If all humans died, when would the last light go out?
Summary
TLDRIn a hypothetical scenario where humans vanish, the script explores the longevity of artificial light sources. Power grids would fail rapidly without human intervention, causing a blackout. Nuclear reactors might run indefinitely but would likely shut down automatically upon a grid failure. Non-grid-tied sources like diesel generators could last days to months, while geothermal and wind turbines might run for years before succumbing to mechanical issues. Solar power, with its durability and low maintenance, is the most promising, potentially providing light for a century if well-maintained. Interestingly, radioactive waste, emitting Cherenkov radiation, could glow for centuries, making it a contender for the longest-lasting light source.
Takeaways
- š Without human intervention, power grids would quickly fail due to the lack of fuel supply and maintenance.
- š Fossil fuel plants would shut down within hours, leading to cascading failures and a global blackout.
- āļø Nuclear reactors could theoretically run indefinitely with their fuel, but would shut down automatically upon any malfunction.
- š Diesel generators in remote areas might continue to operate for days to months until their fuel is depleted.
- š Geothermal plants could run for a few years without human maintenance, but would eventually succumb to corrosion.
- š¬ Wind turbines are designed for low maintenance and could potentially run for decades, with some having status LEDs for light.
- š§ Hydroelectric generators, like the Hoover Dam, could continue running on autopilot for several years if the grid were intact.
- š Battery-powered lights would last only a few decades due to self-discharge, regardless of usage.
- āļø Solar power is the most promising, with off-grid solar systems potentially providing light for over a century if well-maintained.
- š” Solar-powered lights, especially in remote locations, could be among the last human-made light sources remaining.
- š§Ŗ Cherenkov radiation from spent nuclear fuel could provide a faint glow for centuries, making it a long-lasting, albeit unconventional, light source.
Q & A
What would be the immediate impact on artificial light sources if humans disappeared from Earth?
-The major power grids would go down relatively quickly, leading to a rapid series of cascading failures and a blackout of all the major power grids.
How would the absence of humans affect the operation of fossil fuel plants?
-Fossil fuel plants would start shutting down in the first few hours due to the requirement of a steady supply of fuel and the involvement of people in their supply chains.
What is the potential longevity of nuclear reactors without human intervention?
-Nuclear reactors could theoretically continue running almost indefinitely in low-power mode due to the large amount of stored energy in uranium, but they would likely shut down automatically if something went wrong.
How long could diesel generators in remote communities continue to provide power?
-Diesel generators could run until their fuel tanks are empty, which could be anywhere from days to months.
What is the expected lifespan of geothermal plants without human maintenance?
-Geothermal plants might run for a few years without human intervention, but would eventually succumb to corrosion.
How long can wind turbines operate without maintenance before they stop working?
-Modern wind turbines are typically rated to run for 3 years without servicing, and some might operate for decades before their gearboxes seize up.
What is the expected operational duration of hydroelectric generators if the power grid is down?
-Hydroelectric generators, like those at the Hoover Dam, could continue to run on autopilot for several years even if the power grid is down.
How long would battery-powered lights last without any use?
-Battery-powered lights would be off in a few dozen years due to self-discharge, regardless of whether they are in use or not.
What is the potential longevity of solar power systems in remote locations?
-Solar panels, especially in dry locations with well-built electronics, could continue providing power for a century if kept free of dust by occasional breezes or rain.
What is Cherenkov radiation and how is it related to light sources?
-Cherenkov radiation is a blue glow emitted when radioactive particles travel through materials like water or glass, and it is seen in the cores of nuclear reactors.
Which could be the last surviving human light source, according to the script?
-Solar-powered lights in remote locations or the light from spent nuclear fuel in the form of Cherenkov radiation could be the last surviving human light sources.
Outlines
š” The Last Artificial Light: Power Grids and Nuclear Reactors
The script begins by addressing Alan's question about the longevity of artificial light sources if humans were to suddenly vanish. It explains that most lights would fail quickly due to the collapse of major power grids, which rely on human maintenance and fuel supply. Fossil fuel plants would shut down within hours, leading to cascading failures and blackouts. Nuclear reactors, while capable of long-term operation, would also shut down automatically if any issues arose, due to their safety protocols. The discussion highlights the interdependence of human activity and the functioning of power infrastructure.
š Alternative Power Sources and Their Durability
This paragraph explores alternative power sources that might outlast the main power grids. It mentions diesel generators in remote communities, which could run for days to months until their fuel is depleted. Off-grid generating stations, especially geothermal plants, are highlighted for their potential to operate without human intervention for several years, although they would eventually succumb to corrosion. The paragraph also discusses wind turbines, which are designed for minimal maintenance and could potentially operate for decades, and hydroelectric generators, which might continue working for several years even without human oversight.
š Battery-Powered and Solar-Powered Lights: The Lasting Light Sources
The script then delves into battery-powered lights, which would eventually fail due to self-discharge over a few dozen years. Solar power is presented as a more promising option, with off-grid solar-powered buildings and remote infrastructure potentially providing light for an extended period. Solar panels are durable and can last as long as the connected electronics, suggesting that with proper maintenance, they could provide power for a century. The paragraph concludes with a discussion of emergency call boxes, often found in remote locations and frequently solar-powered, which could be among the last light sources remaining.
ā¢ļø Radioactive Waste as a Long-Lasting Light Source
The final paragraph introduces a surprising contender for the last remaining light source: spent nuclear fuel. It explains that radioactive materials can emit light through a process called Cherenkov radiation, which is visible in the blue glow of nuclear reactor cores. The script discusses how radioactive waste products, such as cesium-137, are encapsulated in glass blocks that can glow in the dark for centuries due to their radioactivity. The glow would fade over time but remain blue, suggesting that the light from our most toxic waste could be the longest-lasting human-made light source.
Mindmap
Keywords
š”Power Grids
š”Fossil Fuel Plants
š”Nuclear Reactors
š”Geothermal Plants
š”Wind Power
š”Hydroelectric Power
š”Battery-Powered Lights
š”Solar Power
š”Cherenkov Radiation
š”Radioactive Waste
š”Half-Life
Highlights
Major power grids would go down relatively quickly without human intervention.
Fossil fuel plants require a steady supply of fuel and their supply chains involve human activities.
A rapid series of cascading failures would lead to a blackout of all major power grids.
Nuclear reactors could theoretically run indefinitely with enough fuel, but would likely shut down automatically upon failure.
Diesel generators in remote communities could run for days to months until fuel runs out.
Geothermal plants can operate for a significant time without human intervention but are susceptible to corrosion.
Wind turbines are designed for minimal maintenance and could potentially run for decades.
Hydroelectric generators, like the Hoover Dam, could continue running on autopilot for several years.
Battery-powered lights will turn off within a few dozen years due to self-discharge.
Solar power is a promising candidate for long-term lighting, with potential for a century of operation if maintained.
Spent nuclear fuel emits Cherenkov radiation, creating a blue glow that could last for centuries.
Cesium-137, a radioactive waste product, can glow blue for over two centuries due to its 30-year half-life.
The color of Cherenkov radiation depends on particle decay energy, not the amount of radiation.
Radioactive waste in concrete vaults could be a source of light for centuries.
Off-grid solar-powered infrastructure, such as emergency call boxes, could be among the last light sources.
The longevity of artificial light sources depends on their ability to operate independently of human maintenance.
The last surviving human light source could be solar-powered lights in remote locations or radioactive waste.
Transcripts
This question comes from Alan, who asks:
If every human somehow simplyĀ disappeared from the face of the earth,Ā Ā
how long would it be before the lastĀ artificial light source would go out?
We'll start with the obvious:Ā most lights wouldn't last long,Ā Ā
because the major power gridsĀ would go down relatively quickly.
Without people, there wouldĀ be less demand for power,Ā Ā
but our fridges and air conditionersĀ and lava lamps would still be running.
Fossil fuel plants, which supply theĀ vast majority of the world's electricity,Ā Ā
require a steady supply of fuel, and theirĀ supply chains do involve people doing things.
As coal and oil plants started shutting down inĀ the first few hours, other power sources would getĀ Ā
hit with the extra load. This kind of situationĀ is difficult to handle even with human guidance.
And the result would be a rapidĀ series of cascading failures,Ā Ā
leading to a blackout ofĀ all the major power grids.
Nuclear reactors, of course, donātĀ require a steady supply of fuel:Ā Ā
one reactor operator I talked to said thatĀ if their core settled into low-power mode,Ā Ā
it could continue running almost indefinitely;Ā a cube of uranium contains about six millionĀ Ā
times as much stored energy asĀ a similar-sized cube of coal.
Unfortunately, although there's enough fuel,Ā most nuclear reactors wouldn't keep runningĀ Ā
for long. As soon as something went wrong,Ā the core would go into automatic shutdown.
Every part of a reactor control system is designedĀ so that a failure causes it to rapidly shut down.
This would happen quickly; manyĀ things can trigger shutdown,Ā Ā
but the most likely culprit wouldĀ be the failure of the power grid.
However, plenty of light comes fromĀ sources not tied to the major powerĀ Ā
grids. Let's take a look at a few ofĀ those, and when each one might turn off.
Many remote communities, like those on far-flungĀ islands, get their power from diesel generators.
These can run until their tanks run out of fuel,Ā Ā
which in most cases could beĀ anywhere from days to months.
Off-grid generating stations that don't need aĀ Ā
human-provided fuel supplyĀ would be in better shape.
Geothermal plants can run for a fairĀ bit of time without human intervention.
According to the maintenance schedule for theĀ Svartsengi Island geothermal plant in Iceland,Ā Ā
every six months the operators must change theĀ Ā
gearbox oil and re-grease allĀ electric motors and couplings.
Without humans to perform theseĀ sorts of maintenance procedures,Ā Ā
some plants might run for a few years, butĀ they'd all succumb to corrosion eventually.
Lights relying on wind powerĀ would last a bit longer. WindĀ Ā
turbines are designed so that theyĀ don't need constant maintenance,Ā Ā
for the simple reason that there are aĀ lot of them and they're a pain to climb.
The Gedser Wind Turbine inĀ Denmark was installed in theĀ Ā
late 1950s and it generated powerĀ for 11 years without maintenance.
Modern turbines are typically ratedĀ to run for 3 years without servicing,Ā Ā
and there are no doubt someĀ which would run for decades,Ā Ā
and one of them would probably haveĀ at least a status LED in it somewhere.
Eventually, most of the wind turbinesĀ would be stopped by the same thing thatĀ Ā
would destroy the geothermal plants:Ā Their gearboxes would seize up.
Generators that convert falling waterĀ into electricity will also keep working.
An operator at the Hoover Dam onceĀ said that if everyone walked out,Ā Ā
the facility would continue to runĀ on autopilot for several years.
Though if the power grid is down, allĀ that electricity would have nowhere toĀ Ā
go. In the end the dam would probablyĀ succumb to clogged intakes or the sameĀ Ā
kind of mechanical failure that hit theĀ wind turbines and geothermal plants.
Battery-powered lights wouldnāt fare muchĀ better, and will all be off in a few dozen years.
Even without anything using their power,Ā batteries eventually self-discharge.
Some types last longer than others, butĀ even batteries advertised as having longĀ Ā
shelf lives typically only holdĀ their charge for a decade or two.
Solar power is probably the most promisingĀ candidate. There are many off-grid solar-poweredĀ Ā
buildings, weather stations, and other remoteĀ infrastructure around the world. Emergency callĀ Ā
boxes, often found along the side of the road inĀ remote locations, are frequently solar-powered.
They usually have lights on them, which provideĀ illumination every night. Like wind turbines,Ā Ā
they're hard to service, andĀ they last for a long time.
Solar panels will generally last as longĀ as the electronics connected to them,Ā Ā
and as long as the panels areĀ kept free of dust and debris.
The wires and circuits will eventually succumbĀ to corrosion, but solar panels in a dry place,Ā Ā
with well-built electronics, could easilyĀ continue providing power for a century ifĀ Ā
they're kept free of dust by occasionalĀ breezes or rain on the exposed panels.
If we follow a strict definition ofĀ lighting, solar-powered lights inĀ Ā
remote locations could conceivably beĀ the last surviving human light source.
But there's another contender, andĀ it's a weird one: spent nuclear fuel.
Contrary to popular portrayals,Ā radioactivity isn't usually visible,Ā Ā
which is part of why we need warning signsĀ around areas with radioactive materials or waste.
Sure, watch dials used to be coated inĀ small amounts of radium to help themĀ Ā
glow in the dark, but the glow didn'tĀ come from the radioactivity itself.
It came from the phosphorescent paint on top ofĀ the radium, which glows when itās irradiated.
Once the phosphorescent paint breaks down,Ā Ā
the watch dials are stillĀ radioactive, but no longer glow.Ā
Watch dials, however, are not ourĀ only radioactive light source.
When radioactive particles travelĀ through materials like water or glass,Ā Ā
they can emit light throughĀ a sort of optical sonic boom.
This light is called Cherenkov radiation,Ā and it's seen in the distinctive blueĀ Ā
glow of nuclear reactor cores. Some of ourĀ radioactive waste products, such as cesium-137,Ā Ā
are melted and mixed with glass, which coolsĀ into a solid block before being wrapped inĀ Ā
more shielding for transport and storage. And in the dark, these glass blocks glow blue.
Cesium-137 has a half-life of 30 years,Ā which means that two centuries later,Ā Ā
the blocks will still be glowing withĀ 1% of their original radioactivity.
Since the color of the light depends only onĀ the particle decay energy, and not the amountĀ Ā
of radiation, it will fade in brightnessĀ over time but keep that same blue color.
And thus, we arrive at ourĀ answer: Centuries from now,Ā Ā
deep in concrete vaults, the light fromĀ our most toxic waste will still be shining.
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