Sub-continental-scale Carbon Stocks of Individual Trees in African Drylands

Overview

Journal Nature

Specialty Science

Date 2023 Mar 1

PMID 36859581

Authors

Compton Tucker

Martin Brandt

Pierre Hiernaux

Ankit Kariryaa

Kjeld Rasmussen

Jennifer Small

Christian Igel

Florian Reiner

Katherine Melocik

Jesse Meyer

Scott Sinno

Eric Romero

Erin Glennie

Yasmin Fitts

August Morin

Jorge Pinzon

Devin McClain

Paul Morin

Claire Porter

Shane Loeffler

Laurent Kergoat

Bil-Assanou Issoufou

Patrice Savadogo

Jean-Pierre Wigneron

Benjamin Poulter

Philippe Ciais

Robert Kaufmann

Ranga Myneni

Sassan Saatchi

Rasmus Fensholt

Affiliations

Soon will be listed here.

Abstract

The distribution of dryland trees and their density, cover, size, mass and carbon content are not well known at sub-continental to continental scales. This information is important for ecological protection, carbon accounting, climate mitigation and restoration efforts of dryland ecosystems. We assessed more than 9.9 billion trees derived from more than 300,000 satellite images, covering semi-arid sub-Saharan Africa north of the Equator. We attributed wood, foliage and root carbon to every tree in the 0-1,000 mm year rainfall zone by coupling field data, machine learning, satellite data and high-performance computing. Average carbon stocks of individual trees ranged from 0.54 Mg C ha and 63 kg C tree in the arid zone to 3.7 Mg C ha and 98 kg tree in the sub-humid zone. Overall, we estimated the total carbon for our study area to be 0.84 (±19.8%) Pg C. Comparisons with 14 previous TRENDY numerical simulation studies for our area found that the density and carbon stocks of scattered trees have been underestimated by three models and overestimated by 11 models, respectively. This benchmarking can help understand the carbon cycle and address concerns about land degradation. We make available a linked database of wood mass, foliage mass, root mass and carbon stock of each tree for scientists, policymakers, dryland-restoration practitioners and farmers, who can use it to estimate farmland tree carbon stocks from tablets or laptops.

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