that learning more about this principle could improve future clock designs, especially in quantum technology.

"This finding could also help us understand more generally how the quantum world and the classical world are similar and different in terms of thermodynamics and the passage of time."

Explanation: It may also help bridge our understanding of how time and energy behave in both quantum and classical physics.