Timeless Math Memes: A Century of Distraction for Mathematicians

The tree-like form arises from the connections within the Collatz conjecture.

Marzio de Biagi/Algolito Malte

Nearly a century ago, the renowned mathematician Lothar Collatz introduced a deceptively simple yet profoundly challenging puzzle. This problem has captivated numerous mathematicians, generating much discourse and debate. Despite many claiming to have solved it, the quest for a comprehensive proof continues. Once you grasp the rules, you might find yourself enraptured, and I take no responsibility for any hours you might lose to this intriguing riddle.

The process begins like a magic trick: choose any positive integer. If the number is even, divide it by 2. If it’s odd, multiply by 3 and add 1. Apply these rules iteratively to the resulting numbers. Mathematicians believe that eventually, this process will always lead to 1.

This question, known as the Collatz conjecture, remains unresolved for all positive integers. The conjecture, initiated by Lothar Collatz in the 1930s, has proven to be remarkably challenging. Even the esteemed mathematician Paul Erdős remarked, “mathematics may not be ready for such problems.”

So, what makes the Collatz conjecture so perplexing to prove? Upon hearing about this problem, many rush to calculators, eager to verify if various numbers reach 1. In fact, comprehensive computer algorithms have checked all numbers up to 271, but given the infinity of integers, finding a definitive proof remains elusive.

The behavior of these numbers is unpredictable. Starting with 1 leads to conclusive results, while initiating with 2 accomplishes the same. However, beginning with 3 generates a chain: 10, 5, 16, 8, 4, 2, and finally 1. For 7, the sequence is more extensive, containing intermediate steps that eventually lead back to previously evaluated numbers. This implies that once you revisit past numbers, there’s no need to recalculate since their paths are already known.

This chaotic nature poses significant challenges for mathematicians. I recall a quote from the xkcd webcomic: “There’s a certain type of brain that easily malfunctions when presented with an intriguing problem.” Indeed, as the Collatz meme spread, countless individuals became ensnared by its allure.

The consequences of Collatz’s conjecture affect many enthusiasts.

xkcd.com/356/

The Mysteries of the Collatz Conjecture Unveiled

Tracing the origins of the Collatz conjecture is surprisingly challenging, yet obtaining a proof remains an even greater endeavor. In a 1980 correspondence, Collatz mentioned his long-standing investigation. Initially, he seemed to view this problem as merely a mathematical curiosity. The conjecture began gaining traction around 1950 during the International Congress of Mathematicians conference, where discussions among peers brought it into the spotlight.

Following its rise in popularity, the problem was rediscovered by various mathematicians, acquiring names like the Syracuse problem, Hasse’s algorithm, and the 3x+1 problem. This topic first appeared in print in 1971, described as “mathematical gossip.” It gained wider recognition when Martin Gardner featured it in a 1972 issue of Scientific American. Gardner, a prominent figure in recreational mathematics, fueled public intrigue in this enigmatic problem.

The Collatz conjecture has consistently straddled the line between recreational and formal mathematics. An article from 1983 titled “Do Not Try to Solve These Problems” warned mathematicians against tackling the conjecture, understanding that the temptation was almost irresistible.

Lothar Collatz dedicated over 50 years to analyzing his conjecture.

Oberwolfach photo collection

A notable advancement came in 1976, when Riho Terrace demonstrated significant results. When starting with an even number, the first operation halves it, ensuring that the Collatz chain remains below this initial number. Conversely, starting with an odd number means the first step goes above the starting point. This concept introduced the “stop time” of numbers, confirming that, in most instances, the numbers will decline rather than diverge indefinitely.

Nevertheless, this isn’t sufficient to validate the Collatz conjecture. A solitary enormous counterexample that fails to converge to 1 would invalidate the conjecture. Moreover, tackling infinite potentials raises questions about the meaning of “almost all.” In 2002, Ilya Krasikov and Lagarias provided a proof indicating that for a given number x, at least x0.84 of integers less than x ultimately arrive at 1. For instance, if x is 100, it implies at least 47 integers below 100 do reach 1.

The most significant breakthrough emerged in 2019, when Terence Tao, perhaps the preeminent mathematician of our era, accepted the Collatz challenge. He established a stronger version of Terras’ findings, suggesting that “almost all” numbers not only drop below their initial value but can be reduced to any desired lower threshold. While this progress feels near proof, the existence of potential counterexamples continues to loom.

What lies ahead for the Collatz conjecture? As I compose this piece, reports emerge that OpenAI utilized large-scale language models to tackle a major mathematical conundrum that has confounded scholars for approximately 80 years. Not through a straightforward proof, however, but via the discovery of unexpected counterexamples. Could AI potentially solve the Collatz conjecture? While predictions are premature, it would be intriguing if a challenge that has vexed the human intellect were ultimately resolved by artificial intelligence.

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Source: www.newscientist.com

Smartphone Notifications: A Bigger Distraction Than You Realize

They may be worth managing to reduce interruptions from notifications

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Observing notifications from a social media platform indicates they can distract us for a few moments, even without opening them.

Hippolyte Fournier, from Lumiere University Lyon 2 in France, has been keen to study the impact of attention and social media. “Notifications from a social media app during work hours certainly affected my concentration,” he shares.

To delve deeper, Fournier and his team engaged 180 university students in a psychology exercise known as the Stroop task on smartphone-sized screens. This task evaluates how swiftly individuals can identify colors presented in words, such as the word “red” displayed in blue.

During the task, a social media notification appeared but could not be interacted with. Some participants were led to think these alerts were from their own devices, while others were not aware. A third group encountered blurry, illegible notifications.

The researchers suggested that the valid notifications were the most disruptive to the participants, as they proved to be the most distracting of the three conditions, notes neuroscientist Dean Burnett, who did not participate in the study.

Participants in this group took, on average, about 7 seconds longer to complete the Stroop tasks compared to when no notifications were present. This delay was particularly noted among those who frequently utilized their phones, as indicated by screen time data collected three weeks prior to the study.

Burnett comments that the findings suggest an overload of notifications “hinders your cognitive capacity.”

“We have two types of attention: one that is consciously guided and another that is instinctively responsive,” he explains. “Normally, they are in harmony, but when something grabs our attention, the instinctual response can redirect resources and diminish the mental space needed for our current focus, thus serving as a distraction.”

Researchers plan to investigate further to understand why notifications are so distracting and whether the effects vary with different types of alerts. For the time being, Fournier advises people to manage their notifications by disabling them and checking social media at designated times. “Some studies indicate that turning off notifications can enhance a person’s control over their attention in daily life,” he notes.

This research is available in psyarxiv, although a DOI is not yet assigned.

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Source: www.newscientist.com