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Is this why time speeds up as we age?
We take fewer mental pictures per second.
- Recent memories run in our brains like sped-up old movies.
- In childhood, we capture images in our memory much more quickly.
- The complexities of grownup neural pathways are no match for the direct routes of young brains.
Mechanical engineer Adrian Bejan of Duke University has an interesting theory regarding the strange phenomenon by which time seems to speed up as we age. It's not the only theory, mind you, but an interesting one. In his just-published paper, "Why the Days Seem Shorter as We Get Older," he links the phenomenon to the idea that visual images and the manner in which we process them are the language in which we store and retrieve memories.
Considering it an issue of physics, he suggests that we more rapidly capture and remember visual data when we're young and that this sets our personal "mind time" playback rate. Since it takes longer to capture images and memory when we're older, for a number of reasons, the same length of clock time results in fewer images. When we play our back memories at our habitual mind-time rate, they seem sped up to us, much like how old movies appear (the reason why they appear so will be explained shortly). Hence, the clock time they encompass seems to have gone by faster than older memories.
"The human mind senses time changing when the perceived images change. Days seemed to last longer in your youth because the young mind receives more images during one day than the same mind in old age."
To understand Bejan's concept, it helps to understand the old-movie phenomenon. Obviously, the sense of motion in films is produced by rapidly flashing a sequence of changing images before our eyes that causes our brains to see a cohesive moving event. In the early days of cinema, movie cameras captured images at 16 frames per second.
Since The Jazz Singer in 1927 — in order to accommodate sound — we've filmed and played back movies at 24 frames per second. This means that when we play a second of an old 16 fps film, it goes by in just two-thirds of a second, making it seems like everyone in those days moved more quickly than we do now, or that their time was sped-up. This is the essential conceit behind Bejan's hypothesis.
In this excerpt from Peter Jackson's WWI movie "They Shall Not Grow Old," the playback speed changes from 24 fps to the original 16 fps at the same moment the black-and-white contrast is corrected, and everyone is revealed to be moving at a normal speed. Image source: Imperial War Museums
According to Bejan's paper, "Time represents perceived changes in stimuli (observed facts), such as visual images. The human mind perceives reality (nature, physics) through images that occur as visual inputs reach the cortex."
Clock time is mutually agreed-upon and measurable: All clocks agree on its passage, barring mechanical irregularities. Mind time is more subjective, though, and, "The time that you perceive is not the same as the time perceived by another." Bejan says this is caused by the way we interpret time looking back on memories recent and distant. Our playback rate is constant but fewer images are recorded in memory by older people, producing the old-movie effect.
Processing memory images more slowly as we age
The paper notes that the average adult makes three to five rapid eye movements — or "saccades" — each second, resting in intervals of 200–300 milliseconds in-between. These rest stops are called "fixations." If fixations go on for too long, the visual image blurs, its perception fades away in about 10 seconds, and it's thus less likely to be captured in memory. Because of this, and because one can rarely take in the entire field of vision without moving one's eyes, saccade reaction time is critical to gathering images to store in memory.
In infants, the fixation periods are shorter, and thus the saccades more frequent, allowing the discernment and capture of more images.
As for older people, Bejan cites a study that found "peak [saccade] velocities were significantly reduced in the elderly." In the study, the entire visual system lagged, and "saccadic accuracy was significantly decreased." There are a couple of reasons for this. First, the more complicated neural pathways that have evolved over the course of a lifetime slow down the trip from the eyes to the cortex — children's pathways are still fairly simple, making the journey much more direct and thus shorter. Second, fatigue — used here as a broad term encompassing "impairment, or loss, of efficiency and skill" — lengthens the fixations so they don't stick and reduces the frequency of saccades.
Why do you think time speeds up?
In addition to Bejan's hypothesis, one can also think of other possible reasons that time speeds up in adults as they age:
- A change from the flitting-from-object-to-object attention of childhood to the more concentrated attention required for adult tasks produces fewer visually distinct images worthy of capture.
- Adult responsibilities keep adults busier, and thus the days, weeks, and months fly by more quickly. All of us can remember being bored as children, a sensation that for most of us is a thing of the past.
- A heightening awareness of brevity of life.
It would be interesting to learn if people in retirement continue to experience the speeding up of time.
Construction of the $500 billion dollar tech city-state of the future is moving ahead.
- The futuristic megacity Neom is being built in Saudi Arabia.
- The city will be fully automated, leading in health, education and quality of life.
- It will feature an artificial moon, cloud seeding, robotic gladiators and flying taxis.
The Red Sea area where Neom will be built:
Saudi Arabia Plans Futuristic City, "Neom" (Full Promotional Video)<span style="display:block;position:relative;padding-top:56.25%;" class="rm-shortcode" data-rm-shortcode-id="c646d528d230c1bf66c75422bc4ccf6f"><iframe type="lazy-iframe" data-runner-src="https://www.youtube.com/embed/N53DzL3_BHA?rel=0" width="100%" height="auto" frameborder="0" scrolling="no" style="position:absolute;top:0;left:0;width:100%;height:100%;"></iframe></span>
Are we genetically inclined for superstition or just fearful of the truth?
- From secret societies to faked moon landings, one thing that humanity seems to have an endless supply of is conspiracy theories. In this compilation, physicist Michio Kaku, science communicator Bill Nye, psychologist Sarah Rose Cavanagh, skeptic Michael Shermer, and actor and playwright John Cameron Mitchell consider the nature of truth and why some groups believe the things they do.
- "I think there's a gene for superstition, a gene for hearsay, a gene for magic, a gene for magical thinking," argues Kaku. The theoretical physicist says that science goes against "natural thinking," and that the superstition gene persists because, one out of ten times, it actually worked and saved us.
- Other theories shared include the idea of cognitive dissonance, the dangerous power of fear to inhibit critical thinking, and Hollywood's romanticization of conspiracies. Because conspiracy theories are so diverse and multifaceted, combating them has not been an easy task for science.
A growing body of research suggests COVID-19 can cause serious neurological problems.
- The new study seeks to track the health of 50,000 people who have tested positive for COVID-19.
- The study aims to explore whether the disease causes cognitive impairment and other conditions.
- Recent research suggests that COVID-19 can, directly or indirectly, cause brain dysfunction, strokes, nerve damage and other neurological problems.
Brain images of a patient with acute demyelinating encephalomyelitis.
COVID-19 and the brain<p>A growing body of research reveals alarming neurological complications among COVID-19 patients. On Wednesday, for example, researchers from University College London published a <a href="https://academic.oup.com/brain/article/doi/10.1093/brain/awaa240/5868408" target="_blank">study</a> in the journal Brain that describes how some patients have suffered temporary brain dysfunction, strokes, nerve damage, and other neurological problems concurrent with COVID-19.</p><p>Some patients suffered brain inflammation as a result of a rare disease called acute disseminated encephalomyelitis, which can cause numbness, seizures, and confusion. One patient in the study even hallucinated monkeys and lions in her home.</p>
Photo by Mario Tama/Getty Images<p>A separate study published in the <a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7198407/" target="_blank">Journal of Clinical Neuroscience</a> notes that some COVID-19 patients have also suffered neurological complications like impaired consciousness and acute cerebrovascular disease. The study notes that past viruses like MERS and SARS also seemed to cause neurological problems.</p><p>A troubling finding among this growing body of research is that some patients seem to suffer neurological damage even when respiratory symptoms aren't obvious. Additionally, scientists aren't sure whether damage from the disease will be permanent.</p><p style="margin-left: 20px;">"Given that the disease has only been around for a matter of months, we might not yet know what long-term damage COVID-19 can cause," Dr. Ross Paterson, joint first author of the University College London study, said in a <a href="https://www.eurekalert.org/pub_releases/2020-07/ucl-iid070620.php" target="_blank">press release</a>. "Doctors needs to be aware of possible neurological effects, as early diagnosis can improve patient outcomes."</p><p>If you've been diagnosed with COVID-19 and want to enroll in the study, visit <a href="https://www.cambridgebrainsciences.com/studies/covid-brain-study" target="_blank">cambridgebrainsciences.com/studies/covid-brain-study</a>.</p>
Coronavirus layoffs are a glimpse into our automated future. We need to build better education opportunities now so Americans can find work in the economy of tomorrow.