If everyone in the world turned on the lights at the same time, what would happen?

If everyone in the world turned on their lights at the same time, it would create a huge surge in electricity demand, which power plants would need to respond to quickly to avoid a system crash.
The impact of this sudden demand spike would be mitigated by the fact that most countries have separate grids or regional grids, allowing them to disconnect and reconnect quickly if needed.
LED light bulbs, which are now widely used, require significantly less power from the grid compared to traditional incandescent bulbs, reducing the strain on the electrical system.
A global simultaneous lighting event would also lead to a dramatic increase in sky glow, making it difficult for people to see stars at night and potentially harming human health and wildlife.
Overall, while turning on all lights at once might seem like a simple idea, it would have significant effects on the electrical grid, power consumption, and our environment, highlighting the importance of responsible energy use and sustainable lighting practices.

This combined satellite image shows how Earth's city lights would look if it were night around the entire planet at once. White areas of light show cities with larger populations. NASA/Goddard Space Flight Center

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If everyone in the world turned on the lights at the same time, what would happen? – Clara

The biggest effect of everyone turning lights on at once would be a surge in demand for electricity, which most people worldwide use to operate their lights.

Electricity is a form of energy that is made using many different fuels. Power plants are electricity factories that generate electricity from sources including coal, natural gas, uranium, water, wind and sunlight. Then they feed it into a network of transmission and distribution wires called the power grid, which delivers the electricity to homes and businesses.

To keep the grid stable, electricity must be supplied on demand. When someone turns on a light, they draw power from the grid. A generator must immediately feed an equal amount of power into the grid. If the system gets out of balance, even for a few seconds, a blackout can happen.

System operators use sensors and sophisticated computers to track electricity demand so they can adjust power production up or down as needed. Total power demand, which is called load, varies a lot from hour to hour and season to season. To see why, think of how much electricity your home uses during the day compared with the middle of the night, or during a summer heat wave compared with a cool fall day.

Charts showing 2019 U.S. electricity consumption nationwide, with seasonal and weekly patterns. — These images show patterns of electricity use. Through the year (large graph), people use more electricity for summer cooling and winter heating than in spring and fall. Weekly, consumption drops on weekends, when many businesses are closed.
U.S. Energy Information Administration, Hourly Electric Grid Monitor

Meeting a demand spike

If everyone turned on their lights all at once around the world, they would create a huge, sudden demand for electricity. Power plants would have to ramp up generation very quickly to avoid a system crash. But these plants respond to changing demand in different ways.

Coal and nuclear plants can provide lots of electricity at almost any time, but if they’re shut off for maintenance or they malfunction, they can take many hours to bring back online. They also respond slowly to load changes.

Power plants that burn natural gas can respond more quickly to changing load, so they typically are the tool of choice to cover periods when the most electricity is needed, such as hot, sunny summer afternoons.

Renewable electricity sources such as solar, wind and water power produce less pollution but are not as easily controlled. That’s because the wind doesn’t always blow at the same speed, nor is every day equally sunny in most places.

Grid managers use large batteries to smooth out power flow as demand rises and falls. But it’s not yet possible to store enough electricity in batteries to run an entire town or city. The batteries would be too expensive and would drain too quickly.

Some hydropower operators can pump water into lakes during periods of low demand, then release that water to generate electricity when demand is high by running it through machines called turbines.

Fortunately, if everyone turned on their lights at once, two things would work to prevent a total system crash. First, there is no single worldwide power grid. Most countries have their own grids, or multiple regional grids.

Neighboring grids, such as those in the United States and Canada, are typically connected so that countries can move electricity across their borders. But they can disconnect quickly, so even if the power went out in some areas, it’s unlikely that all the grids would crash at once.

Second, over the past 20 years, light bulbs called LEDs have replaced many older electric lights. LEDs operate differently from earlier light bulb designs and produce much more light from each unit of electricity, so they require much less power from the grid.

According to the U.S. Department of Energy, using LED bulbs saves the average household about US$225 yearly. As of 2020, nearly half of all U.S. homes used LEDS for most or all of their lighting needs.

LEDs, or light–emitting diodes, are semiconductor devices called transistors that generate light with almost no heat.

More glare, fewer stars

Beyond powering lights, it’s also important to think about where all that light would go. A big spike in lighting would dramatically increase sky glow − the hazy brightness that hangs over towns and cities at night.

Sky glow happens when light reflects off haze and dust particles in the air, creating a diffuse glow that washes out the night sky. Light is very difficult to control: For example, it can reflect off bright surfaces, such as car windows and concrete.

Lighting is often overused at night. Think of empty office buildings where lights burn around the clock, or street lights that shine upward instead of down on streets and sidewalks where illumination is needed.

A Joshua tree silhouetted against a starry night sky, with orange glow from artificial lights on the horizon. — Night sky in California’s Joshua Tree National Park, with light pollution from artificial lights in the Coachella Valley.
NPS/Lian Law

Even well-designed lighting systems can add to the problem, making cities and highways visible from space and the stars invisible from the ground. This light pollution
can harm human health by interfering with our bodies’ natural sleep and waking cycles. It can also disorient insects, birds, sea turtles and other wildlife.

If people worldwide all turned on their lights at once, we’d see a modest increase in power consumption, but a lot more sky glow and no stars in the night sky. That’s not a very enticing view.

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Harold Wallace is a member of the Illuminating Engineering Society.

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Q. What would happen if everyone in the world turned on their lights at the same time?

A. The biggest effect would be a surge in demand for electricity, which could lead to a system crash if not managed properly.

Q. How do power plants respond to changing electricity demand?

A. Power plants that burn natural gas can respond more quickly to changing load, while coal and nuclear plants respond slowly due to their shutdown times.

Q. Can the world’s grids handle a sudden surge in electricity demand from everyone turning on their lights at once?

A. No, but there are two factors that would prevent a total system crash: neighboring grids can disconnect quickly, and most countries have multiple regional grids.

Q. What is sky glow, and how does it affect the environment?

A. Sky glow is the hazy brightness that hangs over towns and cities at night due to light reflecting off haze and dust particles in the air, which can harm human health and wildlife.

Q. Why are LED bulbs more energy-efficient than traditional light bulbs?

A. LEDs operate differently from earlier light bulb designs and produce much more light from each unit of electricity, requiring less power from the grid.

Q. How does lighting affect the night sky?

A. Lighting is often overused at night, causing light pollution that can harm human health by interfering with our bodies’ natural sleep-waking cycles and disorienting wildlife.

Q. Can batteries be used to store enough electricity to run an entire town or city?

A. No, it’s not yet possible due to the high cost and limited capacity of current battery technology.

Q. What is the impact of lighting on human health?

A. Excessive lighting can interfere with our bodies’ natural sleep-waking cycles and disrupt our circadian rhythms, leading to negative effects on our overall health.

Q. How much energy do LED bulbs save households each year?

A. According to the U.S. Department of Energy, using LED bulbs saves the average household around $225 yearly.