{"id":906526,"date":"2026-05-17T10:19:21","date_gmt":"2026-05-17T15:19:21","guid":{"rendered":"https:\/\/newsycanuse.com\/index.php\/2026\/05\/17\/the-next-el-nino-could-lock-earth-into-a-hotter-climate\/"},"modified":"2026-05-17T10:19:21","modified_gmt":"2026-05-17T15:19:21","slug":"the-next-el-nino-could-lock-earth-into-a-hotter-climate","status":"publish","type":"post","link":"https:\/\/newsycanuse.com\/index.php\/2026\/05\/17\/the-next-el-nino-could-lock-earth-into-a-hotter-climate\/","title":{"rendered":"The Next El Ni\u00f1o Could Lock Earth Into a Hotter Climate"},"content":{"rendered":"
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The Pacific Ocean is a giant climate cauldron, with a powerful heat engine that affects storms, fisheries and rainfall patterns half a world away, and scientists are watching closely to see if it\u2019s about to boil over.\u00a0<\/p>\n

Their projections<\/a> suggest the tropical Pacific is simmering toward a strong El Ni\u00f1o<\/a>, the warm phase of an ocean-atmosphere cycle that can intensify and shift those impacts.<\/p>\n

In a world already superheated by greenhouse gases, a strong El Ni\u00f1o during the next 12 to 18 months could permanently push the planet\u2019s average annual temperature past the 1.5 degrees Celsius warming threshold enshrined in scientific documents<\/a> and political agreements<\/a> as a turning point for potentially irreversible climate impacts.<\/p>\n

Climate scientists also recently published a study showing that strong El Ni\u00f1o events can trigger what they called \u201cclimate regime shifts,\u201d meaning abrupt, lasting changes in heat, rainfall and drought patterns.<\/p>\n

El Ni\u00f1o is one of the planet\u2019s biggest natural release valves for ocean heat. The venting starts\u00a0with periodic shifts of swirling ocean currents and winds over the Pacific. That causes huge stores of tropical ocean heat to surge eastward from the Western Pacific Warm Pool<\/a>, roughly between Australia and Indonesia, northward to Japan. Those tropical seas are by far the warmest ocean region on Earth, and span an area four times as large as the continental United States<\/a>.<\/p>\n

When that ocean heat spreads across the equatorial Pacific, it spills into the atmosphere in pulses that tilt weather patterns, reroute powerful high-elevation winds, raise global temperatures, bleach coral reefs and disrupt fisheries and ocean ecosystems. The effects hit continents as well, intensifying rainstorms and flooding in some regions, while amplifying extreme heat, drought and wildfires in others.<\/p>\n

In 2015<\/a>, heat from the tropical Pacific helped raise the global annual average temperature irreversibly past 1 degree Celsius above the pre-industrial baseline. And in 2024, Earth experienced the hottest year recorded in human history,<\/a> aided by another El Ni\u00f1o boost.<\/p>\n

Even a moderately strong El Ni\u00f1o during the next 12 to 18 months could drive the average global temperature to about 1.7 degrees Celsius above the preindustrial level, climate scientist James Hansen<\/a> told Inside Climate News. Hansen doubts the world will meaningfully cool back down to below the 1.5 degree Celsius mark after the El Ni\u00f1o fades.<\/p>\n

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Hot El Ni\u00f1o cycles in the tropical Pacific Ocean release so much energy, as heat and moisture, to the atmosphere, that it affects rainfall and drought patterns halfway around the world. Credit: NASA\/JPL<\/figcaption><\/figure>\n

Passing that threshold may not be like falling off a climate cliff, but it\u2019s definitely the point when the edge starts crumbling, with rapid changes to relatively stable systems of forests, water, rain and temperatures that have sustained people and ecosystems for millennia.<\/p>\n

Even below the 1.5-degree Celsius threshold, California reservoirs no longer fill in some years and overflow with extreme rainfall in others. Coral reefs from Australia to the Caribbean have bleached beyond recovery and vast tracts of forests burned up in megafires. Traditional crop calendars don\u2019t align with seasons. Deadly nighttime heat rises in cities, killing vulnerable people in apartments that never cool.<\/p>\n

\u201cSuper El Ni\u00f1o\u201d Seen as Game Changer<\/strong><\/h2>\n

Climate impacts amplified by strong El Ni\u00f1os keep hitting the same vulnerable regions, may be more widespread than previously thought and can persist long after the tropical Pacific cools, according to an El Ni\u00f1o study<\/a> published December 2025 in Nature Communications.\u00a0<\/p>\n

The study concluded that \u201csuper El Ni\u00f1os\u201d are not just passing weather events, but more like climate shocks that can push parts of the Earth system into new states, co-author Jong-Seong Kug<\/a> wrote in an email.\u00a0<\/p>\n

The study\u2019s definition of a super El Ni\u00f1o is when the sea surface temperature anomaly in the tropical Pacific \u201cexceeds 2 standard deviations above normal\u201d\u2014not an ordinary fluctuation, but more of a systemic warning sign.\u00a0<\/p>\n

The impacts are clustered in areas known to be sensitive to long-distance climate connections and regions \u201cthat are already prone to climate regime shifts,\u201d wrote Kug, a climate researcher at Seoul National University in South Korea.\u00a0<\/p>\n

There are only three super El Ni\u00f1os on record: in 1982-83, 1997-98 and 2015-16. All of them contributed to regime shifts in regional ocean temperatures, leading to unprecedented marine heat waves that destroyed or damaged coral reefs and caused mass die-offs and starvation among many marine organisms, from starfish to seabirds and marine mammals.\u00a0<\/p>\n

Those impacts, as well as changes in drought and extreme heat over land areas, persisted for years and could shift some regional patterns for decades, according to the study.<\/p>\n

Kug said the main \u201cregime-shift hotspots\u201d in oceans include the central North Pacific, the southeastern Indian Ocean, the southwestern Pacific and the Gulf of Mexico, areas where globally linked atmospheric connections \u201ccan strongly perturb the ocean surface and, in some cases, help anomalies persist.\u201d<\/p>\n

Kug said the study identified super El Ni\u00f1o regime shifts in East Africa and the Maritime Continent\u2014the island-rich region between the Indian and Pacific Oceans around Indonesia, Malaysia and Papua New Guinea.<\/p>\n

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The research also uncovered strong El Ni\u00f1o signals in the form of soil moisture changes in central southern Asia, central Australia, the Amazon and western Greenland. The land responses are \u201clinked to the way super El Ni\u00f1o reshapes regional precipitation and temperature through teleconnections,\u201d he said in an email.<\/p>\n

\u201cThese shifts matter because they can turn a short-lived climate shock into a longer-lasting risk,\u201d he wrote. If soil moisture stays below normal for several years, crops are exposed to repeated heat and water stress across multiple growing seasons with \u201cdirect consequences for food production and water security.\u201d<\/p>\n

Adapting to a Changing Baseline<\/strong><\/h2>\n

The potential for more destructive physical impacts raises deeper concerns about how societies that developed under relatively stable climate conditions will function in a world with shifting baselines and sharper swings between droughts and floods, more intense tropical storms, expanded fire seasons and long-lasting unseasonal extreme heat.<\/p>\n

Understanding how stronger El Ni\u00f1os reshape the climate can help countries close what the United Nations calls the global adaptation gap, which is the widening distance between known climate risks and actual preparation.<\/p>\n

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