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0 / 29 Fotos
Within a year
- The Earth travels around the Sun over the course of 365 days, six hours, and nine minutes. During this time, seasons change and the direction of the planet influences the climate that takes place on the surface.
© Shutterstock
1 / 29 Fotos
Earth’s tilted axis
- Earth’s axis is perpetually tilted at a 23.4-degree angle, which influences the way in which seasons change. Sunlight is directed unevenly across the surface of the globe, with some parts of the planet receiving more light compared to others during certain times of the year.
© Getty Images
2 / 29 Fotos
Solstices
- The Earth’s tilt also creates the solstices, where one hemisphere experiences its shortest daylight hours while the other enjoys its longest. If the Sun were mapped throughout the year based on its position in the sky at the same time every day, its path would look like an elongated figure eight. Its high and low are where the summer and winter solstices occur, respectively.
© Shutterstock
3 / 29 Fotos
Earth's elliptical orbit
- Earth’s orbit around the Sun is not a perfect circle; it’s elliptical. This means that the planet is closer to the sun during part of the year (perihelion) and farther away in another part (aphelion), influencing seasonal temperatures.
© Shutterstock
4 / 29 Fotos
Northern Hemisphere’s shortest daylight
- The northern winter solstice occurs annually between December 21 and 23. While marking the year's shortest day, this event does not coincide with the coldest period, which typically arrives several weeks later.
© Getty Images
5 / 29 Fotos
Southern Hemisphere’s mirror image
- In the Southern Hemisphere, the winter solstice arrives around June 20 to 22, with similar phenomena occurring. Despite having the shortest day, the coldest temperatures are delayed. So what is the reason for this?
© Getty Images
6 / 29 Fotos
Sunlight’s role in seasonal warmth
- Earth derives most of its warmth from sunlight, which peaks during solstices. But temperatures don’t immediately reflect these shifts in solar energy, and there is a lag between the solstices and actual seasonal temperatures. This is known as seasonal lag, when summer temperatures get hotter and winter gets colder, both only after the solstice.
© Shutterstock
7 / 29 Fotos
Seasonal lag
- Seasonal lag, which is the delay between solstices and temperature extremes, arises because the Earth’s surfaces (land, water, and atmosphere) take time to cool down or warm up.
© Getty Images
8 / 29 Fotos
Land’s slow cooling process
- Physical objects like soil and rocks retain heat from the previous months. In winter, this means the ground holds onto warmth from fall, which delays the onset of the coldest temperatures after the solstice.
© Shutterstock
9 / 29 Fotos
Water’s high heat capacity
- Water requires significantly more energy to change temperature compared to land. This property moderates temperature changes, particularly in regions near oceans, contributing to delayed seasonal temperature peaks or valleys.
© Shutterstock
10 / 29 Fotos
Northern Hemisphere’s coldest month
- In the Northern Hemisphere, the coldest days typically occur in mid-January, well after the winter solstice. By this point, the ground and water have frozen solid and they stop releasing heat into the air.
© Shutterstock
11 / 29 Fotos
Summer solstice’s temperature lag
- Similarly, the longest day of the year, the summer solstice, does not coincide with the hottest temperatures. Warmth builds up gradually, with peak summer heat arriving only weeks later.
© Shutterstock
12 / 29 Fotos
Global examples
- The Mojave Desert, as an example, experiences its highest temperatures in late July, not at the solstice a month earlier. Likewise, regions like Florida’s Gulf Coast can find their hottest periods delayed until August.
© Getty Images
13 / 29 Fotos
Latitude and lag correlation
- Regions closer to the poles experience more pronounced seasonal lag due to their extended nights and slower heat dissipation. Conversely, equatorial areas exhibit less lag due to relatively consistent sunlight throughout the year.
© Getty Images
14 / 29 Fotos
The Pacific
- The Pacific Ocean, the largest on the planet, also has a major effect on heat retention. Coastal regions along the ocean experience milder winters due to the ocean’s moderating effect, much more than can be found with inland areas.
© Getty Images
15 / 29 Fotos
Ocean circulation
- Ocean currents also play a part, as they distribute heat across vast distances and smooth out temperature extremes. Even during long winter nights, warm currents can prevent immediate cooling, which delays the arrival of the coldest days in coastal regions.
© Shutterstock
16 / 29 Fotos
Jet stream
- Even the planet’s jet stream plays a part in temperature differences like this. The jet stream, which is the high-altitude wind current that flows from west to east, divides the southern air from the northern air. After the Northern Hemisphere’s winter solstice, this jet stream shifts further south, leaving only cold air behind.
© Shutterstock
17 / 29 Fotos
Albedo effect
- Interestingly, the ice of the polar regions is a significant factor in the seasonal lags of both hemispheres. This is because of what is known as the albedo effect, which is when different parts of the planet reflect more or less of the Sun’s energy than other parts.
© Shutterstock
18 / 29 Fotos
Icy landscape
- Snow and ice have a high albedo effect, and so they reflect significant solar radiation. By the time the winter solstice arrives, much of the North or South Pole (depending on the hemisphere) is frozen and doesn’t capture any more heat. Its remaining warmth dissipates into the atmosphere.
© Shutterstock
19 / 29 Fotos
Leafless foliage
- During winter, deciduous trees and plants (which are those that do not stay evergreen) lose all of their leaves during winter. Without this mass, foliage is unable to create and retain heat, which contributes to the sudden drop in temperatures after the winter solstice.
© Getty Images
20 / 29 Fotos
Urban heat
- Cities, with their concrete and asphalt surfaces, absorb and retain heat differently than natural landscapes. Urban areas may experience unique lags, with delayed cooling in winter and prolonged heat during summer.
© Getty Images
21 / 29 Fotos
Mountainous regions
- Much like cities, mountainous areas also exhibit unique seasonal lags due to their elevation. Higher altitudes cool down and warm up faster than lowlands, which reduces the lag, while valleys often retain heat longer and extend the seasonal delay.
© Shutterstock
22 / 29 Fotos
Atmospheric heat
- Earth’s atmosphere traps heat from solar radiation, adding another layer of delay in seasonal cooling or warming. This greenhouse effect further contributes to the mismatch between solstices and temperature peaks.
© Shutterstock
23 / 29 Fotos
Climate change
- The increased amount of carbon being pumped into the atmosphere has been known to exacerbate the greenhouse effect. Studies have shown that heat is becoming ever more trapped in the planet, contributing to global warming and making temperature extremes far more pronounced.
© Getty Images
24 / 29 Fotos
Reduced ice - Scientists have warned that global warming will result in significant melting of the ice and snow in polar regions. As a result, solar radiation will not be reflected as much, temperatures will rise drastically, and seasonal lag will be less obvious.
© Getty Images
25 / 29 Fotos
Human adaptation
- Understanding seasonal lag helps communities prepare for weather extremes. Farmers, urban planners, and energy sectors use this knowledge to time activities and resources for peak cold or heat, which improves both efficiency and safety.
© Getty Images
26 / 29 Fotos
Ecological cycles
- Ecosystems around the world are tuned to seasonal lags, with animals and plants adapting their life cycles to temperature changes rather than solstice dates. This synchronization ensures survival in diverse environments.
© Getty Images
27 / 29 Fotos
The wonder of Earth’s heat balance
- The interplay of sunlight, heat retention, and seasonal lag truly highlights the wonder of Earth’s natural balancing act. These delays offer much insight into how the planet manages temperature extremes, and how these can be predicted in the future. Sources: (Live Science) (Britannica) (National Post)
© Shutterstock
28 / 29 Fotos
© Getty Images
0 / 29 Fotos
Within a year
- The Earth travels around the Sun over the course of 365 days, six hours, and nine minutes. During this time, seasons change and the direction of the planet influences the climate that takes place on the surface.
© Shutterstock
1 / 29 Fotos
Earth’s tilted axis
- Earth’s axis is perpetually tilted at a 23.4-degree angle, which influences the way in which seasons change. Sunlight is directed unevenly across the surface of the globe, with some parts of the planet receiving more light compared to others during certain times of the year.
© Getty Images
2 / 29 Fotos
Solstices
- The Earth’s tilt also creates the solstices, where one hemisphere experiences its shortest daylight hours while the other enjoys its longest. If the Sun were mapped throughout the year based on its position in the sky at the same time every day, its path would look like an elongated figure eight. Its high and low are where the summer and winter solstices occur, respectively.
© Shutterstock
3 / 29 Fotos
Earth's elliptical orbit
- Earth’s orbit around the Sun is not a perfect circle; it’s elliptical. This means that the planet is closer to the sun during part of the year (perihelion) and farther away in another part (aphelion), influencing seasonal temperatures.
© Shutterstock
4 / 29 Fotos
Northern Hemisphere’s shortest daylight
- The northern winter solstice occurs annually between December 21 and 23. While marking the year's shortest day, this event does not coincide with the coldest period, which typically arrives several weeks later.
© Getty Images
5 / 29 Fotos
Southern Hemisphere’s mirror image
- In the Southern Hemisphere, the winter solstice arrives around June 20 to 22, with similar phenomena occurring. Despite having the shortest day, the coldest temperatures are delayed. So what is the reason for this?
© Getty Images
6 / 29 Fotos
Sunlight’s role in seasonal warmth
- Earth derives most of its warmth from sunlight, which peaks during solstices. But temperatures don’t immediately reflect these shifts in solar energy, and there is a lag between the solstices and actual seasonal temperatures. This is known as seasonal lag, when summer temperatures get hotter and winter gets colder, both only after the solstice.
© Shutterstock
7 / 29 Fotos
Seasonal lag
- Seasonal lag, which is the delay between solstices and temperature extremes, arises because the Earth’s surfaces (land, water, and atmosphere) take time to cool down or warm up.
© Getty Images
8 / 29 Fotos
Land’s slow cooling process
- Physical objects like soil and rocks retain heat from the previous months. In winter, this means the ground holds onto warmth from fall, which delays the onset of the coldest temperatures after the solstice.
© Shutterstock
9 / 29 Fotos
Water’s high heat capacity
- Water requires significantly more energy to change temperature compared to land. This property moderates temperature changes, particularly in regions near oceans, contributing to delayed seasonal temperature peaks or valleys.
© Shutterstock
10 / 29 Fotos
Northern Hemisphere’s coldest month
- In the Northern Hemisphere, the coldest days typically occur in mid-January, well after the winter solstice. By this point, the ground and water have frozen solid and they stop releasing heat into the air.
© Shutterstock
11 / 29 Fotos
Summer solstice’s temperature lag
- Similarly, the longest day of the year, the summer solstice, does not coincide with the hottest temperatures. Warmth builds up gradually, with peak summer heat arriving only weeks later.
© Shutterstock
12 / 29 Fotos
Global examples
- The Mojave Desert, as an example, experiences its highest temperatures in late July, not at the solstice a month earlier. Likewise, regions like Florida’s Gulf Coast can find their hottest periods delayed until August.
© Getty Images
13 / 29 Fotos
Latitude and lag correlation
- Regions closer to the poles experience more pronounced seasonal lag due to their extended nights and slower heat dissipation. Conversely, equatorial areas exhibit less lag due to relatively consistent sunlight throughout the year.
© Getty Images
14 / 29 Fotos
The Pacific
- The Pacific Ocean, the largest on the planet, also has a major effect on heat retention. Coastal regions along the ocean experience milder winters due to the ocean’s moderating effect, much more than can be found with inland areas.
© Getty Images
15 / 29 Fotos
Ocean circulation
- Ocean currents also play a part, as they distribute heat across vast distances and smooth out temperature extremes. Even during long winter nights, warm currents can prevent immediate cooling, which delays the arrival of the coldest days in coastal regions.
© Shutterstock
16 / 29 Fotos
Jet stream
- Even the planet’s jet stream plays a part in temperature differences like this. The jet stream, which is the high-altitude wind current that flows from west to east, divides the southern air from the northern air. After the Northern Hemisphere’s winter solstice, this jet stream shifts further south, leaving only cold air behind.
© Shutterstock
17 / 29 Fotos
Albedo effect
- Interestingly, the ice of the polar regions is a significant factor in the seasonal lags of both hemispheres. This is because of what is known as the albedo effect, which is when different parts of the planet reflect more or less of the Sun’s energy than other parts.
© Shutterstock
18 / 29 Fotos
Icy landscape
- Snow and ice have a high albedo effect, and so they reflect significant solar radiation. By the time the winter solstice arrives, much of the North or South Pole (depending on the hemisphere) is frozen and doesn’t capture any more heat. Its remaining warmth dissipates into the atmosphere.
© Shutterstock
19 / 29 Fotos
Leafless foliage
- During winter, deciduous trees and plants (which are those that do not stay evergreen) lose all of their leaves during winter. Without this mass, foliage is unable to create and retain heat, which contributes to the sudden drop in temperatures after the winter solstice.
© Getty Images
20 / 29 Fotos
Urban heat
- Cities, with their concrete and asphalt surfaces, absorb and retain heat differently than natural landscapes. Urban areas may experience unique lags, with delayed cooling in winter and prolonged heat during summer.
© Getty Images
21 / 29 Fotos
Mountainous regions
- Much like cities, mountainous areas also exhibit unique seasonal lags due to their elevation. Higher altitudes cool down and warm up faster than lowlands, which reduces the lag, while valleys often retain heat longer and extend the seasonal delay.
© Shutterstock
22 / 29 Fotos
Atmospheric heat
- Earth’s atmosphere traps heat from solar radiation, adding another layer of delay in seasonal cooling or warming. This greenhouse effect further contributes to the mismatch between solstices and temperature peaks.
© Shutterstock
23 / 29 Fotos
Climate change
- The increased amount of carbon being pumped into the atmosphere has been known to exacerbate the greenhouse effect. Studies have shown that heat is becoming ever more trapped in the planet, contributing to global warming and making temperature extremes far more pronounced.
© Getty Images
24 / 29 Fotos
Reduced ice - Scientists have warned that global warming will result in significant melting of the ice and snow in polar regions. As a result, solar radiation will not be reflected as much, temperatures will rise drastically, and seasonal lag will be less obvious.
© Getty Images
25 / 29 Fotos
Human adaptation
- Understanding seasonal lag helps communities prepare for weather extremes. Farmers, urban planners, and energy sectors use this knowledge to time activities and resources for peak cold or heat, which improves both efficiency and safety.
© Getty Images
26 / 29 Fotos
Ecological cycles
- Ecosystems around the world are tuned to seasonal lags, with animals and plants adapting their life cycles to temperature changes rather than solstice dates. This synchronization ensures survival in diverse environments.
© Getty Images
27 / 29 Fotos
The wonder of Earth’s heat balance
- The interplay of sunlight, heat retention, and seasonal lag truly highlights the wonder of Earth’s natural balancing act. These delays offer much insight into how the planet manages temperature extremes, and how these can be predicted in the future. Sources: (Live Science) (Britannica) (National Post)
© Shutterstock
28 / 29 Fotos
Why isn't the darkest time of year also the coldest?
The solstices aren't the coldest or hottest times of the year
© Shutterstock
When people think about the coldest or hottest days of the year, they might instinctively link them to the solstices—the shortest and longest days of the year. After all, the winter solstice marks the day with the least sunlight, while the summer solstice boasts the longest day. Yet, intriguingly, the coldest days of winter often arrive weeks after the winter solstice, and the hottest days of summer don’t coincide with the solstice either.
This curious mismatch raises the question: why isn’t the darkest time of the year also the coldest? And why does the peak of summer heat lag behind the longest day of the year? The answer lies somewhere in the way the planet is designed and how it moves around the Sun. Click through this gallery to see exactly what science has to say.
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