2024’s record ocean heat revved up Atlantic hurricane wind speeds: study

2024’s record ocean heat revved up Atlantic hurricane wind speeds: study

Sub : Geo

Sec : Climatology

Context:

• Climate Change Amplifies Atlantic Hurricane Intensity in 2024.

Key Findings:

• Human-Driven Warming:
  • Climate change, driven by carbon dioxide and other greenhouse gas emissions, intensified every Atlantic hurricane in 2024.
  • Ocean surface temperatures in the Gulf of Mexico were 2.5°F (1.4°C) higher than without climate change, fueling stronger storms.
• Hurricane Intensification:
  • Record ocean warmth intensified the maximum wind speeds of all 11 Atlantic hurricanes in 2024 by 9-28 mph (14-45 kph).
  • Some hurricanes were pushed up a category on the Saffir-Simpson scale, significantly increasing their destructive potential.

Examples of Impact:

• Category Escalations:
  • Hurricanes Milton and Beryl: From Category 4 to Category 5.
  • Helene: From Category 3 to Category 4, causing over 200 fatalities and becoming the second deadliest hurricane to hit the U.S. since Hurricane Katrina (2005).
• Peak Intensification Analysis:
  • At Hurricane Milton’s peak before landfall, climate change made the conditions (e.g., warm sea temperatures) 100 times more likely and increased its maximum wind speed by 24 mph.

Broader Implications:

• Historical Analysis:
  • From 2019 to 2023, 84% of Atlantic hurricanes were significantly strengthened by human-caused ocean warming.
• Global Application:
  • The study’s methodology can analyse tropical cyclones worldwide, not just in the Atlantic Basin.

• Future Risks:
  • Current impacts are seen with the world at 1.3°C (2.3°F) above pre-industrial levels.
  • Exceeding 1.5°C (2.7°F) will likely intensify these effects further.

Hurricanes:

• Hurricanes, also known as tropical cyclones or typhoons (depending on the region), are intense storm systems formed over warm ocean waters.

Process of Hurricane Formation:

Warm Ocean Waters:

• Sea surface temperatures must be at least 26.5°C (80°F) to a depth of about 50 meters.
• Warm water provides the energy needed for the storm to develop.

Low-Pressure System

• A tropical disturbance begins as a cluster of thunderstorms over warm water.
• The warm, moist air above the ocean rises, creating a low-pressure area near the surface.

Coriolis Effect

• The Earth’s rotation causes the rising air to spin.
• This spin organises the system into a cyclonic (rotating) pattern.
• Coriolis Effect is strongest near the equator but hurricanes cannot form at the equator itself (within 5° latitude) due to insufficient Coriolis force.

Convection and Thunderstorm Development

• Warm, moist air rises rapidly, cooling and condensing into clouds and releasing latent heat. This heat fuels further rising air, intensifying the system.

Development of a Core

• As air rises and more heat is released, the pressure in the center drops further, creating the eye (calm, low-pressure center).
• Surrounding this eye is the eyewall, a ring of intense thunderstorms with the strongest winds and heaviest rainfall.

Sustained Growth:

• The hurricane draws in more warm, moist air while expelling cooler, drier air at the top.
• This cycle maintains the storm’s strength as long as:
  • It remains over warm water.
  • There is minimal wind shear (difference in wind speeds/directions at different altitudes).

Movement and Dissipation:

• Hurricanes are guided by prevailing winds and pressure systems.
• They weaken when they move over land or cooler waters due to loss of energy from warm water.

Source: TH