TY - JOUR
T1 - Coupled surface to deep Earth processes
T2 - Perspectives from TOPO-EUROPE with an emphasis on climate- and energy-related societal challenges
AU - Cloetingh, Sierd
AU - Sternai, Pietro
AU - Koptev, Alexander
AU - Ehlers, Todd A.
AU - Gerya, Taras
AU - Kovács, István
AU - Oerlemans, Johannes
AU - Beekman, Fred
AU - Lavallée, Yan
AU - Dingwell, Donald
AU - Békési, Eszter
AU - Porkolàb, Kristóf
AU - Tesauro, Magdala
AU - Lavecchia, Alessio
AU - Botsyun, Svetlana
AU - Muller, Veleda
AU - Roure, François
AU - Serpelloni, Enrico
AU - Matenco, Liviu
AU - Castelltort, Sébastien
AU - Giovannelli, Donato
AU - Brovarone, Alberto Vitale
AU - Malaspina, Nadia
AU - Coletti, Giovanni
AU - Valla, Pierre
AU - Limberger, Jon
N1 - Funding Information:
The ILP, Academia Europaea, Young Academy of Europe, European Science Foundation, Horizon Europe, the Balzan Foundation, the Alexander von Humboldt Foundation, and numerous national research councils are thanked for continuous support and major grants. Magdala Tesauro, Alexander Koptev, and Pietro Sternai thank the ILP for bestowing them with the Flinn-Hart award to young scientists. This work is part of a project that received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation program (Grant agreement No. 864045 ). This work has also been supported by Fondazione Cariplo and Fondazione CDP (Grant n° 2022- 1546_001 ) and by the Italian Ministry of Education, MUR (Project Dipartimenti di Eccellenza, TECLA, Department of Earth and Environmental Sciences, University of Milano-Bicocca ). We thank Nevena Andrić-Tomašević, an anonymous reviewer and the editor Howard Falcon-Lang for their thoughtful and constructive reviews.
Funding Information:
The International Lithosphere Program (ILP) launched a European multidisciplinary program in Europe under the umbrella name of TOPO-EUROPE with a workshop in 2005 and a white paper ( Cloetingh et al., 2007 ) describing its scientific scope. The program represents a bottom-up, community effort to self-organize and cross-fertilize the disparate fields within the geological and geophysical communities. Throughout the last fifteen years the program has continued to grow. The core of the TOPO-EUROPE research activities was supported through funding of a European Collaborative Research (EUROCORES) program administered by the European Science Foundation (ESF), with 14.5 M€ allocated by 23 different member states to better understand and quantify the evolution of topography in Europe, the accompanying changes in sea level and their surface and deep Earth driving mechanisms. The ESF EUROCORES provided funding for the training of more than 60 European young researchers with widespread results published in several special volumes and papers of high-impact international journals and papers. Since the establishment and start of the TOPO-EUROPE programme in 2006, a significant number of scientific results from collaborative research projects have been published in several special volumes ( Cloetingh et al., 2007, 2009, 2011, 2013, 2018 ; Cloetingh and Tibaldi, 2012 ; Matenco and Andriessen, 2013 ). Highlights include amongst others:
Funding Information:
TOPO-EUROPE has been extraordinarily successful in capacity building on a pan-European scale and inspiring large scale collaborative research in Europe. Several International Training Networks (ITN) funded by the European Commission for training and networking young researchers followed. The ITNs SUBITOP and TOPOMOD, for instance, have funded more than 20 young researchers together. On a national level, programs such as the TOPO-IBERIA ( Gallart et al., 2015 ; Garate et al., 2015 ; Cloetingh et al., 2011 ) program funded by the national research council of Spain (CSIC) with an amount of 8 M€ to unravel the structure and evolution of the Iberian topography, with an average elevation higher than that of Switzerland. TOPO-EUROPE also demonstrated the need for integrated European Solid Earth Scientific infrastructures and accomplished the realization of the European Plate Observing System (EPOS, https://www.epos-eu.org/ ) coordinated by the Italian National Institute of Geophysics and Volcanology (INGV) as part of the European Scientific Research Infrastructure (ESFRI) program. Other examples of community building in the Solid Earth science inspired by TOPO-EUROPE are the AlpArray, AdriaArray and Topo-Iberia programs for deployment of dense networks of seismic stations to address first order questions about intra-crustal heterogeneities and coeval regional seismicity, orogenies and lithosphere dynamics. Overall, TOPO-EUROPE served as a trigger to bring integrative Earth Science to a position where it could more easily branch out to synergies with other disciplines such as Environmental and Climate science.
Publisher Copyright:
© 2023
PY - 2023/7
Y1 - 2023/7
N2 - Understanding the interactions between surface and deep Earth processes is important for research in many diverse scientific areas including climate, environment, energy, georesources and biosphere. The TOPO-EUROPE initiative of the International Lithosphere Program serves as a pan-European platform for integrated surface and deep Earth sciences, synergizing observational studies of the Earth structure and fluxes on all spatial and temporal scales with modelling of Earth processes. This review provides a survey of scientific developments in our quantitative understanding of coupled surface-deep Earth processes achieved through TOPO-EUROPE. The most notable innovations include (1) a process-based understanding of the connection of upper mantle dynamics and absolute plate motion frames; (2) integrated models for sediment source-to-sink dynamics, demonstrating the importance of mass transfer from mountains to basins and from basin to basin; (3) demonstration of the key role of polyphase evolution of sedimentary basins, the impact of pre-rift and pre-orogenic structures, and the evolution of subsequent lithosphere and landscape dynamics; (4) improved conceptual understanding of the temporal evolution from back-arc extension to tectonic inversion and onset of subduction; (5) models to explain the integrated strength of Europe's lithosphere; (6) concepts governing the interplay between thermal upper mantle processes and stress-induced intraplate deformation; (7) constraints on the record of vertical motions from high-resolution data sets obtained from geo-thermochronology for Europe's topographic evolution; (8) recognition and quantifications of the forcing by erosional and/or glacial-interglacial surface mass transfer on the regional magmatism, with major implications for our understanding of the carbon cycle on geological timescales and the emerging field of biogeodynamics; and (9) the transfer of insights obtained on the coupling of deep Earth and surface processes to the domain of geothermal energy exploration. Concerning the future research agenda of TOPO-EUROPE, we also discuss the rich potential for further advances, multidisciplinary research and community building across many scientific frontiers, including research on the biosphere, climate and energy. These will focus on obtaining a better insight into the initiation and evolution of subduction systems, the role of mantle plumes in continental rifting and (super)continent break-up, and the deformation and tectonic reactivation of cratons; the interaction between geodynamic, surface and climate processes, such as interactions between glaciation, sea level change and deep Earth processes; the sensitivity, tipping points, and spatio-temporal evolution of the interactions between climate and tectonics as well as the role of rock melting and outgassing in affecting such interactions; the emerging field of biogeodynamics, that is the impact of coupled deep Earth – surface processes on the evolution of life on Earth; and tightening the connection between societal challenges regarding renewable georesources, climate change, natural geohazards, and novel process-understanding of the Earth system.
AB - Understanding the interactions between surface and deep Earth processes is important for research in many diverse scientific areas including climate, environment, energy, georesources and biosphere. The TOPO-EUROPE initiative of the International Lithosphere Program serves as a pan-European platform for integrated surface and deep Earth sciences, synergizing observational studies of the Earth structure and fluxes on all spatial and temporal scales with modelling of Earth processes. This review provides a survey of scientific developments in our quantitative understanding of coupled surface-deep Earth processes achieved through TOPO-EUROPE. The most notable innovations include (1) a process-based understanding of the connection of upper mantle dynamics and absolute plate motion frames; (2) integrated models for sediment source-to-sink dynamics, demonstrating the importance of mass transfer from mountains to basins and from basin to basin; (3) demonstration of the key role of polyphase evolution of sedimentary basins, the impact of pre-rift and pre-orogenic structures, and the evolution of subsequent lithosphere and landscape dynamics; (4) improved conceptual understanding of the temporal evolution from back-arc extension to tectonic inversion and onset of subduction; (5) models to explain the integrated strength of Europe's lithosphere; (6) concepts governing the interplay between thermal upper mantle processes and stress-induced intraplate deformation; (7) constraints on the record of vertical motions from high-resolution data sets obtained from geo-thermochronology for Europe's topographic evolution; (8) recognition and quantifications of the forcing by erosional and/or glacial-interglacial surface mass transfer on the regional magmatism, with major implications for our understanding of the carbon cycle on geological timescales and the emerging field of biogeodynamics; and (9) the transfer of insights obtained on the coupling of deep Earth and surface processes to the domain of geothermal energy exploration. Concerning the future research agenda of TOPO-EUROPE, we also discuss the rich potential for further advances, multidisciplinary research and community building across many scientific frontiers, including research on the biosphere, climate and energy. These will focus on obtaining a better insight into the initiation and evolution of subduction systems, the role of mantle plumes in continental rifting and (super)continent break-up, and the deformation and tectonic reactivation of cratons; the interaction between geodynamic, surface and climate processes, such as interactions between glaciation, sea level change and deep Earth processes; the sensitivity, tipping points, and spatio-temporal evolution of the interactions between climate and tectonics as well as the role of rock melting and outgassing in affecting such interactions; the emerging field of biogeodynamics, that is the impact of coupled deep Earth – surface processes on the evolution of life on Earth; and tightening the connection between societal challenges regarding renewable georesources, climate change, natural geohazards, and novel process-understanding of the Earth system.
KW - Climate changes across timescales
KW - Coupled surface-deep Earth interactions
KW - Earth environment
KW - Earth system science
KW - Geo-biosphere
KW - Geo-energy
UR - http://www.scopus.com/inward/record.url?scp=85159572445&partnerID=8YFLogxK
U2 - 10.1016/j.gloplacha.2023.104140
DO - 10.1016/j.gloplacha.2023.104140
M3 - Review article
AN - SCOPUS:85159572445
SN - 0921-8181
VL - 226
JO - Global and Planetary Change
JF - Global and Planetary Change
M1 - 104140
ER -