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1. The Deep Soil Organic Carbon Response to Global Change

Author

Hicks Pries, Caitlin E, Ryals, Rebecca, Zhu, Biao, Min, Kyungjin, Cooper, Alexia, Goldsmith, Sarah, Pett-Ridge, Jennifer, Torn, Margaret, and Berhe, Asmeret Asefaw

Subjects
Agricultural, Veterinary and Food Sciences, Biological Sciences, Ecology, Forestry Sciences, Life on Land, Climate Action, deep soil organic carbon, global change, climate change, elevated CO2, land use and land cover change, Environmental Sciences, Agricultural and Veterinary Sciences, Evolutionary Biology, Agricultural, veterinary and food sciences, Biological sciences, Environmental sciences
Abstract

Over 70% of soil organic carbon (SOC) is stored at a depth greater than 20 cm belowground. A portion of this deep SOC actively cycles on annual to decadal timescales and is sensitive to global change. However, deep SOC responses to global change likely differ from surface SOC responses because biotic controls on SOC cycling become weaker as mineral controls predominate with depth. Here, we synthesize the current information on deep SOC responses to the global change drivers of warming, shifting precipitation, elevated CO2, and land use and land cover change. Most deep SOC responses can only be hypothesized because few global change studies measure deep soils, and even fewer global change experiments manipulate deep soils. We call on scientists to incorporate deep soils into their manipulations, measurements, and models so that the response of deep SOC can be accounted for in projections of nature-based climate solutions and terrestrial feedbacks to climate change.

Published
2023

2. Climate Warming Alters Nutrient Storage in Seasonally Dry Forests: Insights From a 2,300 m Elevation Gradient

Author

Yang, Yang, Berhe, Asmeret Asefaw, Barnes, Morgan E, Moreland, Kimber C, Tian, Zhiyuan, Kelly, Anne E, Bales, Roger C, O'Geen, Anthony T, Goulden, Michael L, Hartsough, Peter, and Hart, Stephen C

Subjects
Climate Action, Atmospheric Sciences, Geochemistry, Oceanography, Meteorology & Atmospheric Sciences
Abstract

Understanding potential response of forest carbon (C) and nutrient storage to warming is important for climate mitigation policies. Unfortunately, those responses are difficult to predict in seasonally dry forests, in part, because ecosystem processes are highly sensitive to both changes in temperature and precipitation. We investigated how warming might alter stocks of C, nitrogen (N), and phosphorus (P) in vegetation and the entire regolith (soil + weathered bedrock or “saprock”) using a space-for-time substitution along a bioclimatic gradient in the Sierra Nevada, California. The pine-oak and mixed-conifer forests between 1,160–2,015 m elevation have more optimal climates (not too dry or hot) for ecosystem productivity, soil weathering, and cycling of essential elements than the oak savannah (405 m) and subalpine forest (2,700 m). We found decreases in overstory vegetation nutrient stocks with decreasing elevation because of enhanced water limitation and greater occurrence of disturbances. Stocks of C, N, and P in the entire regolith peaked at the pine-oak and mixed-conifer forests across the bioclimatic gradient, driven by thicker regolith profiles and greater nutrient input rates. These observations suggest long-term warming will decrease ecosystem nutrient storage at the warmer, transitional pine-oak zone, but will increase nutrient storage at the colder, subalpine zone. Assuming steady-state conditions, we found the mean residence time of ecosystem C decreased with projected rising air temperatures and increased following a major drought event across the bioclimatic gradient. Our study emphasizes potentially elevation-dependent changes in nutrient storage and C persistence with warming in seasonally dry forests.

Published
2022

4. Impacts of climate and forest management on suspended sediment source and transport in montane headwater catchments

Author

Yang, Yang, Safeeq, Mohammad, Wagenbrenner, Joseph, Berhe, Asmeret Asefaw, and Hart, Stephen

Subjects
climate change, drought, forest thinning, hysteresis analysis, Mediterranean-climate, prescribed fire, Sierra Nevada, soil erosion
Abstract

Suspended sediment transport in montane headwaters is important to water quality and nutrient balances. However, predictions of sediment source and transport can be difficult, in part, because of a changing climate and increasing frequencies of disturbances. We used observations from 10 headwater streams in water year (WY; starting on 1st October ending on 30th September) 2007–2009 and 2013–2018 to determine the potential impacts of climate and forest management on suspended sediment delivery. We analysed hysteretic responses of suspended sediment for 76 events in five headwater catchments within a snow-dominated site and another five within a lower-elevation, rain-snow transition site, in the mixed-conifer zone of California's Sierra Nevada. Hysteresis patterns were predominantly clockwise at both sites, suggesting localized sediment sources such as streambeds and banks. The warmer, transition site exhibited a lower proportion of clockwise-loop events, faster transport speed and higher peak sediment concentrations than the snow-dominated site. This suggests extended sediment sources and increases in transport can occur as currently snow-dominated areas become rain-snow transitional. Over the nine water years, we observed similar hysteresis effects amongst years under drought, near-average, and extremely wet conditions. Hence, fluctuations in precipitation amounts across years may not influence sediment source area substantially. Furthermore, we compared hysteresis metrics between the control, thin only, burn only and thin combined with burn catchments during the posttreatment period (WY 2013– 2018). Hysteresis effects remained unchanged amongst treatments, which may be attributed to the combinations of low-intensity operations implemented with best management practises combined with a four-year drought (WY 2013–2016). Taken together, sediment sources in small headwater catchments will probably remain localized with changing precipitation levels and low-intensity management operations, but it may be extended and potentially lead to higher sediment yields as the main hydrologic input shifts from primarily snow to a mix of rain and snow.

Published
2022

5. Dairy Manure Co-composting with Wood Biochar Plays a Critical Role in Meeting Global Methane Goals

Author

Harrison, Brendan P, Gao, Si, Gonzales, Melinda, Thao, Touyee, Bischak, Elena, Ghezzehei, Teamrat Afewerki, Berhe, Asmeret Asefaw, Diaz, Gerardo, and Ryals, Rebecca A

Subjects
Climate Action, Charcoal, Composting, Goals, Manure, Methane, Soil, Wood, composting, biochar, livestock, natural climate solutions, climate change mitigation, methane, Environmental Sciences
Abstract

Livestock are the largest source of anthropogenic methane (CH4) emissions, and in intensive dairy systems, manure management can contribute half of livestock CH4. Recent policies such as California's short-lived climate pollutant reduction law (SB 1383) and the Global Methane Pledge call for cuts to livestock CH4 by 2030. However, investments in CH4 reduction strategies are primarily aimed at liquid dairy manure, whereas stockpiled solids remain a large source of CH4. Here, we measure the CH4 and net greenhouse gas reduction potential of dairy manure biochar-composting, a novel manure management strategy, through a composting experiment and life-cycle analysis. We found that biochar-composting reduces CH4 by 79%, compared to composting without biochar. In addition to reducing CH4 during composting, we show that the added climate benefit from biochar production and application contributes to a substantially reduced life-cycle global warming potential for biochar-composting: -535 kg CO2e Mg-1 manure compared to -194 kg CO2e Mg-1 for composting and 102 kg CO2e Mg-1 for stockpiling. If biochar-composting replaces manure stockpiling and complements anaerobic digestion, California could meet SB 1383 with 132 less digesters. When scaled up globally, biochar-composting could mitigate 1.59 Tg CH4 yr-1 while doubling the climate change mitigation potential from dairy manure management.

Published
2022

6. Burn Intensity Drives the Alteration of Phenolic Lignin to (Poly) Aromatic Hydrocarbons as Revealed by Pyrolysis Gas Chromatography-Mass Spectrometry (Py-GC/MS).

Author

Chen, Huan, Wang, Jun-Jian, Ku, Pei-Jia, Tsui, Martin Tsz-Ki, Abney, Rebecca B, Berhe, Asmeret Asefaw, Zhang, Qiang, Burton, Sarah D, Dahlgren, Randy A, and Chow, Alex T

Subjects
alkyl side chain, black carbon/nitrogen, forest fuel reduction, prescribed fire, wildfire, Environmental Sciences
Abstract

High-intensity wildfires alter the chemical composition of organic matter, which is expected to be distinctly different from low-intensity prescribed fires. Herein, we used pyrolysis gas chromatography/mass spectrometry (Py-GC/MS), in conjunction with solid-state 13C nuclear magnetic resonance (NMR) and Fourier transform infrared (FT-IR) spectroscopy, to assess chemical alterations from three wildfires and a long-term frequent prescribed fire site. Our results showed that black ash formed under moderate intensity burns contained less aromatic (ArH), polyaromatic hydrocarbon (PAH), and nitrogen-containing compounds (Ntg) but more lignin (LgC) and phenol compounds (PhC), compared to white ash formed under high intensity burns. Both 13C NMR and FT-IR confirmed a higher relative percentage of carboxyl carbon in white ash, indicating the potential for higher water solubility and more mobile carbon, relative to black ash. Compared to wildfires, ash from low-intensity prescribed fire contained less ArH, PAH, and Ntg and more LgC and PhC. Controlled laboratory burning trials indicated that organic matter alteration was sensitive to the burn temperature, but not related to the fuel type (pine vs fir) nor oxygen absence/presence at high burn temperatures. This study concludes that higher burn temperatures resulted in higher (poly)aromatic carbon/nitrogen and lower lignin/phenol compounds.

Published
2022

8. Ten simple rules for creating and sustaining antiracist graduate programs

Author

Perez-Lopez, Edgar, Gavrilova, Larisa, Disla, Janice, Goodlad, Melissa, Ngo, Dalena, Seshappan, Arabi, Sharmin, Farhana, Cisneros, Jesus, Kello, Christopher T, and Berhe, Asmeret Asefaw

Subjects
Education, Specialist Studies In Education, Law and Legal Studies, Reduced Inequalities, Peace, Justice and Strong Institutions, Quality Education, COVID-19, Ethnicity, Humans, Pandemics, Racial Groups, Racism, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics
Abstract

In 2020, the combination of police killings of unarmed Black people, including George Floyd, Breonna Taylor, and Ahmaud Arbery, and the Coronavirus Disease 2019 (COVID-19) pandemic brought about public outrage over long-standing inequalities in society. The events of 2020 ignited global attention to systemic racism and racial inequalities, including the lack of diversity, equity, and inclusion in the academy and especially in science, technology, engineering, mathematics, and medicine (STEMM) fields. Racial and ethnic diversity in graduate programs in particular warrants special attention as graduate students of color report experiencing alarming rates of racism, discrimination, microaggressions, and other exclusionary behaviors. As part of the Graduate Dean's Advisory Council on Diversity (GDACD) at the University of California Merced, the authors of this manuscript held a year-long discussion on these issues and ways to take meaningful action to address these persistent issues of injustices. We have outlined 10 rules to help graduate programs develop antiracist practices to promote racial and ethnic justice, equity, diversity, and inclusion (JEDI) in the academy. We focus on efforts to address systemic causes of the underrepresentation and attrition of students from minoritized communities. The 10 rules are developed to allow graduate groups to formulate and implement rules and policies to address root causes of underrepresentation of minoritized students in graduate education.

Published
2022

9. What's soil got to do with climate change?

Author

Berhe, Asmeret Asefaw and Sequential Potential

Subjects
soil science, climate change, carbon sequestration, soil health, global warming
Abstract

This comic is based on Prof. Asmeret Asefaw Berhe's TEDtalk "A climate change solution that's right under our feet" (https://www.ted.com/talks/asmeret_asefaw_berhe_a_climate_change_solution_that_s_right_under_our_feet?language=en) Abstract from TED.com: There's two times more carbon in the earth's soil than in all of its vegetation and the atmosphere -- combined. Biogeochemist Asmeret Asefaw Berhe dives into the science of soil and shares how we could use its awesome carbon-trapping power to offset climate change. "[Soil] represents the difference between life and lifelessness in the earth system, and it can also help us combat climate change -- if we can only stop treating it like dirt," she says.

Published
2021

10. Deep in the Sierra Nevada critical zone: saprock represents a large terrestrial organic carbon stock

Author

Moreland, Kimber, Tian, Zhiyuan, Berhe, Asmeret Asefaw, McFarlane, Karis J, Hartsough, Peter, Hart, Stephen C, Bales, Roger, and O’Geen, Anthony T

Subjects
Climate Action, soil carbon, weathered bedrock, carbon biogeochemistry, saprock, deep soil carbon, carbon storage, critical zone, Meteorology & Atmospheric Sciences
Abstract

Large uncertainty remains in the spatial distribution of deep soil organic carbon (OC) storage and how climate controls belowground OC. This research aims to quantify OC stocks, characterize soil OC age and chemical composition, and evaluate climatic impacts on OC storage from the soil surface through the deep critical zone to bedrock. These objectives were carried out at four sites along a bio-climosequence in the Sierra Nevada, California. On average, 74% of OC was stored below the A horizon, and up to 30% of OC was stored in saprock (friable weakly weathered bedrock). Radiocarbon, spectroscopic, and isotopic analyses revealed the coexistence of very old organic matter (OM) (mean radiocarbon age = 20 300 years) with relatively recent OM (mean radiocarbon age = 4800 years) and highly decomposed organic compounds with relatively less decomposed material in deep soil and saprock. This co-mingling of OM suggests OC is prone to both active cycling and long-term protection from degradation. In addition to having direct effects on OC cycling, climate indirectly controls deep OC storage through its impact on the degree of regolith weathering (e.g. thickening). Although deep OC concentrations are low relative to soil, thick saprock represents a large, previously unrealized OC pool.

Published
2021

12. Ten simple rules for building an antiracist lab.

Author

Chaudhary, V Bala and Berhe, Asmeret Asefaw

Subjects
Bioinformatics, Mathematical Sciences, Biological Sciences, Information and Computing Sciences
Abstract

Demographics of the science, technology, engineering, and mathematics (STEM) workforce and student body in the US and Europe continue to show severe underrepresentation of Black, Indigenous, and people of color (BIPOC). Among the documented causes of the persistent lack of diversity in STEM are bias, discrimination, and harassment of members of underrepresented minority groups (URMs). These issues persist due to continued marginalization, power imbalances, and lack of adequate policies against misconduct in academic and other scientific institutions. All scientists can play important roles in reversing this trend by shifting the culture of academic workplaces to intentionally implement equitable and inclusive policies, set norms for acceptable workplace conduct, and provide opportunities for mentorship and networking. As scientists are increasingly acknowledging the lack of racial and ethnic diversity in science, there is a need for clear direction on how to take antiracist action. Here we present 10 rules to help labs develop antiracists policies and action in an effort to promote racial and ethnic diversity, equity, and inclusion in science.

Published
2020

13. The influence of soil age on ecosystem structure and function across biomes.

Author

Delgado-Baquerizo, Manuel, Reich, Peter B, Bardgett, Richard D, Eldridge, David J, Lambers, Hans, Wardle, David A, Reed, Sasha C, Plaza, César, Png, G Kenny, Neuhauser, Sigrid, Berhe, Asmeret Asefaw, Hart, Stephen C, Hu, Hang-Wei, He, Ji-Zheng, Bastida, Felipe, Abades, Sebastián, Alfaro, Fernando D, Cutler, Nick A, Gallardo, Antonio, García-Velázquez, Laura, Hayes, Patrick E, Hseu, Zeng-Yei, Pérez, Cecilia A, Santos, Fernanda, Siebe, Christina, Trivedi, Pankaj, Sullivan, Benjamin W, Weber-Grullon, Luis, Williams, Mark A, and Fierer, Noah

Subjects
Bacteria, Fungi, Plants, Soil, Ecosystem, Biodiversity, Biomass, Climate, Time Factors, Biota, Microbiota
Abstract

The importance of soil age as an ecosystem driver across biomes remains largely unresolved. By combining a cross-biome global field survey, including data for 32 soil, plant, and microbial properties in 16 soil chronosequences, with a global meta-analysis, we show that soil age is a significant ecosystem driver, but only accounts for a relatively small proportion of the cross-biome variation in multiple ecosystem properties. Parent material, climate, vegetation and topography predict, collectively, 24 times more variation in ecosystem properties than soil age alone. Soil age is an important local-scale ecosystem driver; however, environmental context, rather than soil age, determines the rates and trajectories of ecosystem development in structure and function across biomes. Our work provides insights into the natural history of terrestrial ecosystems. We propose that, regardless of soil age, changes in the environmental context, such as those associated with global climatic and land-use changes, will have important long-term impacts on the structure and function of terrestrial ecosystems across biomes.

Published
2020

14. Phosphorus Speciation in Atmospherically Deposited Particulate Matter and Implications for Terrestrial Ecosystem Productivity

Author

O’Day, Peggy A, Nwosu, Ugwumsinachi G, Barnes, Morgan E, Hart, Stephen C, Berhe, Asmeret Asefaw, Christensen, John N, and Williams, Kenneth H

Subjects
Colorado, Ecosystem, Particle Size, Particulate Matter, Phosphorus, Environmental Sciences
Abstract

Chemical forms of phosphorus (P) in airborne particulate matter (PM) are poorly known and do not correlate with solubility or extraction measurements commonly used to infer speciation. We used P X-ray absorption near-edge structure (XANES) and 31P nuclear magnetic resonance (NMR) spectroscopies to determine P species in PM collected at four mountain sites (Colorado and California). Organic P species dominated samples from high elevations, with organic P estimated at 65-100% of total P in bulk samples by XANES and 79-88% in extracted fractions (62-84% of total P) by NMR regardless of particle size (≥10 or 1-10 μm). Phosphorus monoester and diester organic species were dominant and present in about equal proportions, with low fractions of inorganic P species. By comparison, PM from low elevation contained mixtures of organic and inorganic P, with organic P estimated at 30-60% of total P. Intercontinental PM transport determined from radiogenic lead (Pb) isotopes varied from 0 to 59% (mean 37%) Asian-sourced Pb at high elevation, whereas stronger regional PM inputs were found at low elevation. Airborne flux of bioavailable P to high-elevation ecosystems may be twice as high as estimated by global models, which will disproportionately affect net primary productivity.

Published
2020

15. Phosphorus Speciation in Atmospherically Deposited Particulate Matter and Implications for Terrestrial Ecosystem Productivity.

Author

O'Day, Peggy A, Nwosu, Ugwumsinachi G, Barnes, Morgan E, Hart, Stephen C, Berhe, Asmeret Asefaw, Christensen, John N, and Williams, Kenneth H

Subjects
Phosphorus, Ecosystem, Particle Size, Colorado, Particulate Matter, Environmental Sciences
Abstract

Chemical forms of phosphorus (P) in airborne particulate matter (PM) are poorly known and do not correlate with solubility or extraction measurements commonly used to infer speciation. We used P X-ray absorption near-edge structure (XANES) and 31P nuclear magnetic resonance (NMR) spectroscopies to determine P species in PM collected at four mountain sites (Colorado and California). Organic P species dominated samples from high elevations, with organic P estimated at 65-100% of total P in bulk samples by XANES and 79-88% in extracted fractions (62-84% of total P) by NMR regardless of particle size (≥10 or 1-10 μm). Phosphorus monoester and diester organic species were dominant and present in about equal proportions, with low fractions of inorganic P species. By comparison, PM from low elevation contained mixtures of organic and inorganic P, with organic P estimated at 30-60% of total P. Intercontinental PM transport determined from radiogenic lead (Pb) isotopes varied from 0 to 59% (mean 37%) Asian-sourced Pb at high elevation, whereas stronger regional PM inputs were found at low elevation. Airborne flux of bioavailable P to high-elevation ecosystems may be twice as high as estimated by global models, which will disproportionately affect net primary productivity.

Published
2020

16. Quantifying Uncertainties in Sequential Chemical Extraction of Soil Phosphorus Using XANES Spectroscopy

Author

Gu, Chunhao, Dam, Than, Hart, Stephen C, Turner, Benjamin L, Chadwick, Oliver A, Berhe, Asmeret Asefaw, Hu, Yongfeng, and Zhu, Mengqiang

Subjects
Minerals, Phosphates, Phosphorus, Soil, Soil Pollutants, X-Ray Absorption Spectroscopy, Environmental Sciences
Abstract

Sequential chemical extraction has been widely used to study soil phosphorus (P) dynamics and inform nutrient management, but its efficacy for assigning P into biologically meaningful pools remains unknown. Here, we evaluated the accuracy of the modified Hedley extraction scheme using P K-edge X-ray absorption near-edge structure (XANES) spectroscopy for nine carbonate-free soil samples with diverse chemical and mineralogical properties resulting from different degrees of soil development. For most samples, the extraction markedly overestimated the pool size of calcium-bound P (Ca-P, extracted by 1 M HCl) due to (1) P redistribution during the alkaline extractions (0.5 M NaHCO3 and then 0.1 M NaOH), creating new Ca-P via formation of Ca phosphates between NaOH-desorbed phosphate and exchangeable Ca2+ and/or (2) dissolution of poorly crystalline Fe and Al oxides by 1 M HCl, releasing P occluded by these oxides into solution. The first mechanism may occur in soils rich in well-crystallized minerals and exchangeable Ca2+ regardless of the presence or absence of CaCO3, whereas the second mechanism likely operates in soils rich in poorly crystalline Fe and Al minerals. The overestimation of Ca-P simultaneously caused underestimation of the pools extracted by the alkaline solutions. Our findings identify key edaphic parameters that remarkably influenced the extractions, which will strengthen our understanding of soil P dynamics using this widely accepted procedure.

Published
2020

17. Plant footprint decreases the functional diversity of molecules in topsoil organic matter after millions of years of ecosystem development

Author

European Commission, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Junta de Andalucía, Sáez-Sandino, Tadeo [0000-0001-9539-4716], Gallardo, Antonio [0000-0002-2674-4265], Eldridge, David J. [0000-0002-2191-486X], Berhe, Asmeret Asefaw [0000-0002-6986-7943], Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Sáez-Sandino, Tadeo, Gallardo, Antonio, Eldridge, David J., Berhe, Asmeret Asefaw, Doetterl, Sebastian, Delgado-Baquerizo, Manuel, European Commission, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Junta de Andalucía, Sáez-Sandino, Tadeo [0000-0001-9539-4716], Gallardo, Antonio [0000-0002-2674-4265], Eldridge, David J. [0000-0002-2191-486X], Berhe, Asmeret Asefaw [0000-0002-6986-7943], Delgado-Baquerizo, Manuel [0000-0002-6499-576X], Sáez-Sandino, Tadeo, Gallardo, Antonio, Eldridge, David J., Berhe, Asmeret Asefaw, Doetterl, Sebastian, and Delgado-Baquerizo, Manuel

Abstract

Aim Theory suggests that the diversity of molecules in soil organic matter (SOM functional diversity) provides key insights on multiple ecosystem services. We aimed to investigate how and why SOM functional diversity and composition change as topsoils develop, and its implications for key soil functions (e.g., from nutrient pool to water regulation). Location We reported data on 16 soil chronosequences globally distributed in nine countries from six continents. Time Period 2016–2017. Major Taxa Studied Soil microbes (bacteria and fungi) and vascular plants. Methods SOM functional diversity and composition without mineral interference were measured using diffuse reflectance mid-infrared Fourier transform spectroscopy (DRIFT). We aimed to characterize the main environmental factors related to SOM functional diversity and composition. Also, we calculated the links among SOM functional diversity and key soil functions. Results We found that SOM functional diversity declines after millions of years of soil formation (pedogenesis). We further showed that increases in plant cover and productivity led to a higher ratio of reduced (e.g., alkanes) over oxidized carbon forms (i.e., C: O-functional groups ratio), which was positively correlated to SOM functional diversity as soils age. Our findings indicated that the plant footprint (i.e., the accumulation of plant-derived material promoting the C: O-functional group ratio) would explain the reduction of SOM functional diversity as ecosystems develop. Moreover, the dissimilarity in SOM composition consistently increased with soil age, with the soil development stage emerging as the main predictor of SOM dissimilarity across contrasting biomes. Main Conclusions Our global survey contextualized the natural history of SOM functional diversity and composition during long-term soil development. Together, we showed how plant footprint drives the losses of SOM functional diversity with increasing age, which might provide a novel mecha

Published
2024

18. Changes in belowground biodiversity during ecosystem development.

Author

Hayes, Patrick, Hseu, Zeng-Yei, Kirchmair, Martin, Peña-Ramírez, Victor, Pérez, Cecilia, Reed, Sasha, Santos, Fernanda, Siebe, Christina, Sullivan, Benjamin, Weber-Grullon, Luis, Fierer, Noah, Delgado-Baquerizo, Manuel, Bardgett, Richard, Vitousek, Peter, Maestre, Fernando, Williams, Mark, Eldridge, David, Lambers, Hans, Neuhauser, Sigrid, Gallardo, Antonio, García-Velázquez, Laura, Sala, Osvaldo, Abades, Sebastián, Alfaro, Fernando, Bowker, Matthew, Currier, Courtney, Cutler, Nick, Berhe, Asmeret Asefaw, and Hart, Stephen

Subjects
acidification, ecosystem development, global scale, soil biodiversity, soil chronosequences, Biodiversity, Models, Biological
Abstract

Belowground organisms play critical roles in maintaining multiple ecosystem processes, including plant productivity, decomposition, and nutrient cycling. Despite their importance, however, we have a limited understanding of how and why belowground biodiversity (bacteria, fungi, protists, and invertebrates) may change as soils develop over centuries to millennia (pedogenesis). Moreover, it is unclear whether belowground biodiversity changes during pedogenesis are similar to the patterns observed for aboveground plant diversity. Here we evaluated the roles of resource availability, nutrient stoichiometry, and soil abiotic factors in driving belowground biodiversity across 16 soil chronosequences (from centuries to millennia) spanning a wide range of globally distributed ecosystem types. Changes in belowground biodiversity during pedogenesis followed two main patterns. In lower-productivity ecosystems (i.e., drier and colder), increases in belowground biodiversity tracked increases in plant cover. In more productive ecosystems (i.e., wetter and warmer), increased acidification during pedogenesis was associated with declines in belowground biodiversity. Changes in the diversity of bacteria, fungi, protists, and invertebrates with pedogenesis were strongly and positively correlated worldwide, highlighting that belowground biodiversity shares similar ecological drivers as soils and ecosystems develop. In general, temporal changes in aboveground plant diversity and belowground biodiversity were not correlated, challenging the common perception that belowground biodiversity should follow similar patterns to those of plant diversity during ecosystem development. Taken together, our findings provide evidence that ecological patterns in belowground biodiversity are predictable across major globally distributed ecosystem types and suggest that shifts in plant cover and soil acidification during ecosystem development are associated with changes in belowground biodiversity over centuries to millennia.

Published
2019

19. Stabilization Mechanisms and Decomposition Potential of Eroded Soil Organic Matter Pools in Temperate Forests of the Sierra Nevada, California

Author

Stacy, Erin M, Berhe, Asmeret Asefaw, Hunsaker, Carolyn T, Johnson, Dale W, Meding, S Mercer, and Hart, Stephen C

Subjects
Life on Land, erosion, stabilization, soil organic matter, montane, temperate coniferous forests, Geophysics
Abstract

The lateral destination and potential decomposition of soil organic matter mobilized by soil erosion depends on factors such as the amount and type of precipitation, topography, the nature of mobilized organic matter (OM), potential mixing with mineral particles, and the stabilization mechanisms of the soil OM. This study examined how the relative distribution of carbon (C) and nitrogen (N) in different OM fractions varied in soils from eroding slopes and in eroded sediments in a series of low-order forested catchments in the western Sierra Nevada, California. We found that precipitation amount played a major role in mobilizing OM. More than 40% of the OM exported from these forested catchments was free particulate OM, or OM physically protected inside relatively less stable macroaggregates, compared to OM inside microaggregates or chemically associated with soil minerals. Years with high amounts of precipitation generally transported more mineral-associated OM, with lower C and N concentrations, while sediment transported in drier years was more enriched in unprotected, coarse particulate OM derived from surficial soils. When incubated under the same conditions, sediment C (from material captured in settling basins) produced 72–97% more CO 2 during decomposition than soil C did. Our results suggest that without stabilization through burial or reconfigured organomineral associations, this sediment OM is prone to decomposition, which may contribute to little to no terrestrial CO 2 sink induced from erosion in these Mediterranean montane forest ecosystems.

Published
2019

24. Subsurface plant‐accessible water in mountain ecosystems with a Mediterranean climate

Author

Klos, P Zion, Goulden, Michael L, Riebe, Clifford S, Tague, Christina L, O’Geen, A Toby, Flinchum, Brady A, Safeeq, Mohammad, Conklin, Martha H, Hart, Stephen C, Berhe, Asmeret Asefaw, Hartsough, Peter C, Holbrook, W Steven, and Bales, Roger C

Subjects
Life on Land, critical zone, regolith, vegetation
Abstract

Enhanced understanding of subsurface water storage will improve prediction of future impacts of climate change, including drought, forest mortality, wildland fire, and strained water security. Previous research has examined the importance of plant-accessible water in soil, but in upland landscapes within Mediterranean climates, soil often accounts for only a fraction of subsurface water storage. We draw insights from previous research and a case study of the Southern Sierra Critical Zone Observatory to define attributes of subsurface storage; review observed patterns in their distribu-tion; highlight nested methods for estimating them across scales; and showcase the fundamental processes controlling their formation. We review observations that highlight how forest ecosystems subsist on lasting plant-accessible stores of subsurface water during the summer dry period and during multiyear droughts. The data suggest that trees in these forest ecosystems are rooted deeply in the weathered, highly porous saprolite or saprock, which reaches up to 10–20 m beneath the surface. This review confirms that the system harbors large volumes of subsurface water and shows that they are vital to supporting the ecosystem through the summer dry season and extended droughts. This research enhances understanding of deep subsurface water storage across landscapes and identifies key remaining challenges in predicting and managing response to climate and land use change in mountain ecosystems of the Sierra Nevada and in other Mediterranean climates worldwide. This article is categorized under: Science of Water > Hydrological Processes Science of Water > Water Extremes Water and Life > Nature of Freshwater Ecosystems.

Published
2018

27. Erosional redistribution of topsoil controls soil nitrogen dynamics

Author

Berhe, Asmeret Asefaw and Torn, Margaret S

Subjects
Environmental Sciences, Soil Sciences, Life on Land, Soil erosion, Soil nitrogen, Soil organic matter, Coupled C and N cycling, Other Chemical Sciences, Geochemistry, Environmental Science and Management, Agronomy & Agriculture, Environmental management
Abstract

In recent years, the role of soil erosion on terrestrial carbon sequestration had been the focus of a growing number of studies. However, relatively little attention has been paid so far to the role of erosion on the lateral distribution of soil nitrogen (N) and the role of geomorphic processes on soil N dynamics. Here, we present primary data on the stock of nitrogen in soil and its rate of erosion at a relatively undisturbed, zero-order watershed in northern California. Erosion transports 0.26–0.47 g N m⁻² year⁻¹ from eroding slope positions (Summit and Slope), and about two-thirds of the eroded N enters depositional landform positions (Hollow and Plain). Our results show that depositional-position soil profiles contain up to 3 times more N than soil profiles in the eroding positions. More than 92% of all soil nitrogen was chemically bound to soil minerals in all the landform positions, compared to 2–4% each found in the free light and occluded light fractions. Nitrogen associated with the free light fraction in topsoil is particularly susceptible to loss by soil erosion. By comparison, soil N associated with the aggregate-protected occluded light fractions and the mineral-associated dense fractions is likely to be protected from gaseous and dissolved losses. On average, we found that soil N has mean residence time of 694 years in eroding landform positions, compared to 2951 years in depositional landform positions. Our results also show that microbial processing of organic matter exerts strong control on overall soil N storage and N stabilized through sorptive interactions with soil minerals only in poorly drained depositional landform positions. Soil erosion exerts important control on stock, distribution, and long-term fate of soil N in dynamic landscapes.

Published
2017

29. Tracing the source of soil organic matter eroded from temperate forest catchments using carbon and nitrogen isotopes

Author

McCorkle, Emma P, Berhe, Asmeret Asefaw, Hunsaker, Carolyn T, Johnson, Dale W, McFarlane, Karis J, Fogel, Marilyn L, and Hart, Stephen C

Subjects
Life on Land, Erosion, Radiocarbon, Sediment sources, Sierra Nevada, Soil organic matter, Stable isotopes
Abstract

Soil erosion continuously redistributes soil and associated soil organic matter (SOM) on the Earth's surface, with important implications for biogeochemical cycling of essential elements and terrestrial carbon sequestration. Despite the importance of soil erosion, surprisingly few studies have evaluated the sources of eroded carbon (C). We used natural abundance levels of the stable and radioactive isotopes of C (13C and 14C) and stable isotope of nitrogen (15N) to elucidate the origins of SOM eroded from low-order catchments along the western slopes of the Sierra Nevada of California, USA. Our work was conducted in two relatively undisturbed catchments (low elevation = 1800 m, and high elevation = 2300 m) of the Kings River Experimental Watersheds (KREW) in the Sierra National Forest. Sediment captured in basins at the outlet of each gauged watershed were compared to possible source materials, which included: upland surficial organic horizons (i.e., forest floor) and mineral soils (0–0.6 m) from three landform positions (i.e., crest, backslope, and toeslope), stream bank soils (0–0.6 m), and stream-bed materials (0–0.05 m). We found that most of the organic matter (OM) in the captured sediments was composed of O-horizon material that had high C concentrations. Radiocarbon analyses also showed that the captured OM is composed of modern (post-1950) C, with fraction modern values at or above 1.0. Our results suggest that surface (sheet) erosion, as opposed to channeling through established streams and episodic mass wasting events, is likely the largest source of sediment exported out of these minimally disturbed, headwater catchments. The erosional export of sediment with a high concentration of C, especially in the form of relatively undecomposed litter from the O horizon, suggests that a large fraction of the exported C is likely to be decomposed during or after erosion; hence, it is unlikely that soil erosion acts as a significant net sink for atmospheric CO2 in these low-order, temperate forest catchments.

Published
2016

32. Controls on timescales of soil organic carbon persistence across sub‐Saharan Africa

Author

von Fromm, Sophie F., primary, Doetterl, Sebastian, additional, Butler, Benjamin M., additional, Aynekulu, Ermias, additional, Berhe, Asmeret Asefaw, additional, Haefele, Stephan M., additional, McGrath, Steve P., additional, Shepherd, Keith D., additional, Six, Johan, additional, Tamene, Lulseged, additional, Tondoh, Ebagnerin J., additional, Vågen, Tor‐Gunnar, additional, Winowiecki, Leigh A., additional, Trumbore, Susan E., additional, and Hoyt, Alison M., additional

Published
2023
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35. Soil and human security in the 21st century

Author

Amundson, Ronald, Berhe, Asmeret Asefaw, Hopmans, Jan W, Olson, Carolyn, Sztein, A Ester, and Sparks, Donald L

Subjects
Zero Hunger, Climate Action, Agriculture, Climate Change, Conservation of Natural Resources, Fertilizers, Food Supply, Fossil Fuels, Humans, Nitrogen, Soil, Survival, General Science & Technology
Abstract

Human security has and will continue to rely on Earth's diverse soil resources. Yet we have now exploited the planet's most productive soils. Soil erosion greatly exceeds rates of production in many agricultural regions. Nitrogen produced by fossil fuel and geological reservoirs of other fertilizers are headed toward possible scarcity, increased cost, and/or geopolitical conflict. Climate change is accelerating the microbial release of greenhouse gases from soil organic matter and will likely play a large role in our near-term climate future. In this Review, we highlight challenges facing Earth's soil resources in the coming century. The direct and indirect response of soils to past and future human activities will play a major role in human prosperity and survival.

Published
2015

36. Soil science. Soil and human security in the 21st century.

Author

Amundson, Ronald, Berhe, Asmeret Asefaw, Hopmans, Jan W, Olson, Carolyn, Sztein, A Ester, and Sparks, Donald L

Subjects
Humans, Nitrogen, Soil, Fertilizers, Conservation of Natural Resources, Fossil Fuels, Survival, Agriculture, Food Supply, Climate Change, General Science & Technology
Abstract

Human security has and will continue to rely on Earth's diverse soil resources. Yet we have now exploited the planet's most productive soils. Soil erosion greatly exceeds rates of production in many agricultural regions. Nitrogen produced by fossil fuel and geological reservoirs of other fertilizers are headed toward possible scarcity, increased cost, and/or geopolitical conflict. Climate change is accelerating the microbial release of greenhouse gases from soil organic matter and will likely play a large role in our near-term climate future. In this Review, we highlight challenges facing Earth's soil resources in the coming century. The direct and indirect response of soils to past and future human activities will play a major role in human prosperity and survival.

Published
2015

40. Impact of fire on active layer and permafrost microbial communities and metagenomes in an upland Alaskan boreal forest.

Author

Taş, Neslihan, Prestat, Emmanuel, McFarland, Jack W, Wickland, Kimberley P, Knight, Rob, Berhe, Asmeret Asefaw, Jorgenson, Torre, Waldrop, Mark P, and Jansson, Janet K

Subjects
Carbon, Soil Microbiology, Fires, Biodiversity, Alaska, Metagenome, Permafrost, Taiga, boreal forest, climate change, metagenomics, microbial community response, permafrost, wildfire, Microbiology, Environmental Sciences, Biological Sciences, Technology
Abstract

Permafrost soils are large reservoirs of potentially labile carbon (C). Understanding the dynamics of C release from these soils requires us to account for the impact of wildfires, which are increasing in frequency as the climate changes. Boreal wildfires contribute to global emission of greenhouse gases (GHG-CO2, CH4 and N2O) and indirectly result in the thawing of near-surface permafrost. In this study, we aimed to define the impact of fire on soil microbial communities and metabolic potential for GHG fluxes in samples collected up to 1 m depth from an upland black spruce forest near Nome Creek, Alaska. We measured geochemistry, GHG fluxes, potential soil enzyme activities and microbial community structure via 16SrRNA gene and metagenome sequencing. We found that soil moisture, C content and the potential for respiration were reduced by fire, as were microbial community diversity and metabolic potential. There were shifts in dominance of several microbial community members, including a higher abundance of candidate phylum AD3 after fire. The metagenome data showed that fire had a pervasive impact on genes involved in carbohydrate metabolism, methanogenesis and the nitrogen cycle. Although fire resulted in an immediate release of CO2 from surface soils, our results suggest that the potential for emission of GHG was ultimately reduced at all soil depths over the longer term. Because of the size of the permafrost C reservoir, these results are crucial for understanding whether fire produces a positive or negative feedback loop contributing to the global C cycle.

Published
2014

41. Early spring, severe frost events, and drought induce rapid carbon loss in high elevation meadows.

Author

Arnold, Chelsea, Ghezzehei, Teamrat A, and Berhe, Asmeret Asefaw

Subjects
Carbon Dioxide, Carbon, Altitude, Seasons, California, Droughts, Grassland, General Science & Technology
Abstract

By the end of the 20th century, the onset of spring in the Sierra Nevada mountain range of California has been occurring on average three weeks earlier than historic records. Superimposed on this trend is an increase in the presence of highly anomalous "extreme" years, where spring arrives either significantly late or early. The timing of the onset of continuous snowpack coupled to the date at which the snowmelt season is initiated play an important role in the development and sustainability of mountain ecosystems. In this study, we assess the impact of extreme winter precipitation variation on aboveground net primary productivity and soil respiration over three years (2011 to 2013). We found that the duration of snow cover, particularly the timing of the onset of a continuous snowpack and presence of early spring frost events contributed to a dramatic change in ecosystem processes. We found an average 100% increase in soil respiration in 2012 and 2103, compared to 2011, and an average 39% decline in aboveground net primary productivity observed over the same time period. The overall growing season length increased by 57 days in 2012 and 61 days in 2013. These results demonstrate the dependency of these keystone ecosystems on a stable climate and indicate that even small changes in climate can potentially alter their resiliency.

Published
2014

42. Impacts of organic matter amendments on carbon and nitrogen dynamics in grassland soils

Author

Ryals, Rebecca, Kaiser, Michael, Torn, Margaret S, Berhe, Asmeret Asefaw, and Silver, Whendee L

Subjects
Environmental Sciences, Soil Sciences, Life on Land, Density fractionation, Diffuse Reflectance Infrared Fourier, Transform spectroscopy, Carbon sequestration, Soil amendment, Grassland ecosystems, Biological Sciences, Agricultural and Veterinary Sciences, Agronomy & Agriculture, Soil sciences
Abstract

Organic matter amendments have been proposed as a means to enhance soil carbon (C) stocks on degraded soils. However, only few data exist on rates of soil C sequestration or the fate of added C in grassland soils, which are generally thought to have high C storage potential. We measured changes in the amount of C and nitrogen (N) in soils and in the composition of soil organic matter (SOM) following a single application of composted organic matter in two annual grasslands from different bioclimatic zones (coastal and inland valley). There was a significant increase in bulk soil organic C content at the valley grassland, and a similar but non-significant trend at the coastal grassland. Physical fractionation of soil three years after organic matter amendment revealed increases in C and N in the free- and occluded light fractions in both the valley and coastal grasslands. Amendments resulted in a greater relative increase in the N stored in light soil fractions compared to C, leading to lower C:N ratios. Diffuse Reflectance Infrared Fourier Transform (DRIFT) spectroscopy showed an increase in the ratio of carboxyl and carbonyl functional groups to aliphatic methyl and methylene groups in the free- and occluded light fractions. These data show that the organic matter amendment was incorporated in the free light and occluded light fractions over three years. Our results indicate that a single application of compost to grassland soils can increase soil C and N storage in labile and physically protected pools over relatively short time periods and contribute to climate change mitigation.

Published
2014

50. Plant footprint decreases the functional diversity of molecules in topsoil organic matter after millions of years of ecosystem development.

Author

Sáez‐Sandino, Tadeo, Gallardo, Antonio, Eldridge, David J., Berhe, Asmeret Asefaw, Doetterl, Sebastian, and Delgado‐Baquerizo, Manuel

Subjects
MID-infrared spectroscopy, CONTINENTS, SOIL chronosequences, REFLECTANCE spectroscopy, TOPSOIL, NATURAL history
Abstract

Aim: Theory suggests that the diversity of molecules in soil organic matter (SOM functional diversity) provides key insights on multiple ecosystem services. We aimed to investigate how and why SOM functional diversity and composition change as topsoils develop, and its implications for key soil functions (e.g., from nutrient pool to water regulation). Location: We reported data on 16 soil chronosequences globally distributed in nine countries from six continents. Time Period: 2016–2017. Major Taxa Studied: Soil microbes (bacteria and fungi) and vascular plants. Methods: SOM functional diversity and composition without mineral interference were measured using diffuse reflectance mid‐infrared Fourier transform spectroscopy (DRIFT). We aimed to characterize the main environmental factors related to SOM functional diversity and composition. Also, we calculated the links among SOM functional diversity and key soil functions. Results: We found that SOM functional diversity declines after millions of years of soil formation (pedogenesis). We further showed that increases in plant cover and productivity led to a higher ratio of reduced (e.g., alkanes) over oxidized carbon forms (i.e., C: O‐functional groups ratio), which was positively correlated to SOM functional diversity as soils age. Our findings indicated that the plant footprint (i.e., the accumulation of plant‐derived material promoting the C: O‐functional group ratio) would explain the reduction of SOM functional diversity as ecosystems develop. Moreover, the dissimilarity in SOM composition consistently increased with soil age, with the soil development stage emerging as the main predictor of SOM dissimilarity across contrasting biomes. Main Conclusions: Our global survey contextualized the natural history of SOM functional diversity and composition during long‐term soil development. Together, we showed how plant footprint drives the losses of SOM functional diversity with increasing age, which might provide a novel mechanism to explain typically reported losses in ecosystem functions during ecosystem retrogression. [ABSTRACT FROM AUTHOR]

Published
2024
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