Southern ocean – Artifex.News https://artifex.news Stay Connected. Stay Informed. Wed, 13 May 2026 07:06:00 +0000 en-US hourly 1 https://wordpress.org/?v=7.0 https://artifex.news/wp-content/uploads/2026/05/cropped-cropped-app-logo-32x32.png Southern ocean – Artifex.News https://artifex.news 32 32 INCOIS expands coastal flood monitoring to tackle ‘Kallakkadal’ surges https://artifex.news/article70970515-ecerand29/ Wed, 13 May 2026 07:06:00 +0000 https://artifex.news/article70970515-ecerand29/ Read More “INCOIS expands coastal flood monitoring to tackle ‘Kallakkadal’ surges” »

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INCOIS’s second Coastal Flood Monitoring System (CFMS) near Kollam Harbour in Kerala to improve the accuracy of ‘Kallakkadal’ forecasts.
| Photo Credit: BY ARRANGEMENT

The Indian National Centre for Ocean Information Services (INCOIS), headquartered in Hyderabad, has installed a second Coastal Flood Monitoring System (CFMS) near Kollam Harbour in Kerala to enhance the accuracy of ‘Kallakkadal’ (swell surge) forecasts along India’s southwest coast.

Who are at threat from swell surges?

‘Kallakkadal’ events — sudden and powerful swell surges — pose a significant threat to fishing communities and coastal infrastructure. These surges are typically triggered by long-period swells generated by distant storms in the southern Indian Ocean, nearly 10,000 kilometres from the Indian coastline, said INCOIS Director T.M. Balakrishnan Nair.

Swell surges frequent during pre-monsoon

The first observational evidence of such waves in Indian waters was recorded during the initial deployment of the CFMS at Vizhinjam last year. The system was operated between February and May, covering the pre-monsoon season when these swell surges are most frequent.

Scientists observed that these swells, with periods ranging from 30 to 300 seconds, can substantially elevate coastal water levels. The aim, they said, is to identify patterns in southern ocean swells and refine forecasting models for improved accuracy.

CFMS integrates a coastal automatic weather station with four high-frequency pressure sensors installed in shallow waters at depths of three to seven metres. This configuration enables precise monitoring of nearshore wave transformation processes, providing valuable real-time data.

INCOIS is working to build a comprehensive understanding of the entire chain of processes — from swell generation in the open ocean to wave transformation near the shore and the resulting coastal flooding. This integrated approach is expected to strengthen early warning systems and improve the precision of ‘Kallakkadal’ forecasts.

Scientific basis of swell surge generation

About a decade ago, it had established the scientific basis of swell surge generation in the southern Indian Ocean, demonstrating how distant meteorological systems can produce long-period swells that travel thousands of kilometres before impacting the Indian coast. Subsequent research has linked ‘Kallakkadal’ events to infragravity waves — low-frequency waves formed through interactions among shorter waves in the open ocean.

As these waves approach shallow waters, their energy intensifies due to shoaling — a process in which wave height increases as waves move from deep to shallow regions. Coastal bathymetry, or underwater topography, further amplifies these surges and contributes to sudden coastal flooding, said scientists.

Kollam was chosen for the second system due to its frequent exposure to such events. Following the installation, INCOIS conducted a community awareness programme to improve preparedness and encourage effective use of forecast information, said scientist Praveen Kumar. Through a combination of scientific research, advanced observations, and community outreach, INCOIS aims to strengthen coastal resilience and reduce the risks posed by ‘Kallakkadal’ events.



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World’s Largest Iceberg A23a Breaks Free, Drifts In The Southern Ocean https://artifex.news/worlds-largest-iceberg-a23a-breaks-free-drifts-in-the-southern-ocean-7262258/ Mon, 16 Dec 2024 13:40:02 +0000 https://artifex.news/worlds-largest-iceberg-a23a-breaks-free-drifts-in-the-southern-ocean-7262258/ Read More “World’s Largest Iceberg A23a Breaks Free, Drifts In The Southern Ocean” »

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After being grounded for over 30 years, the world’s largest iceberg, A23a, has started drifting in the Southern Ocean. This massive iceberg, which is roughly double the size of Greater London and weighs approximately one trillion tonnes, broke off from Antarctica’s Filchner Ice Shelf in 1986. Since then, it had remained stuck on the seabed near the South Orkney Islands in the Weddell Sea until it began its slow movement northwards in 2020.

“It’s exciting to see A23a on the move again after periods of being stuck. We are interested to see if it will take the same route the other large icebergs that have calved off Antarctica have taken. And more importantly what impact this will have on the local ecosystem,” said Dr Andrew Meijers, who is an oceanographer with the British Antarctic Survey.

A23a’s journey

The journey of iceberg A23a has been marked by fascinating scientific events. A23a broke free from Antarctica in 1986 but got stuck in the Weddell Sea’s bottom mud for 30 years. It remained a static “ice island” until 2020 when it finally began to drift again. Slowly at first, it then accelerated northward, moving towards warmer air and waters. 

For several months, the iceberg was trapped in a rare oceanographic phenomenon known as a Taylor Column, where rotating water above a seamount held it in place. This unusual event caused A23a to spin in a single spot, delaying its expected rapid drift north.

As A23a continues on its journey, it is anticipated to follow the Antarctic Circumpolar Current into the Southern Ocean. This current is likely to drive the iceberg towards the sub-Antarctic island of South Georgia. Once it reaches this region, A23a will encounter warmer waters, leading to its eventual break-up into smaller icebergs and subsequent melting.

Biogeochemist Laura Taylor, who was on board a research vessel, expressed hope that scientists would be able to study the impact of the massive iceberg A23a on the surrounding ecosystems as it melts and breaks apart.

“We know that these giant icebergs can provide nutrients to the waters they pass through, creating thriving ecosystems in otherwise less productive areas,” Ms Taylor said.

“What we don’t know is what difference particular icebergs, their scale, and their origins can make to that process. We took samples of ocean surface waters behind, immediately adjacent to, and ahead of the iceberg’s route. They should help us determine what life could form around A23a and how it impacts carbon in the ocean and its balance with the atmosphere,” she added.




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The Southern Ocean has the earth’s cleanest air — scientists finally know why https://artifex.news/article68031586-ece/ Fri, 05 Apr 2024 12:38:37 +0000 https://artifex.news/article68031586-ece/ Read More “The Southern Ocean has the earth’s cleanest air — scientists finally know why” »

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The Southern Ocean is renowned for having the cleanest air on Earth. But the precise reasons why have remained a mystery, until now. Image for Representation.
| Photo Credit: AP

The Southern Ocean is renowned for having the cleanest air on Earth. But the precise reasons why have remained a mystery, until now.

There’s more to it than just a lack of human activity. Yes, there are fewer people down there using industrial chemicals and burning fossil fuels. But there are natural sources of fine particles too, such as salt from sea spray or dust whipped up by the wind.

Regardless of origin, fine solid particles or liquid droplets suspended in air are known as “aerosols”. We consider clean air to have low levels of aerosols, without discriminating between natural or industrial sources.

Our recent research discovered clouds and rain play a crucial role in scrubbing the atmosphere clean.

Understanding the role of clouds and rain

Aerosol levels over the Southern Ocean are influenced by a range of factors. These include the amount of salt spray and seasonal variation in the growth of tiny plant-like organisms called phytoplankton, which are a source of airborne sulphate particles.

Fewer sulphates are produced during winter, which is when the air over the Southern Ocean is most pristine.

But that’s not the full story. The Southern Ocean is also the cloudiest place on Earth. It experiences short-lived, sporadic showers like nowhere else. We wanted to understand the role of clouds and rain in cleaning the air.

The biggest barrier to understanding these processes has always been the lack of high-quality observations of clouds, rainfall and aerosols in this poorly observed region of the world.

Thankfully, a new generation of satellites allows us to study images of clouds in unprecedented detail. We developed a computer program to recognise different cloud patterns over a vast area of the Southern Ocean.

In particular we were on the lookout for distinctive honeycomb-shaped patterns in the cloud field. These honeycomb-like clouds are of great interest because they have a major role in regulating the climate.

When the honeycomb cell is filled with cloud or “closed” it is whiter and brighter, reflecting more sunlight back to space. So these clouds help keep the Earth cool.

Empty or “open” honeycomb cells, on the other hand, let more sunlight in.

These intricacies remain a source of error in modelling the Earth’s climate because they are not being properly included. It’s important to get the balance of open and closed cells right, or the results can be way off.

Whether the honeycomb cells are open or closed also relates to the amount of rainfall they can produce.

The cells are big enough to be seen from space, around 40-60km in diameter. So we can study them using satellite images.

Our research is particularly timely given this month’s launch of a cloud and precipitation experiment at Kennaook/Cape Grim in Tasmania. It aims to get higher resolution data on clouds, rain and sunlight.

Scrubbing aerosols out of the sky

We compared the honeycomb cloud patterns with measurements of aerosols from the Kennaook/Cape Grim observatory and also with the Bureau of Meteorology’s rainfall observations from a nearby rain gauge.

Our results showed days with the cleanest air were associated with the presence of open honeycomb cloud. We think this is because these clouds generate sporadic but intense rain showers, which seem to “wash” the aerosol particles out of the air.

It’s somewhat counter-intuitive, but it turns out the open cells contain more moisture and produce more rain than the fluffy white closed cells filled with cloud. We found the open honeycomb clouds produce six times as much rain as the closed ones.

So what looks like less cloudy weather by satellite actually triggers the most effective rain showers for washing the aerosols out. Whereas the filled or closed honeycomb pattern, which looks cloudier, is less effective. That was one of the more surprising aspects of our findings.

We found the empty honeycombs to be far more common during the winter months, when the air is cleanest.

We also wanted to know what makes cloud fields look the way they do. Our analysis suggests large-scale weather systems control the pattern of the cloud field. As unruly storms track across the Southern Ocean, they produce these open and closed cells.

Fresh air and better climate models

Our research has added a new piece to the puzzle of why the Southern Ocean has the world’s cleanest air. Rainfall is the key, especially rain from these clear, open honeycomb cell-type clouds. We were first to discover they are truly responsible for cleaning up all the air flowing over the Southern Ocean.

These honeycomb patterns are also found in both the North Atlantic and North Pacific regions during winter. So our work will also help explain how these clouds remove aerosols including dust and pollution in these locations. And our findings will help improve climate models, enabling more accurate predictions.

Rain scrubs the aerosols out of the sky in much the same way as a washing machine acts to clean clothes.

After the cold front comes through, the air is clean. If you’re wintering on the south coast of Australia, you can breathe in the benefits as this fresh air comes in off the Southern Ocean.

The Conversation

Tahereh Alinejadtabrizi, PhD student, Monash University; Steven Siems, Professor in Cloud Microphysics, Monash University, and Yi Huang, Senior Lecturer in Climate Science, The University of Melbourne

This article is republished from The Conversation under a Creative Commons license. Read the original article.



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