Lo, Yueh-Hsin

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https://academica-e.unavarra.es/handle/2454/49416

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Lo

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Yueh-Hsin

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Ciencias

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IMAB. Research Institute for Multidisciplinary Applied Biology

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0000-0001-6444-0273

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750529

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810917

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2019 - 201912020 - 20211
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Author: González de Andrés, Ester × Subject: Climate change ×

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Now showing 1 - 2 of 2
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    PublicationOpen Access
    CO2 fertilization plays a minor role in long-term carbon accumulation patterns in temperate pine forests in the southwestern Pyrenees
    (Elsevier, 2019) Lo, Yueh-Hsin; Blanco Vaca, Juan Antonio; González de Andrés, Ester; Imbert Rodríguez, Bosco; Castillo Martínez, Federico; Institute for Multidisciplinary Research in Applied Biology - IMAB
    Isolating the long-term fertilization effect of CO 2 from other climate- and site-related effects on tree growth has been proven a challenging task. To isolate long-term effects of [CO2] on water use efficiency at ecosystem level, we used the FORECAST Climate forest model, calibrated for Scots pine (Pinus sylvestris L.) forests in the southwestern Pyrenees, growing at a Mediterranean montane site and at a continental subalpine site. Future climate scenarios (RCP 4.5 and RCP 8.5) were generated using a battery of six climate models to estimate daily values of temperature and precipitation in a 90-year series. A factorial experiment was designed to disentangle the importance on C pools of three growing limiting factors (nitrogen limitation, climate (temperature + precipitation) limitation and atmospheric CO 2 concentration). The relative importance of each factor was quantified by comparing the scenario with the limitation of each individual factor turned on with the non-limitation scenario. Positive CO 2 fertilization due to improvement in water use efficiency was detected by the model, but its quantitative impact improving tree growth was minimum: its average increase in ecosystem C pools ranged from 0.3 to 0.9%. At the site with cooler climate conditions (continental), the main limitation for tree growth was climate. Such limitation will be reduced under climate change and the ecosystem will store more carbon. At the site with milder climate conditions (Mediterranean), N availability was the main limiting factor albeit modulated by water availability. Such limitation could be reduced under climate change as N cycling could accelerate (higher litterfall production and decomposition rates) but also increase if droughts become more frequent and severe. In addition, the magnitude of the uncertainty related to climate model selection was much more important than CO 2 fertilization, indicating that atmospheric processes are more important than tree physiological processes when defining how much carbon could be gained (or lost) in forests under climate change. In conclusion, due to the small changes in forest C pools caused by variation of atmospheric CO 2 concentrations compared to changes caused by other growth limiting factors (nutrients, climate), reducing uncertainty related to climate projections seems a more efficient way to reduce uncertainty in tree growth projections than increasing forest model complexity.
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    PublicationOpen Access
    Synergies between climate change, biodiversity, ecosystem function and services, indirect drivers of change and human well-being in forests
    (Springer, 2021) Imbert Rodríguez, Bosco; Blanco Vaca, Juan Antonio; Candel Pérez, David; Lo, Yueh-Hsin; González de Andrés, Ester; Yeste Yeste, Antonio; Herrera Álvarez, Ximena; Rivadeneira Barba, Gabriela; Liu, Yang; Chang, Shih-Chieh; Ciencias; Zientziak
    Climate change is having impacts on the biodiversity and structure of many ecosystems. In this chapter, we focus on its impacts on forests. We will focus on how the potential climate change impacts on forest biodiversity and structure will have a reflection on the ecosystem services provided by forests, and therefore on the capacity of these ecosystems to support the Sustainable Development Goals set by the United Nations. The chapter will be organized in three sections, considering boreal, temperate, and tropical forests along each section. The first section will deal with the synergies or interactions between climate change, biodiversity, and ecosystem function with emphasis not only on plants but also on fungi, animals, and prokaryotes. Synergies between climate change and ecosystem services will be described and analyzed in the second section. To better link the first two sections, we will explore the relationships between ecosystem function, species traits, and ecosystem services. Finally, case studies for boreal, Mediterranean, and tropical forests will be presented, emphasizing the synergies between the above factors, the indirect drivers of change (demographic, economic, sociopolitical, science and technology, culture and religion), and human well-being (basic materials for a good life, health, good social relations, freedom of choice and actions) in forests.