Latest news with #Neoproterozoic
Economic Times
30-07-2025
- Science
- Economic Times
Scientists discover 400-mile-long chain of fossilized volcanoes buried beneath China
Formation and geological significance Methodology and findings Broader implications Live Events (You can now subscribe to our (You can now subscribe to our Economic Times WhatsApp channel Researchers have uncovered a massive, 400-mile-long chain of extinct, fossilized volcanoes deep under South China , revealing a surprising new chapter in Earth 's geological history. This ancient volcanic arc formed around 800 million years ago during the early Neoproterozoic era , when two tectonic plates collided during the breakup of the supercontinent Rodinia, according to a recent study published in the Journal of Geophysical Research: Solid 800 million years ago, South China sat on the northwestern margin of Rodinia. Shifting tectonic forces caused the landmass, now known as the Yangtze Block, to break off and move toward the China Ocean plate. This collision caused the denser oceanic crust to subduct beneath the continental crust — a process that generated magma as the oceanic plate heated up and released water. The magma rose through the crust, forming a long volcanic arc along the subduction typical narrow volcanic arcs seen along continental margins (such as the Cascade Range in North America), this chain is unusually broad, stretching approximately 430 miles (700 km) long and about 30 miles (50 km) wide, extending as far as 550 miles (900 km) inland. This extensive width is linked to a tectonic process called flat-slab subduction, where the oceanic plate moves horizontally at a shallow angle beneath the continent before descending deeper. This shallow subduction produces two volcanic ridges—one near the plate boundary and another further inland—explaining the wide spatial extent of the fossilized volcanic arc beneath the Yangtze fossil volcanoes erode over millions of years and become buried under thick sedimentary layers (up to several kilometers thick in the Sichuan Basin), they are challenging to detect. The research team, led by Zhidong Gu (PetroChina) and Junyong Li (Nanjing University), employed airborne magnetic sensing technology to map magnetic minerals beneath these sedimentary layers, revealing iron-rich rocks with strong magnetic signals consistent with volcanic arc magmatism approximately 4 miles (6 kilometers) below the taken from seven deep boreholes drilled in the Sichuan Basin showed geochemical signatures similar to crust formed by volcanic arcs, and uranium-lead dating confirmed that these magmatic rocks formed between 770 million and 820 million years ago, placing them firmly in the early discovery has significant implications for understanding Earth's crustal evolution. Volcanism and related mountain building in arc systems create new crust and alter existing crust. The volume and extent of magmatic activity revealed by this study suggest that ancient volcanic arcs were more extensive than previously realized in this Peter Cawood from Monash University, who was not involved in the study, pointed out alternative possibilities, such as the idea that the two volcanic belts revealed might be separate, contemporaneous systems joined together later in geological time. Nevertheless, he emphasized that the study provides "exciting new data" in a traditionally difficult-to-study area.
Time of India
29-07-2025
- Science
- Time of India
Scientists discover 400-mile-long chain of fossilized volcanoes buried beneath China
Researchers have uncovered a massive, 400-mile-long chain of extinct, fossilized volcanoes deep under South China , revealing a surprising new chapter in Earth 's geological history. This ancient volcanic arc formed around 800 million years ago during the early Neoproterozoic era , when two tectonic plates collided during the breakup of the supercontinent Rodinia, according to a recent study published in the Journal of Geophysical Research: Solid Earth . Formation and geological significance About 800 million years ago, South China sat on the northwestern margin of Rodinia. Shifting tectonic forces caused the landmass, now known as the Yangtze Block, to break off and move toward the China Ocean plate. This collision caused the denser oceanic crust to subduct beneath the continental crust — a process that generated magma as the oceanic plate heated up and released water. The magma rose through the crust, forming a long volcanic arc along the subduction zone. Explore courses from Top Institutes in Please select course: Select a Course Category Degree Design Thinking healthcare Data Science MCA others Management Cybersecurity PGDM Operations Management Project Management Technology Public Policy Leadership CXO Healthcare Digital Marketing Product Management Artificial Intelligence Finance Data Analytics Others Data Science MBA Skills you'll gain: Data-Driven Decision-Making Strategic Leadership and Transformation Global Business Acumen Comprehensive Business Expertise Duration: 2 Years University of Western Australia UWA Global MBA Starts on Jun 28, 2024 Get Details Unlike typical narrow volcanic arcs seen along continental margins (such as the Cascade Range in North America), this chain is unusually broad, stretching approximately 430 miles (700 km) long and about 30 miles (50 km) wide, extending as far as 550 miles (900 km) inland. This extensive width is linked to a tectonic process called flat-slab subduction, where the oceanic plate moves horizontally at a shallow angle beneath the continent before descending deeper. This shallow subduction produces two volcanic ridges—one near the plate boundary and another further inland—explaining the wide spatial extent of the fossilized volcanic arc beneath the Yangtze Block. Methodology and findings Because fossil volcanoes erode over millions of years and become buried under thick sedimentary layers (up to several kilometers thick in the Sichuan Basin), they are challenging to detect. The research team, led by Zhidong Gu (PetroChina) and Junyong Li (Nanjing University), employed airborne magnetic sensing technology to map magnetic minerals beneath these sedimentary layers, revealing iron-rich rocks with strong magnetic signals consistent with volcanic arc magmatism approximately 4 miles (6 kilometers) below the surface. Rocks taken from seven deep boreholes drilled in the Sichuan Basin showed geochemical signatures similar to crust formed by volcanic arcs, and uranium-lead dating confirmed that these magmatic rocks formed between 770 million and 820 million years ago, placing them firmly in the early Neoproterozoic. Broader implications This discovery has significant implications for understanding Earth's crustal evolution. Volcanism and related mountain building in arc systems create new crust and alter existing crust. The volume and extent of magmatic activity revealed by this study suggest that ancient volcanic arcs were more extensive than previously realized in this region. Live Events Geologist Peter Cawood from Monash University, who was not involved in the study, pointed out alternative possibilities, such as the idea that the two volcanic belts revealed might be separate, contemporaneous systems joined together later in geological time. Nevertheless, he emphasized that the study provides "exciting new data" in a traditionally difficult-to-study area.
Yahoo
26-02-2025
- Science
- Yahoo
Ancient glacier finding reveals clues to how complex life on Earth evolved, scientists say
Sign up for CNN's Wonder Theory science newsletter. Explore the universe with news on fascinating discoveries, scientific advancements and more. More than half a billion years ago on a frigid, ice-covered Earth, glaciers stirred up ingredients for complex life by bulldozing land minerals and then depositing them in the ocean, according to a new study. Inch by inch, as massive glaciers crept over frozen land toward an ice-covered sea, they scoured the ground beneath them, gouging and scraping rocks from Earth's crust. When the glaciers eventually melted, they released a torrent of terrestrial chemicals into the ocean, researchers recently reported. Minerals swept up on land by this 'glacial broom' altered marine chemistry and infused oceans with nutrients that they say may have shaped how complex life evolved. This ancient period of deep freeze, known as the Neoproterozoic Era, or 'Snowball Earth,' lasted from about 1 billion to 543 million years ago. During that time, landmasses consolidated into a supercontinent called Rodinia and then broke apart again. Earth's earliest forms of life, such as microbes, cyanobacteria, sponges and seafloor-dwelling organisms, populated the oceans. After the end of the Neoproterozoic came the rise of more complex life, with the first appearance of marine creatures sporting armor, shells and spikes. Scientists have attributed this evolutionary boom to increased oxygen levels in Earth's atmosphere and in shallow ocean waters. And now, research published Tuesday in the journal Geology suggests the flowing of ancient glaciers may have directly shaped chemical changes in the ocean that were critical for the evolution of complex organisms. Studying Snowball Earth offers a window into our planet's past, but it also presents valuable insights into modern climate change, lead study author Dr. Chris Kirkland said. 'Our deep time geological record indicates how changing one part of Earth affects another,' he said. Right now, the dramatic warming of the planet that marks the human-fueled climate crisis is happening at breakneck speed compared with these ancient processes that took millions of years. 'This rapid pace limits Earth's ability to naturally regulate itself, underscoring the urgency of addressing anthropogenic climate change.' Glacier movement, or glaciation, is known to scrape up and ferry terrestrial sediments into oceans, lakes and rivers, forming the basis of aquatic food webs. However, researchers who study ancient Earth were previously uncertain whether Neoproterozoic glaciers moved at all, let alone enough to erode the ground beneath them and transfer minerals into the sea. 'It had been hypothesized that widespread glacial erosion of continental interiors could be caused by the Snowball Earth ice,' said Kirkland, a professor in the School of Earth and Planetary Sciences at Curtin University in Perth, Australia. 'However, aspects of this idea were not clear because that ice may not have moved or moved only slightly or indeed even flowed.' Kirkland and his colleagues found answers in Scotland and Northern Ireland, where they studied sediments from rock formations dating to the Neoproterozoic. The team looked at zircons — crystallized minerals that are exceptionally durable and can weather extreme geological events. Zircons also contain uranium; by measuring the stages of uranium's decay in zircons, geologists use the minerals as chronometers for studying Earth's past. The researchers examined sediments dating to the time when Earth was covered with ice, and from the 'hothouse Earth' period millions of years later when the ice was gone, and found the mineral composition of Snowball Earth sediments differed dramatically from that of later sediments. 'We recovered distinctive patterns in the populations of these mineral grains,' Kirkland told CNN in an email. 'In essence the 'DNA' fingerprint of these sedimentary rocks changed.' The findings appear to bolster the notion of active glaciation 'somewhat,' said Dr. Graham Shields, a professor of geology at University College London. Shields was not involved in the new research. However, the study did not include data from a significant glacial interval called the Marinoan, which marked the end of Snowball Earth, he told CNN in an email. Shields was also cautious about directly linking glacial erosion to the evolution of complex life. 'This connection has been proposed before but it is controversial because the linkage is assumed rather than explained,' Shields said. 'Dramatic landscape change causing the emergence of macroscopic animals is a neat idea, but the paper introduces a hypothesis about glacial erosion/weathering that can be tested, rather than settling the debate.' Rocks from the time of Snowball Earth contained older minerals, but also featured a range of mineral ages, hinting that the rocks were exposed and eroded over time by the scraping movement of glaciers. This evidence told the scientists that the glaciers of the Neoproterozoic were mobile. Younger rocks, from when Snowball Earth was thawing, had a narrower range of mineral ages, and more fragile grains were absent, suggesting flowing water had dissolved material that was previously ground down. At the waning of the Neoproterozoic, one of the known changes in ocean chemistry was a rise in uranium. Other research had previously explained this increase as resulting from the rise in atmospheric oxygen, 'however, our data imply that the delivery of chemical elements into the oceans also played a role in this,' Kirkland said. 'The 'lost' dissolved component in these rocks is seen 'popping back up' in changes in ocean chemistry at this time,' he added. By mapping these changes in terrestrial and marine environments, 'we are imaging the transfer of chemical elements through the Earth as a system.' The scientists reported that major glaciation events took place at least twice between 720 million and 635 million years ago. By the end of the Neoproterozoic, as Earth's icy cover began to thaw, major chemistry shifts were taking place in Earth's atmosphere and oceans. 'The end of these glaciations is marked by rapid increases in atmospheric and oceanic oxygen, possibly due to enhanced weathering of exposed rock surfaces and increased nutrient fluxes into the ocean,' Kirkland said. Such changes could have infused nutrient cycles and provided emerging life with the boost it needed to evolve into more complex forms. 'The idea that glacial debris from Neoproterozoic ice ages provided nutrients to support early animal evolution has been around for a while,' said Dr. Andrew Knoll, a professor emeritus of Earth and planetary sciences at Harvard University, who was not involved in the new research. However, questions remain about whether the minerals poured into the ocean by Neoproterozoic glaciation would have been enough to spur long-term environmental changes with biological consequences, Knoll told CNN in an email. Other research previously suggested that the impacts of glaciation events, such as the ones described in the new study, 'might well have only transient consequences — a bolus of nutrients raising primary production and perhaps increasing oxygen levels, before relaxing back to the earlier state of the environment,' Knoll said. The new findings are 'an interesting addition to the conversation,' he added. 'But the conversation continues.' From the Neoproterozoic to the present, similar processes shape climate change, including the role played by carbon dioxide (CO2) and the behavior of feedback loops, when a process feeds into an existing aspect of Earth's climate system and intensifies it. Ancient climate evidence also illuminates what happens during climate tipping points — when a threshold is crossed, triggering large-scale changes that are often irreversible. Today, Earth is heating up rapidly rather than cooling gradually over time. It took millions of years for glaciation to overtake the planet during Earth's snowball phase, while modern warming is accelerating over mere decades, 'much faster than past natural climate shifts,' Kirkland said. However, climate change's global progress is still mapped by studying the interplay of CO2 buildup, feedback loops and tipping points, he added. 'We can see how different parts of the planet are interrelated via chemical links,' he said. 'Change one part of the system, other parts also change.' Mindy Weisberger is a science writer and media producer whose work has appeared in Live Science, Scientific American and How It Works magazine.
CNN
26-02-2025
- Science
- CNN
Ancient glaciers reshaped Earth's surface, fueling the rise of complex life on Earth, scientists say
More than half a billion years ago on a frigid, ice-covered Earth, glaciers stirred up ingredients for complex life by bulldozing land minerals and then depositing them in the ocean, according to a new study. Inch by inch, as massive glaciers crept over frozen land toward an ice-covered sea, they scoured the ground beneath them, gouging and scraping rocks from Earth's crust. When the glaciers eventually melted, they released a torrent of terrestrial chemicals into the ocean, researchers recently reported. Minerals swept up on land by this 'glacial broom' altered marine chemistry and infused oceans with nutrients that they say may have shaped how complex life evolved. This ancient period of deep freeze, known as the Neoproterozoic Era, or 'Snowball Earth,' lasted from about 1 billion to 543 million years ago. During that time, landmasses consolidated into a supercontinent called Rodinia and then broke apart again. Earth's earliest forms of life, such as microbes, cyanobacteria, sponges and seafloor-dwelling organisms, populated the oceans. After the end of the Neoproterozoic came the rise of more complex life, with the first appearance of marine creatures sporting armor, shells and spikes. Scientists have attributed this evolutionary boom to increased oxygen levels in Earth's atmosphere and in shallow ocean waters. And now, research published Tuesday in the journal Geology suggests the flowing of ancient glaciers may have directly shaped chemical changes in the ocean that were critical for the evolution of complex organisms. Studying Snowball Earth offers a window into our planet's past, but it also presents valuable insights into modern climate change, lead study author Dr. Chris Kirkland said. 'Our deep time geological record indicates how changing one part of Earth affects another,' he said. Right now, the dramatic warming of the planet that marks the human-fueled climate crisis is happening at breakneck speed compared with these ancient processes that took millions of years. 'This rapid pace limits Earth's ability to naturally regulate itself, underscoring the urgency of addressing anthropogenic climate change.' From snowball Earth to hothouse planet Glacier movement, or glaciation, is known to scrape up and ferry terrestrial sediments into oceans, lakes and rivers, forming the basis of aquatic food webs. However, researchers who study ancient Earth were previously uncertain whether Neoproterozoic glaciers moved at all, let alone enough to erode the ground beneath them and transfer minerals into the sea. 'It had been hypothesized that widespread glacial erosion of continental interiors could be caused by the Snowball Earth ice,' said Kirkland, a professor in the School of Earth and Planetary Sciences at Curtin University in Perth, Australia. 'However, aspects of this idea were not clear because that ice may not have moved or moved only slightly or indeed even flowed.' Kirkland and his colleagues found answers in Scotland and Northern Ireland, where they studied sediments from rock formations dating to the Neoproterozoic. The team looked at zircons — crystallized minerals that are exceptionally durable and can weather extreme geological events. Zircons also contain uranium; by measuring the stages of uranium's decay in zircons, geologists use the minerals as chronometers for studying Earth's past. The researchers examined sediments dating to the time when Earth was covered with ice, and from the 'hothouse Earth' period millions of years later when the ice was gone, and found the mineral composition of Snowball Earth sediments differed dramatically from that of later sediments. 'We recovered distinctive patterns in the populations of these mineral grains,' Kirkland told CNN in an email. 'In essence the 'DNA' fingerprint of these sedimentary rocks changed.' The findings appear to bolster the notion of active glaciation 'somewhat,' said Dr. Graham Shields, a professor of geology at University College London. Shields was not involved in the new research. However, the study did not include data from a significant glacial interval called the Marinoan, which marked the end of Snowball Earth, he told CNN in an email. Shields was also cautious about directly linking glacial erosion to the evolution of complex life. 'This connection has been proposed before but it is controversial because the linkage is assumed rather than explained,' Shields said. 'Dramatic landscape change causing the emergence of macroscopic animals is a neat idea, but the paper introduces a hypothesis about glacial erosion/weathering that can be tested, rather than settling the debate.' Mass glacier thaw transforms oceans Rocks from the time of Snowball Earth contained older minerals, but also featured a range of mineral ages, hinting that the rocks were exposed and eroded over time by the scraping movement of glaciers. This evidence told the scientists that the glaciers of the Neoproterozoic were mobile. Younger rocks, from when Snowball Earth was thawing, had a narrower range of mineral ages, and more fragile grains were absent, suggesting flowing water had dissolved material that was previously ground down. At the waning of the Neoproterozoic, one of the known changes in ocean chemistry was a rise in uranium. Other research had previously explained this increase as resulting from the rise in atmospheric oxygen, 'however, our data imply that the delivery of chemical elements into the oceans also played a role in this,' Kirkland said. 'The 'lost' dissolved component in these rocks is seen 'popping back up' in changes in ocean chemistry at this time,' he added. By mapping these changes in terrestrial and marine environments, 'we are imaging the transfer of chemical elements through the Earth as a system.' The scientists reported that major glaciation events took place at least twice between 720 million and 635 million years ago. By the end of the Neoproterozoic, as Earth's icy cover began to thaw, major chemistry shifts were taking place in Earth's atmosphere and oceans. 'The end of these glaciations is marked by rapid increases in atmospheric and oceanic oxygen, possibly due to enhanced weathering of exposed rock surfaces and increased nutrient fluxes into the ocean,' Kirkland said. Such changes could have infused nutrient cycles and provided emerging life with the boost it needed to evolve into more complex forms. 'The idea that glacial debris from Neoproterozoic ice ages provided nutrients to support early animal evolution has been around for a while,' said Dr. Andrew Knoll, a professor emeritus of Earth and planetary sciences at Harvard University, who was not involved in the new research. However, questions remain about whether the minerals poured into the ocean by Neoproterozoic glaciation would have been enough to spur long-term environmental changes with biological consequences, Knoll told CNN in an email. Other research previously suggested that the impacts of glaciation events, such as the ones described in the new study, 'might well have only transient consequences — a bolus of nutrients raising primary production and perhaps increasing oxygen levels, before relaxing back to the earlier state of the environment,' Knoll said. The new findings are 'an interesting addition to the conversation,' he added. 'But the conversation continues.' Lessons for today's climate crisis From the Neoproterozoic to the present, similar processes shape climate change, including the role played by carbon dioxide (CO2) and the behavior of feedback loops, when a process feeds into an existing aspect of Earth's climate system and intensifies it. Ancient climate evidence also illuminates what happens during climate tipping points — when a threshold is crossed, triggering large-scale changes that are often irreversible. Today, Earth is heating up rapidly rather than cooling gradually over time. It took millions of years for glaciation to overtake the planet during Earth's snowball phase, while modern warming is accelerating over mere decades, 'much faster than past natural climate shifts,' Kirkland said. However, climate change's global progress is still mapped by studying the interplay of CO2 buildup, feedback loops and tipping points, he added. 'We can see how different parts of the planet are interrelated via chemical links,' he said. 'Change one part of the system, other parts also change.'
Yahoo
26-02-2025
- Science
- Yahoo
Glaciers ‘bulldozed' snowball Earth and changed ocean chemistry, paving the way for complex life, scientists say
Sign up for CNN's Wonder Theory science newsletter. Explore the universe with news on fascinating discoveries, scientific advancements and more. More than half a billion years ago on a frigid, ice-covered Earth, glaciers stirred up ingredients for complex life by bulldozing land minerals and then depositing them in the ocean, according to a new study. Inch by inch, as massive glaciers crept over frozen land toward an ice-covered sea, they scoured the ground beneath them, gouging and scraping rocks from Earth's crust. When the glaciers eventually melted, they released a torrent of terrestrial chemicals into the ocean, researchers recently reported. Minerals swept up on land by this 'glacial broom' altered marine chemistry and infused oceans with nutrients that they say may have shaped how complex life evolved. This ancient period of deep freeze, known as the Neoproterozoic Era, or 'Snowball Earth,' lasted from about 1 billion to 543 million years ago. During that time, landmasses consolidated into a supercontinent called Rodinia and then broke apart again. Earth's earliest forms of life, such as microbes, cyanobacteria, sponges and seafloor-dwelling organisms, populated the oceans. After the end of the Neoproterozoic came the rise of more complex life, with the first appearance of marine creatures sporting armor, shells and spikes. Scientists have attributed this evolutionary boom to increased oxygen levels in Earth's atmosphere and in shallow ocean waters. And now, research published Tuesday in the journal Geology suggests the flowing of ancient glaciers may have directly shaped chemical changes in the ocean that were critical for the evolution of complex organisms. Studying Snowball Earth offers a window into our planet's past, but it also presents valuable insights into modern climate change, lead study author Dr. Chris Kirkland said. 'Our deep time geological record indicates how changing one part of Earth affects another,' he said. Right now, the dramatic warming of the planet that marks the human-fueled climate crisis is happening at breakneck speed compared with these ancient processes that took millions of years. 'This rapid pace limits Earth's ability to naturally regulate itself, underscoring the urgency of addressing anthropogenic climate change.' Glacier movement, or glaciation, is known to scrape up and ferry terrestrial sediments into oceans, lakes and rivers, forming the basis of aquatic food webs. However, researchers who study ancient Earth were previously uncertain whether Neoproterozoic glaciers moved at all, let alone enough to erode the ground beneath them and transfer minerals into the sea. 'It had been hypothesized that widespread glacial erosion of continental interiors could be caused by the Snowball Earth ice,' said Kirkland, a professor in the School of Earth and Planetary Sciences at Curtin University in Perth, Australia. 'However, aspects of this idea were not clear because that ice may not have moved or moved only slightly or indeed even flowed.' Kirkland and his colleagues found answers in Scotland and Northern Ireland, where they studied sediments from rock formations dating to the Neoproterozoic. The team looked at zircons — crystallized minerals that are exceptionally durable and can weather extreme geological events. Zircons also contain uranium; by measuring the stages of uranium's decay in zircons, geologists use the minerals as chronometers for studying Earth's past. The researchers examined sediments dating to the time when Earth was covered with ice, and from the 'hothouse Earth' period millions of years later when the ice was gone, and found the mineral composition of Snowball Earth sediments differed dramatically from that of later sediments. 'We recovered distinctive patterns in the populations of these mineral grains,' Kirkland told CNN in an email. 'In essence the 'DNA' fingerprint of these sedimentary rocks changed.' The findings appear to bolster the notion of active glaciation 'somewhat,' said Dr. Graham Shields, a professor of geology at University College London. Shields was not involved in the new research. However, the study did not include data from a significant glacial interval called the Marinoan, which marked the end of Snowball Earth, he told CNN in an email. Shields was also cautious about directly linking glacial erosion to the evolution of complex life. 'This connection has been proposed before but it is controversial because the linkage is assumed rather than explained,' Shields said. 'Dramatic landscape change causing the emergence of macroscopic animals is a neat idea, but the paper introduces a hypothesis about glacial erosion/weathering that can be tested, rather than settling the debate.' Rocks from the time of Snowball Earth contained older minerals, but also featured a range of mineral ages, hinting that the rocks were exposed and eroded over time by the scraping movement of glaciers. This evidence told the scientists that the glaciers of the Neoproterozoic were mobile. Younger rocks, from when Snowball Earth was thawing, had a narrower range of mineral ages, and more fragile grains were absent, suggesting flowing water had dissolved material that was previously ground down. At the waning of the Neoproterozoic, one of the known changes in ocean chemistry was a rise in uranium. Other research had previously explained this increase as resulting from the rise in atmospheric oxygen, 'however, our data imply that the delivery of chemical elements into the oceans also played a role in this,' Kirkland said. 'The 'lost' dissolved component in these rocks is seen 'popping back up' in changes in ocean chemistry at this time,' he added. By mapping these changes in terrestrial and marine environments, 'we are imaging the transfer of chemical elements through the Earth as a system.' The scientists reported that major glaciation events took place at least twice between 720 million and 635 million years ago. By the end of the Neoproterozoic, as Earth's icy cover began to thaw, major chemistry shifts were taking place in Earth's atmosphere and oceans. 'The end of these glaciations is marked by rapid increases in atmospheric and oceanic oxygen, possibly due to enhanced weathering of exposed rock surfaces and increased nutrient fluxes into the ocean,' Kirkland said. Such changes could have infused nutrient cycles and provided emerging life with the boost it needed to evolve into more complex forms. 'The idea that glacial debris from Neoproterozoic ice ages provided nutrients to support early animal evolution has been around for a while,' said Dr. Andrew Knoll, a professor emeritus of Earth and planetary sciences at Harvard University, who was not involved in the new research. However, questions remain about whether the minerals poured into the ocean by Neoproterozoic glaciation would have been enough to spur long-term environmental changes with biological consequences, Knoll told CNN in an email. Other research previously suggested that the impacts of glaciation events, such as the ones described in the new study, 'might well have only transient consequences — a bolus of nutrients raising primary production and perhaps increasing oxygen levels, before relaxing back to the earlier state of the environment,' Knoll said. The new findings are 'an interesting addition to the conversation,' he added. 'But the conversation continues.' From the Neoproterozoic to the present, similar processes shape climate change, including the role played by carbon dioxide (CO2) and the behavior of feedback loops, when a process feeds into an existing aspect of Earth's climate system and intensifies it. Ancient climate evidence also illuminates what happens during climate tipping points — when a threshold is crossed, triggering large-scale changes that are often irreversible. Today, Earth is heating up rapidly rather than cooling gradually over time. It took millions of years for glaciation to overtake the planet during Earth's snowball phase, while modern warming is accelerating over mere decades, 'much faster than past natural climate shifts,' Kirkland said. However, climate change's global progress is still mapped by studying the interplay of CO2 buildup, feedback loops and tipping points, he added. 'We can see how different parts of the planet are interrelated via chemical links,' he said. 'Change one part of the system, other parts also change.' Mindy Weisberger is a science writer and media producer whose work has appeared in Live Science, Scientific American and How It Works magazine.
