Atlantic Niña on the verge of developing. Here’s why we should pay attention

This article was originally published on climate.gov on August 14th, 2024. Written by: Franz Philip Tuchen

If you’re a regular reader of Climate.gov’s ENSO blog, then you know that scientists have been carefully observing how the Pacific Ocean is changing from El Niño’s warmer-than-average conditions earlier this year to expected cooler-than-average La Niña conditions by late summer. But as it happens, something similar might be cooking this summer in the Atlantic Ocean. 

Much of the North Atlantic has been extremely warm so far this year. In contrast, since the beginning of June, sea surface temperature (SST) in the central equatorial Atlantic has been 0.5–1.0 degrees Celsius (0.9–1.8 degrees Fahrenheit) colder than average for this time of the year. If these cold conditions persist to the end of August, a phenomenon known as Atlantic Niña may be declared. But what is Atlantic Niña, and what could it mean for weather and climate around the tropical Atlantic? 

Average sea surface temperatures in June-July 2024 compared to the 1982-2023 average (with any long-term warming signal removed), showing the cool waters along the equator that might become an Atlantic Niña event. The black box outlines the specific area used for monitoring Atlantic Niños and Niñas. NOAA Climate.gov image, adapted from original by Franz Philip Tuchen.

What is Atlantic Niña (and Niño)?

Atlantic Niña is the cold phase of a natural climate pattern we call the Atlantic zonal mode. (Zonal means “along lines of latitude.”) This pattern, just like ENSO (El Niño-Southern Oscillation), swings between cold and warm phases every few years. Typically, sea surface temperatures in the eastern equatorial Atlantic have a somewhat surprising seasonal cycle. The warmest waters of the year occur in spring, while the coolest waters of the year—below 25 degrees Celsius, or 77 degrees Fahrenheit—occur from July to August.

Monthly average sea surface temperature in the eastern equatorial Atlantic between 1982-2023 (black) and during 2024 (red and blue markers). Red colors indicate warmer than normal waters, while blue colors indicate colder than normal waters. The gray area represents the ±0.5 degrees Celsius (±0.9 degrees Fahrenheit) threshold that needs to be exceeded in order to qualify as an Atlantic Niño/Niña. Image by Franz Philip Tuchen.

This summer cooling is because of winds that act on the ocean surface. Earth has a year-round rainfall band around the tropics. Driven by stronger solar heating, this rainfall band migrates northward during the summer in the Northern Hemisphere. The regular rainstorms draw in air from the southeast over the equatorial Atlantic. 

These steady southeasterly winds are strong enough to drag surface waters away from the equator, which brings relatively cold water from deeper ocean layers to the surface. This process, known as equatorial upwelling, forms a tongue of relatively cold water along the equatorial Atlantic during the summer months. 

July average sea surface temperatures in the central Atlantic Ocean, showing the tongue of relatively cool water—relative to the rest of the tropical North Atlantic—that develops along the equator in the east. NOAA Climate.gov image, based on data from Coral Reef Watch project. Click here for explanation of the CoralTemp climatology. 

However, every few years this cold tongue is substantially warmer or colder than average due to swings of the Atlantic zonal mode. Cold events are referred to as Atlantic Niñas; warm events are referred to as Atlantic Niños. The exact definitions vary, but typically, 3-month averaged sea surface temperature anomalies in the eastern equatorial Atlantic have to exceed ±0.5 degrees Celsius (± 0.9 degrees Fahrenheit) for at least two overlapping seasons in order to qualify as an Atlantic Niño or Niña. 

2024 to date

2024 began with extremely warm sea surface temperatures in the eastern equatorial Atlantic during February to March, when temperatures exceeded 30 degrees Celsius (86 degrees Fahrenheit). This was the strongest warm event since 1982. Equally remarkable was the rapid transition from warm to cold SST anomalies. Never before has the eastern equatorial Atlantic swung so quickly from one to another extreme event.

(left) Monthly sea surface temperatures compared to average in the key Atlantic Niño/Niña monitoring region between January 1982 and July 2024 (with any long-term warming signal removed). The 2024 Atlantic Niño was the strongest (highest red bar) since 1982. (right) Temperatures in the eastern equatorial Atlantic were just shy of the Niña threshold in July 2024.

Surprisingly, the observed cold anomalies in the eastern equatorial Atlantic during June/July 2024 coincide with a weakening of the southeasterly trade winds near the equator. Relaxed equatorial winds are usually associated with reduced upwelling and warm anomalies. Only south of 5 degrees South were the southeasterly trade winds stronger than usual. As of now, these atmosphere-ocean conditions, apparently unfavorable for the developing Atlantic Niña event, are quite perplexing. We will need to dig deeper to reveal the exact causes of this seemingly unusual event. 

0.5 degrees Celsius? Why does it matter? 

One might think that a temperature difference of ±0.5 degrees Celsius (± 0.9 degrees Fahrenheit) in the tropical Atlantic does not seem like a big deal, but this difference can have a huge impact on rainfall over the surrounding continents. Reduced rainfall over the Sahel region, increased rainfall over the Gulf of Guinea, and seasonal shifts of the rainy season in northeastern South America have all been attributed to Atlantic Niño events. 

Plus, Atlantic Niños have been shown to increase the likelihood of powerful hurricanes developing near the Cape Verde islands. NOAA’s seasonal forecast of above-normal 2024 hurricane activity is based on expected La Niña conditions in the equatorial Pacific and warm ocean temperatures in the tropical North Atlantic. It will be interesting to monitor whether this Atlantic Niña fully develops, and if so, whether it has a dampening effect on hurricane activity as the season progresses. 

We’ll be keeping an eye on this event in coming weeks, and will have a follow-up post later this month letting you know whether an Atlantic Niña fully developed. We’ll also go over some of the hypotheses scientists have for what triggers these events and how their frequency might be affected over the coming century by human-caused global warming. Stay tuned!


Referencias

Bjerknes, J. (1969): Atmospheric teleconnections from the equatorial Pacific. Monthly Weather Review, 97(3), 163-172, https://doi.org/10.1175/1520-0493(1969)097<0163:ATFTEP>2.3.CO;2

Chang, P., Fang, Y., Saravan, R., Ju, L., & Seidel, H. (2006): The cause of the fragile relationship between the Pacific El Niño and the Atlantic Niño. Nature, 443, 324-328, https://doi.org/10.1038/nature05053 

Crespo, L. R., Prigent, A., Keenlyside, N. , Koseki, S., Svendsen, L., Richter, I., & Sánchez-Gómez, E. (2022): Weakening of the Atlantic Niño variability under global warming. Nature Climate Change, 12, 822-827, https://doi.org/10.1038/s41558-022-01453-y 

Foltz, G. R., & McPhaden, M. J. (2010): Interaction between the Atlantic meridional and Niño modes. Geophysical Research Letters, 37, L18604, https://doi.org/10.1029/2010GL044001 

Keenlyside, N. S., & Latif, M. (2007): Understanding Equatorial Atlantic Interannual Variability. Journal of Climate, 20(1), 131-142, https://doi.org/10.1175/JCLI3992.1 

Kim, D., Lee, S.-K., Lopez, H., Foltz, G. R., Wen, C., West, R., & Dunion, J. (2023): Increase in Cape Verde hurricanes during Atlantic Niño. Nature Communications, 14, 3704, https://doi.org/10.1038/s41467-023-39467-5

Lee, S.-K., Lopez, H., Tuchen, F. P., Kim, D., Foltz, G. R., & Wittenberg, A. T. (2023): On the Genesis of the 2021 Atlantic Niño. Geophysical Research Letters, 50, e2023GL104452, https://doi.org/10.1029/2023GL104452 

Lübbecke, J. F., Rodríguez-Fonseca, B., Richter, I., Martín-Rey, M., Losada, T., Polo, I., & Keenlyside, N. S. (2018): Equatorial Atlantic variability – Modes, mechanisms, and global teleconnections. WIREs Climate Change, 9:e527, https://doi.org/10.1002/wcc.527 

Nnamchi, H. C., Li, J., Kucharski, F., Kang, I.-S., Keenlyside, N. S., Chang, P., & Farneti, R. (2015): Thermodynamic controls of the Atlantic Niño. Nature Communications, 6, 8895, https://doi.org/10.1038/ncomms9895 

Prigent, A., Lübbecke, J. F., Bayr, T., Latif, M., & Wengel, C. (2020): Weakened SST variability in the tropical Atlantic Ocean since 2000. Climate Dynamics, 54, 2731-2744, https://doi.org/10.1007/s00382-020-05138-0 

Richter, I., Behera, S. K., Masumoto, Y., Taguchi, B., Sasaki, H., & Yamagata, T. (2012): Multiple causes of interannual sea surface temperature variability in the equatorial Atlantic Ocean. Nature Geoscience, 6, 43-47, https://doi.org/10.1038/NGEO1660 

Richter, I., Tokinaga, H., & Okumura, Y. M. (2022): The Extraordinary Equatorial Atlantic Warming in Late 2019. Geophysical Research Letters, 49, e2021GL095918, https://doi.org/10.1029/2021GL095918 

Tokinaga, H., Richter, I., & Kosaka, Y. (2019): ENSO Influence on the Atlantic Niño, Revisited: Multi-Year versus Single-Year ENSO Events. Journal of Climate, 32(14), 4585-4600, https://doi.org/10.1175/JCLI-D-18-0683.1 

Tuchen, F. P., Perez, R. C., Foltz, G. R., Brandt, P., Subramaniam, A., Lee, S.-K., Lumpkin, R., & Hummels, R. (2024): Modulation of Equatorial Currents and Tropical Instability Waves During the 2021 Atlantic Niño. Journal of Geophysical Research: Oceans, 129, e2023JC020431, https://doi.org/10.1029/2023JC020431 

Vallès-Casanova, I., Lee, S.-K., Foltz, G. R., & Pelegri, J. L. (2020): On the Spatiotemporal Diversity of Atlantic Niño and Associated Rainfall Variability Over West Africa and South America. Geophysical Research Letters, 47, e2020GL087108, https://doi.org/10.1029/2020GL087108