Lagged effects regulate the inter-annual variability of the tropical carbon balance

A Anthony Bloom,T Luke Smallman,David S Schimel,Sassan S Saatchi,Jean-François Exbrayat,Nicholas C Parazoo,Gregory R Quetin,Alexandra G Konings,John T Reager,Helen M Worden,Victoria Meyer,Kevin W Bowman,Mathew Williams,John R Worden,Yi Yin,Junjie Liu,Zhe Jiang

doi:10.5194/bg-17-6393-2020

Abstract

Abstract. Inter-annual variations in the tropical land carbon (C) balance are a dominant component of the global atmospheric CO2 growth rate. Currently, the lack of quantitative knowledge on processes controlling net tropical ecosystem C balance on inter-annual timescales inhibits accurate understanding and projections of land–atmosphere C exchanges. In particular, uncertainty on the relative contribution of ecosystem C fluxes attributable to concurrent forcing anomalies (concurrent effects) and those attributable to the continuing influence of past phenomena (lagged effects) stifles efforts to explicitly understand the integrated sensitivity of a tropical ecosystem to climatic variability. Here we present a conceptual framework – applicable in principle to any land biosphere model – to explicitly quantify net biospheric exchange (NBE) as the sum of anomaly-induced concurrent changes and climatology-induced lagged changes to terrestrial ecosystem C states (NBE = NBECON+NBELAG). We apply this framework to an observation-constrained analysis of the 2001–2015 tropical C balance: we use a data–model integration approach (CARbon DAta-MOdel fraMework – CARDAMOM) to merge satellite-retrieved land-surface C observations (leaf area, biomass, solar-induced fluorescence), soil C inventory data and satellite-based atmospheric inversion estimates of CO2 and CO fluxes to produce a data-constrained analysis of the 2001–2015 tropical C cycle. We find that the inter-annual variability of both concurrent and lagged effects substantially contributes to the 2001–2015 NBE inter-annual variability throughout 2001–2015 across the tropics (NBECON IAV = 80 % of total NBE IAV, r = 0.76; NBELAG IAV = 64 % of NBE IAV, r = 0.61), and the prominence of NBELAG IAV persists across both wet and dry tropical ecosystems. The magnitude of lagged effect variations on NBE across the tropics is largely attributable to lagged effects on net primary productivity (NPP; NPPLAG IAV 113 % of NBELAG IAV, r = −0.93, p value < 0.05), which emerge due to the dependence of NPP on inter-annual variations in foliar C and plant-available H2O states. We conclude that concurrent and lagged effects need to be explicitly and jointly resolved to retrieve an accurate understanding of the processes regulating the present-day and future trajectory of the terrestrial land C sink.

Highlights

Immediate ecosystem responses to external forcings are invariably followed by time-lagged ecosystem responses, attributable to a continuum of lagged biotic and physical processes
To assess the CARDAMOM 2001–2015 reanalysis, here we present an evaluation of CARDAMOM against (a) the assimilated 2010–2013 Gases Observing Satellite (GOSAT)-derived net biospheric exchange (NBE) dataset, (b) the withheld OCO-2-derived 2015 NBE dataset, and (c) assimilated and independent datasets of tropical terrestrial ecosystem states and fluxes
We find that the sum of regional foliar C and plant-available H2O impacts on NBECON) and lagged effects ( (NBELAG) (Fig. 8) are approximately equivalent to NPPLAG (Fig. 7); in turn, the considerable contributions of both NPPLAG and NPPCON across tropical ecosystems indicate that both climatic variability and initial ecosystem states are substantial contributors to tropical net primary productivity (NPP) inter-annual variability (IAV)

Summary

Introduction

Immediate ecosystem responses to external forcings are invariably followed by time-lagged ecosystem responses, attributable to a continuum of lagged biotic and physical processes. Contemporaneous ecosystem state changes attributable to disturbances, climatic variability and increasing atmospheric CO2 levels all induce a temporal spectrum of lagged processes, such as diurnal to seasonal dy-. For a given time span, the sum of these “lagged effects” on ecosystem states represents the ecosystem dynamics attributable to a unique integrated legacy of past phenomena, spanning from diurnal to geologic timescales, making lagged effects a ubiquitous dynamical property of any terrestrial ecosystem. Ecosystem function at any given time (such as photosynthetic uptake, respiration and evapotranspiration rates) is an emergent consequence of an ecosystem’s initial physical and biotic states and the contemporaneous impact of meteorological and disturbance forcings on these states

Methods

Results

Conclusion