By Our Reporter
Namaqualand is a landscape along the Buffels River in South Africa. Namaqualand region is dotted with thousands of sandy mounds that occupy about 20% of the surface area.
These little hills popularly called heuweltjies by the Afrikaans, are termite mounds, inhabited by an underground network of tunnels and nests of the southern harvester termites.
The vast land is a global biodiversity hotspot renowned for its spring flowers, but it is a dry area. Surface water is in short supply and the groundwater is saline.
Most of Namaqualand receives very little rainfall, there are rare, high intensity rainfall events. When these do occur, the termite burrows on the mound surfaces serve as water flow paths that can harvest rain and channel water into the mound.
This causes the salts that built up in the mounds over thousands of years to be flushed into the groundwater system via flow paths created by the tunnelling action of the termites, pushing the dissolved minerals ever deeper.
This process also pushes down the carbon that when termites collected plant material and brought it into the mound over millennia.
In 2021, a group of scientists set out to study why the groundwater in the area, around 530km from Cape Town, is saline. The groundwater salinity seemed to be specifically related to the location of these little hills.
The researchers used radiocarbon dating; dating the mounds, they reasoned, would allow them to see when minerals that were stored in the mounds were flushed to the groundwater.
The tests revealed far more than what the researchers expected. Namaqualand’s little hills turned out to be the world’s oldest inhabited termite mounds. According to the researchers, some date as far back as between 34,000 and 13,000 years.
Findings showed that the oldest previously known inhabited mounds were 4,000 years old from a different termite species from Brazil and 2,300 years old from central Congo.
This is more than just an interesting scientific find or historical curiosity. It offers a window into what our planet looked like tens of thousands of years ago, providing a living archive of environmental conditions that shaped our world.
It also revealed today that there is huge growing evidence that termites have a substantial, but still poorly understood, role in the carbon cycle.
Carbon storage
The ability of termite mounds to sequester carbon, the researchers noted, is linked to their unique behaviour. The insects transport deep into the soil. This way, fresh stores of carbon are continuously added at depths greater than one metre.
Deep storage reduces the likelihood of organic carbon being released back into the atmosphere. So the mound acts as a long-term carbon sink.
Not only do the termites take the organic carbon material deep underground into their nests, but their tunnels also allow dissolved inorganic carbon (known as soil calcite or calcium carbonate) in the mound soil to move into the groundwater along with other soluble minerals.
So the termite mounds also through dissolution and leaching of soil carbonate-bicarbonate to groundwater. This is a long term carbon storage method that carbon storage companies are trying to replicate to reduce atmospheric carbon.
The results of these researchers radiocarbon dating of both the organic and inorganic carbon in this soil show that the mounds have been accumulating organic matter and nutrients, including carbon, for tens of thousands of years.
This enrichment is one of the reasons that Namaqualand’s famous wildflowers are so prominent on the mounds in spring. During the mounds’ formation, the region experienced more rainfall than it does today.
The researchers stressed that studying the layers of the mounds and looking at the carbon, sulphur, and oxygen isotopes preserved in the mounds and in the groundwater showed that periods of higher rainfall in the region were associated with global climate cooling.
These cooler and wetter periods were associated with the leaching of accumulated carbon and other minerals to the groundwater.
These findings, the researchers noted, are further evidence that termites fully deserve their reputation as ecosystem engineers. They modify their soil surroundings to maintain ideal humidity and temperature conditions, and their foraging paths extend many tens of metres.
The researchers argue that, given what we’ve uncovered in Namaqualand, termite activity should be incorporated into carbon models.
These primarily focus on forests and oceans; including termite mounds can help provide a more comprehensive understanding of global carbon dynamics.
The study revealed that in Namaqualand, mounds occupy 27% of the total area but contribute 44 % of the total soil organic carbon stock. This highlights the disproportionate contribution termite mounds make to carbon stocks in these semi-arid environments.
Termite mounds are often cleared for agriculture or termites are considered pests. Raising awareness about the ecological importance of termite mounds and integrating these findings into environmental policies can help promote practices that support natural carbon sinks.
By studying the little hills in Namaqualand region in South Africa and other termite mounds anywhere across the world, scientists can gain a better understanding of how to sequester (store) carbon.
This process removes CO₂ from the atmosphere and is vital for mitigating climate change.