(A) Project Goal
- [ POBE-Project-Summary.pdf ]
Using US and international observational datasets combined with physical and biological
models, this project investigates the mechanisms of climate-related
variability in three Pacific boundary ecosystems: Gulf of Alaska
(GOA) and California Current System (CCS) referred to as the Northeast
Pacific (NEP), the Humboldt or Peru-Chile
Current System (PCCS), and the Kuroshio-Oyashio Extension (KOE) region.
(The figure below shows the regional domains)
(B) Research Activities -
(1) Assess to what extent, and by what mechanisms, large-scale climate
modes (e.g. PDO, NPGO, ENSO, and potentially others) drove coherent
changes across Pacific boundary ecosystems over the period 1960-2007.
(2) Quantify and explain how changes in regional ocean processes (e.g.
upwelling, transport dynamics, mixing and mesoscale structure) at each
boundary control phytoplankton and zooplankton dynamics. Then, use those
results to test the degree to which changes in each study region reflect
bottom-up control of their respective ecosystems.
(3) Quantify the extent to which changes in the statistics of
shorter-period events (e.g. intraseasonal oscillation, timing of spring
transitions) during different phases of the longer-period climate modes
(e.g. PDO, NPGO and others) determine the climate state of
boundary-current ecosystems.
(4)
Explore the range of uncertainties in the response of regional ocean
dynamics and their ecosystems to climate change using forcing scenarios
from selected climate model integrations that are part of the IPCC 2007
report. This last objective begins an assessment of the potential
impacts of climate change on regional ocean ecosystems, a topic poorly
addressed in the latest IPCC report, but the chief instrument for most
fisheries and coastal management.
(C) Main Hypothesis -
This diagram below shows the main path of the hypothesis of the proposal. The
hypothesis can be grouped in three principal sets. (H1)
Linking large-scale physical variability to regional scales through
comparison with available observations of the physical state of the
regional oceans along the Pacific Boundaries. (H2)
Understand the relative importance of regionally dependent forcing vs.
large-scale. How much of the variability along the boundary is coherent
and linked to modes of climate variability of the Pacific Ocean. (H3)
Link changes in the physical state at the regional scale with changes in
transport dynamics and nutrient flux. Our main hypotheses is that
ecosystem variability in the Pacific boundaries is driven by changes in
nutrient flux. Hence we seek for direct links between changes in
horizontal and vertical transport to observed measures of ecosystem
state.
(D) Research Tasks organization -
The research tasks are grouped in 5 topic areas that cover the following
geographical locations (color coded):
Pacific Basin,
Northeast Pacific (NEP),
Peru-Chile Current System (PCCS),
the Kuroshio Region (KOE)
and Cross-Bundary Synthesis
Activities.
Below are a set of diagrams -- one for each group -- showing the type of ongoing research activities. A detailed description of these research activities for each group is available on the [ Research Activities ] page.
Pacific Basin Analysis
North Pacific Eastern Boundary Analysis
South Pacific Eastern Boundary Analysis
North Pacific Western Boundary Analysis
Cross Boundary Synthesis
A detailed description of these research activities for each group is available on the [ Research Activities ] page.