Your search keyword '"Bach, Lennart Thomas"' showing total 4 results

1. Drivers of particle sinking velocities in the Peruvian upwelling system.

Author

Baumann, Moritz, Paul, Allanah Joy, Taucher, Jan, Bach, Lennart Thomas, Goldenberg, Silvan, Stange, Paul, Minutolo, Fabrizio, and Riebesell, Ulf

Subjects

CARBON sequestration, VELOCITY, TERRITORIAL waters, PARTICLE analysis, MOTOR vehicle driving, MARINE ecology

Abstract

As one of Earth's most productive marine ecosystems, the Peruvian upwelling system transports large amounts of biogenic matter from the surface to the deep ocean. Whilst particle sinking velocity is a key factor controlling the biological pump, thereby affecting carbon sequestration and O 2 -depletion, it has not yet been measured in this system. During a 50 d mesocosm experiment in the surface waters off the coast of Peru, we assessed particle sinking velocities and their biogeochemical and physical drivers. We further characterized the general properties of exported particles under different phytoplankton communities and nutritional states. Average sinking velocities varied between size classes and ranged from 12.8 ± 0.7 m d -1 (particles 40–100 µ m) to 19.4 ± 0.7 m d -1 (particles 100–250 µ m) and 34.2 ± 1.5 m d -1 (particles 250–1000 µ m) (± 95 % CI). Despite a distinct plankton succession from diatoms to dinoflagellates with concomitant 5-fold drop in opal ballasting, substantial changes in sinking velocity were not observed. This illustrates the complexity of counteracting factors driving the settling behaviour of marine particles. In contrast, we found higher sinking velocities with increasing particle size and roundness and decreasing porosity. Size had by far the strongest influence among these physical particle properties, despite a high amount of unexplained variability. Our study provides a detailed analysis of the drivers of particle sinking velocity in the Peruvian upwelling system, which allows modellers to optimize local particle flux parameterization. This will help to better project oxygen concentrations and carbon sequestration in a region that is subject to substantial climate-driven changes. [ABSTRACT FROM AUTHOR]

Published

2023

2. Drivers of Particle Sinking Velocities in the Peruvian Upwelling System.

Author

Baumann, Moritz, Paul, Allanah Joy, Taucher, Jan, Bach, Lennart Thomas, Goldenberg, Silvan, Stange, Paul, Minutolo, Fabrizio, and Riebesell, Ulf

Subjects

CARBON sequestration, VELOCITY, TERRITORIAL waters, PARTICLE analysis, MARINE ecology

Abstract

As one of Earth's most productive marine ecosystems, the Peruvian Upwelling System transports large amounts of biogenic matter from the surface to the deep ocean. Whilst particle sinking velocity is a key factor controlling the biological pump, thereby affecting carbon sequestration and O2-depletion, it has not yet been measured in this system. During a 50-day mesocosm experiment in the surface waters off the coast of Peru, we measured particle sinking velocities and their biogeochemical and physical drivers. We further characterized the general properties of exported particles under different phytoplankton communities and nutritional states. Average sinking velocities varied between size classes and ranged from 12.8 ± 0.7 m d-1 (particles 40-100 µm), to 19.4 ± 0.7 m d-1 (particles 100-250 µm), and 34.2 ± 1.5 m d-1 (particles 250-1000 µm) (± 95% CI). Surprisingly, no relationship between opal ballast and sinking velocity could be identified, despite the presence of diatoms, questioning the importance of opal ballast in freshly produced material sinking from the surface. In contrast, we found higher sinking velocities with increasing particle size, compactness and roundness. Size had by far the strongest influence among these physical particle properties. Our study provides a detailed analysis of the drivers of particle sinking velocity in the Peruvian Upwelling System, which allows modelers to optimize local particle flux parameterization. This will help to better project oxygen concentrations and carbon sequestration in a region that is subject to substantial climate-driven changes. [ABSTRACT FROM AUTHOR]

Published

2022

3. Factors controlling plankton community production, export flux, and particulate matter stoichiometry in the coastal upwelling system off Peru.

Author

Bach, Lennart Thomas, Paul, Allanah Joy, Boxhammer, Tim, von der Esch, Elisabeth, Graco, Michelle, Schulz, Kai Georg, Achterberg, Eric, Aguayo, Paulina, Arístegui, Javier, Ayón, Patrizia, Baños, Isabel, Bernales, Avy, Boegeholz, Anne Sophie, Chavez, Francisco, Chavez, Gabriela, Chen, Shao-Min, Doering, Kristin, Filella, Alba, Fischer, Martin, and Grasse, Patricia

Subjects

PARTICULATE matter, STOICHIOMETRY, FLUX (Energy), PLANKTON, EXPORTS, BIOGEOCHEMICAL cycles, OCEAN mining, NUTRIENT cycles

Abstract

Eastern boundary upwelling systems (EBUS) are among the most productive marine ecosystems on Earth. The production of organic material is fueled by upwelling of nutrient-rich deep waters and high incident light at the sea surface. However, biotic and abiotic factors can modify surface production and related biogeochemical processes. Determining these factors is important because EBUS are considered hotspots of climate change, and reliable predictions of their future functioning requires understanding of the mechanisms driving the biogeochemical cycles therein. In this field experiment, we used in situ mesocosms as tools to improve our mechanistic understanding of processes controlling organic matter cycling in the coastal Peruvian upwelling system. Eight mesocosms, each with a volume of ∼55 m 3 , were deployed for 50 d ∼6 km off Callao (12 ∘ S) during austral summer 2017, coinciding with a coastal El Niño phase. After mesocosm deployment, we collected subsurface waters at two different locations in the regional oxygen minimum zone (OMZ) and injected these into four mesocosms (mixing ratio ≈1.5 : 1 mesocosm: OMZ water). The focus of this paper is on temporal developments of organic matter production, export, and stoichiometry in the individual mesocosms. The mesocosm phytoplankton communities were initially dominated by diatoms but shifted towards a pronounced dominance of the mixotrophic dinoflagellate (Akashiwo sanguinea) when inorganic nitrogen was exhausted in surface layers. The community shift coincided with a short-term increase in production during the A. sanguinea bloom, which left a pronounced imprint on organic matter C : N : P stoichiometry. However, C, N, and P export fluxes did not increase because A. sanguinea persisted in the water column and did not sink out during the experiment. Accordingly, export fluxes during the study were decoupled from surface production and sustained by the remaining plankton community. Overall, biogeochemical pools and fluxes were surprisingly constant for most of the experiment. We explain this constancy by light limitation through self-shading by phytoplankton and by inorganic nitrogen limitation which constrained phytoplankton growth. Thus, gain and loss processes remained balanced and there were few opportunities for blooms, which represents an event where the system becomes unbalanced. Overall, our mesocosm study revealed some key links between ecological and biogeochemical processes for one of the most economically important regions in the oceans. [ABSTRACT FROM AUTHOR]

Published

2020

4. Factors controlling plankton productivity, particulate matter stoichiometry, and export fluxin the coastal upwelling system off Peru.

Author

Bach, Lennart Thomas, Paul, Allanah Joy, Boxhammer, Tim, von der Esch, Elisabeth, Graco, Michelle, Schulz, Kai Georg, Achterberg, Eric, Aguayo, Paulina, Aristegui, Javier, Ayon, Patrizia, Banos, Isabel, Bernales, Avy, Boegeholz, Anne Sophie, Chavez, Francisco, Shao-Min Chen, Doering, Kristin, Filella, Alba, Fischer, Martin, Grasse, Patricia, and Haunost, Mathias

Subjects

ECOLOGICAL regime shifts, PARTICULATE matter, STOICHIOMETRY, PLANKTON, WATER, BODIES of water, NITROGEN in water

Abstract

Eastern boundary upwelling systems (EBUS) are among the most productive marine ecosystems on Earth. The high productivity in surface waters is facilitated by upwelling of nutrient-rich deep waters, with high light availability enabling fast phytoplankton growth and nutrient utilization. However, there are numerous biotic and abiotic factors modifying productivity and biogeochemical processes. Determining these factors is important because EBUS are considered hotspots of climate change, and reliable predictions on their future functioning requires understanding of the mechanisms driving biogeochemical cycles therein. In this study, we used in situ mesocosms to obtain mechanistic understanding of processes controlling productivity, organic matter export, and particulate matter stoichiometry in the coastal Peruvian upwelling system. Therefore, eight mesocosm units with a volume of ~50m³ were deployed for 50 days ~6km off Callao during austral summer 2017, coinciding with a coastal El Niño event. To compare how upwelling of different water bodies influences plankton succession patterns, we collected two subsurface waters at different locations in the regional oxygen minimum zone (OMZ) and injected these into four replicate mesocosms, respectively (mixing ratio ≈ 1.5:1 mesocosm: OMZ water). The differences in nutrient concentrations between the collected water bodies were relatively small, and therefore we do not consider treatment differences in the present paper. The phytoplankton communities were initially dominated by diatoms but shifted towards a pronounced dominance of the mixotrophic harmful dinoflagellate (Akashiwo sanguinea) when inorganic nitrogen was exhausted in surface layers. The community shift resulted in a major short-term increase in productivity during A. sanguinea growth which left a pronounced imprint on organic matter C:N:P stoichiometry. However, C, N, and P export fluxes were not affected by this ecological regime shift because A. sanguinea persisted in the water column and did not sink out during the experiment. Accordingly, ongoing export fluxes during the study were maintained mainly by a remaining "background" plankton community. Overall, biogeochemical pools and fluxes were surprisingly constant in between the ecological regime shifts. We explain this constancy by light limitation through self-shading by phytoplankton and inorganic nitrogen limitation which constrained phytoplankton growth. Thus, gain and loss processes seemed to be relatively well balanced and there was little opportunity for blooms, which represents an event where the system becomes unbalanced. The mesocosm study revealed key links between ecological and biogeochemical processes for one of the economically most important regions in the oceans. [ABSTRACT FROM AUTHOR]

Published

2020