A fraction of the carbon that finds its way into Earth's oceans -- the black soot and charcoal residue of fires -- stays there for thousands for years, and a new first-of-its-kind analysis shows how some black carbon breaks away and hitches a ride to the ocean floor on passing particles.
The study by scientists from Rice University, the University of California, Irvine, and the University of South Carolina offers the first detailed analysis of how black carbon gets into deep ocean sediments, as well as an accounting of the types and amounts of black carbon found in those sediments.
"Our previous work showed that the black carbon in ocean sediments is ancient," said lead investigator Ellen Druffel, the Fred Kavli Professor of Earth System Science at UC Irvine. "It's anywhere from 2,000 to 5,500 years older than the organic carbon in the same sediments. That means that it either stays dissolved in the water for a long time before it's deposited or it stays trapped somewhere else -- like the soil -- for thousands of years before it enters the ocean. This new study offers the most complete picture yet of how black carbon finds its way into deep ocean sediments."
"The environmental fate of black carbon is not well-understood," said study co-author Caroline Masiello, a Rice biogeochemist who began studying black carbon with Druffel in the 1990s. "It's extraordinarily stable, and though we don't fully understand how nature breaks it down and recycles it into the deep Earth, we know that it must because otherwise we would be knee-deep in it."
Virtually all black carbon results from combustion. Soot, the airborne version of black carbon, is a key element of smoke. Charcoal is another form of black carbon. Each form is produced naturally by wildfires, as well by industry and other human activities.
Druffel and colleagues said their study did not aim to answer questions about how much black carbon people are producing today or how human-produced black carbon is affecting global climate.
"Our aim was to show how the black carbon cycle likely works in the ocean," Druffel said. "We are looking for the baseline, which is an important thing for others to have to do future studies about anthropogenic change."
Scientific interest in black carbon is high. On the one hand, a comprehensive 2013 study found that soot is a far more important player in global climate than was previously believed. On the other, there is a growing global movement among gardeners, farmers and others to use another form of black carbon -- biochar -- to both boost crop yields and to counter greenhouse emissions by locking carbon in soil for centuries.
"Whether you come at this from the point of view of reducing soot in the atmosphere or of using biochar to counter global warming, it's important to have a better understanding of where black carbon goes, how it gets there and how much of it breaks down along the way," said Masiello, associate professor of Earth science at Rice. "One of the important things about this study is that we were able to classify the kinds and types of black carbon found in seafloor sediments. This helps us narrow down the role of the ocean as a sink for both soot and charcoal."
Black carbon's journey to the bottom of the ocean begins when the material enters the water. Airborne soot gets into the ocean via rainfall and runoff from streams. Though charcoal residue can stay trapped in soils for thousands of years, runoff and erosion eventually carry some of it to the ocean as well.
The researchers used radiocarbon dating and other techniques to examine the black carbon that was buried in seafloor sediments in the Northeast Pacific that dated to about 20,000 years ago. The study's lead author, graduate student Alysha Coppola of UC Irvine, also conducted an extensive chemical analysis of the types and amounts of black carbon that were dissolved in seawater, trapped in sediments and contained in ocean-going particles, tiny specs of matter that gradually sink to the seafloor.
"We found that black carbon is taken up by particles that are produced in the water column," said Coppola. "One example would be fecal pellets that are excreted by organisms. Another is a sticky 'marine snow' that falls slowly downward to the bottom and gets buried in sediments."
Coppola said black carbon tends to stay dissolved in seawater, and only occasionally gets snagged by a passing marine particle.
"I'm surprised that given how much black carbon is produced, most of it remains in the ocean for thousands of years," Coppola said. "It's very interesting that only a relatively small amount with a certain type of chemistry is removed to the ocean floor."
The National Science Foundation funded the study. Co-authors include Lori Ziolkowski of the University of South Carolina.
High-resolution IMAGES are available for download at:
CAPTION: Sediment traps, like this one being deployed from the research vessel New Horizon, were used to sample black carbon in particles that sank to the bottom of the Northeast Pacific.
CREDIT: E. Druffel/UC Irvine
CAPTION: Ellen Druffel
CREDIT: UC Irvine
CAPTION: Caroline Masiello
CREDIT: Rice University
CAPTION: Alysha Coppola
CREDIT: UC Irvine
A copy of the Geophysical Research Letters paper is available at:
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Located on a 300-acre forested campus in Houston, Rice University is consistently ranked among the nation's top 20 universities by U.S. News & World Report. Rice has highly respected schools of Architecture, Business, Continuing Studies, Engineering, Humanities, Music, Natural Sciences and Social Sciences and is home to the Baker Institute for Public Policy. With 3,920 undergraduates and 2,567 graduate students, Rice's undergraduate student-to-faculty ratio is 6.3-to-1. Its residential college system builds close-knit communities and lifelong friendships, just one reason why Rice has been ranked No. 1 for best quality of life multiple times by the Princeton Review and No. 2 for "best value" among private universities by Kiplinger's Personal Finance.
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