[et_pb_section fb_built=”1″ _builder_version=”4.27.3″ _module_preset=”default” background_image=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2025\/01\/publications-2.webp” custom_padding=”85px||85px||true|false” background_last_edited=”on|phone” background_image_phone=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2025\/01\/publications-3.webp” background_enable_image_phone=”on” locked=”off” global_colors_info=”{}”][et_pb_row _builder_version=”4.27.3″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.27.3″ _module_preset=”default” global_colors_info=”{}”][et_pb_text content_tablet=”<\/p>\n
” content_phone=”<\/p>\n
” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|700|||||||” text_text_color=”#00284B” text_font_size=”48px” text_line_height=”1.2em” header_text_color=”#00284B” header_line_height=”1em” max_width_tablet=”300px” max_width_phone=”300px” max_width_last_edited=”on|tablet” module_alignment=”left” custom_margin=”||10px||false|false” custom_margin_tablet=”||10px||false|false” custom_margin_phone=”||10px||false|false” custom_margin_last_edited=”on|tablet” animation_style=”fade” animation_delay=”300ms” text_font_size_tablet=”32px” text_font_size_phone=”32px” text_font_size_last_edited=”on|phone” module_alignment_tablet=”left” module_alignment_phone=”center” module_alignment_last_edited=”on|desktop” global_colors_info=”{}”]<\/p>\n
[\/et_pb_text][et_pb_text content_tablet=”<\/p>\n
PUBLICATIONS<\/p>\n
” content_phone=”<\/p>\n
PUBLICATIONS<\/p>\n
” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”satoshi complete||||||||” text_text_color=”#6941EB” text_font_size=”22px” text_line_height=”0.2em” custom_margin=”19px|||||” custom_margin_tablet=”||20px||false|false” custom_margin_phone=”||||false|false” custom_margin_last_edited=”on|phone” custom_padding=”6px||||false|false” animation_style=”fade” animation_delay=”300ms” text_font_size_tablet=”20px” text_font_size_phone=”18px” text_font_size_last_edited=”on|phone” text_line_height_tablet=”0.2em” text_line_height_phone=”0.2em” text_line_height_last_edited=”on|tablet” global_colors_info=”{}”]<\/p>\n
PUBLICATIONS<\/p>\n
[\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_row column_structure=”1_6,1_6,1_6,1_6,1_6,1_6″ use_custom_gutter=”on” gutter_width=”2″ _builder_version=”4.26.0″ _module_preset=”default” width=”60%” custom_margin=”||||true|true” custom_padding=”|0px||0px|true|true” custom_css_main_element=”display:flex;||align-items: center;||” global_colors_info=”{}”][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-global-change-biology-400×400-1.jpg” title_text=”cnrs-ecotron-publications-logo-global-change-biology-400×400″ _builder_version=”4.26.0″ _module_preset=”default” width=”100%” max_width=”100%” custom_margin=”0px|0px|0px|0px|true|false” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-ecology-letters.jpeg” title_text=”cnrs-ecotron-publications-logo-ecology-letters” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-nature-ecology-and-evolution.jpg” title_text=”cnrs-ecotron-publications-logo-nature-ecology-and-evolution” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/applied-geochemistry@4x.png” title_text=”applied-geochemistry@4x” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-ecological-society-of-america.jpg” title_text=”cnrs-ecotron-publications-logo-ecological-society-of-america” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-giga-n-science.png” title_text=”cnrs-ecotron-publications-logo-giga-n-science” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_6,1_6,1_6,1_6,1_6,1_6″ use_custom_gutter=”on” gutter_width=”2″ _builder_version=”4.26.0″ _module_preset=”default” width=”60%” custom_padding=”||||false|true” custom_css_main_element=”display:flex;||align-items: center;||” global_colors_info=”{}”][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-egu-bg.png” title_text=”cnrs-ecotron-publications-logo-egu-bg” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/soil-chemistry@4x.png” title_text=”soil-chemistry@4x” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-plant-cell-environment.jpg” title_text=”cnrs-ecotron-publications-logo-plant-cell-environment” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”0px|0px|0px|0px|true|true” custom_padding=”0px|0px|0px|0px|true|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-oikos-copie.webp” title_text=”cnrs-ecotron-publications-logo-oikos copie” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/Fichier-1@4x.png” title_text=”Fichier 1@4x” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-plos.png” title_text=”cnrs-ecotron-publications-logo-plos” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_6,1_6,1_6,1_6,1_6,1_6″ use_custom_gutter=”on” gutter_width=”2″ _builder_version=”4.26.0″ _module_preset=”default” width=”60%” custom_padding=”|0px||0px|false|true” custom_css_main_element=”display:flex;||align-items: center;||” global_colors_info=”{}”][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-nature-plant.jpg” title_text=”cnrs-ecotron-publications-logo-nature-plant” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-scientific-reports.png” title_text=”cnrs-ecotron-publications-logo-scientific-reports” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-elife.png” title_text=”cnrs-ecotron-publications-logo-elife” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-nature-genzet.jpg” title_text=”cnrs-ecotron-publications-logo-nature-genzet” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/cnrs-ecotron-publications-logo-pnas-scaled.jpg” title_text=”PNAS Logo” _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][et_pb_column type=”1_6″ _builder_version=”4.26.0″ _module_preset=”default” global_colors_info=”{}”][et_pb_image src=”https:\/\/ecotron.cnrs.dev-djaka.fr\/wp-content\/uploads\/2024\/07\/Nature_Communications_Logo-1200×250-1.png” title_text=”Nature_Communications_Logo-1200×250″ _builder_version=”4.26.0″ _module_preset=”default” width=”100%” custom_margin=”|0px||0px|false|true” custom_padding=”|0px||0px|false|true” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ disabled_on=”on|on|on” _builder_version=”4.27.4″ _module_preset=”default” custom_padding=”||||false|false” disabled=”on” global_colors_info=”{}”][et_pb_row _builder_version=”4.25.1″ _module_preset=”default” width=”40%” module_alignment=”center” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.25.1″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n
* <\/span>Articles presenting the Ecotron experimental platforms in an international context<\/p>\n ** <\/span>Data paper<\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_4,1_4,1_4,1_4″ make_equal=”on” _builder_version=”4.26.0″ _module_preset=”default” custom_padding=”||5px|||” global_colors_info=”{}”][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 45<\/span> Honvault, N., Tiouchichine, M.L., \u2026 Milcu, A. (2024)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n Additive effects of basalt enhanced weathering and biochar co-application on carbon sequestration, soil nutrient status and plant performance in a mesocosm experiment. <\/span>Applied Geochemistry<\/em><\/span>, 169. https:\/\/doi.org\/10.1016\/j.apgeochem.2024.106054<\/a><\/p>\n ” content_phone=”<\/p>\n Additive effects of basalt enhanced weathering and biochar co-application on carbon sequestration, soil nutrient status and plant performance in a mesocosm experiment. <\/span>Applied Geochemistry<\/em><\/span>, 169. https:\/\/doi.org\/10.1016\/j.apgeochem.2024.106054<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n Additive effects of basalt enhanced weathering and biochar co-application on carbon sequestration, soil nutrient status and plant performance in a mesocosm experiment. <\/span>Applied Geochemistry<\/em><\/span>, 169. https:\/\/doi.org\/10.1016\/j.apgeochem.2024.106054<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 44<\/span> Cassan, O., Pimpare, L., \u2026 Martin, A. (2024)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Natural genetic variation underlying the negative effect of elevated CO2 on ionome composition in Arabidopsis thaliana. <\/em>eLife<\/i> 12:RP90170. https:\/\/doi.org\/10.7554\/eLife.90170.3<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Natural genetic variation underlying the negative effect of elevated CO2 on ionome composition in Arabidopsis thaliana. <\/em>eLife<\/i> 12:RP90170. https:\/\/doi.org\/10.7554\/eLife.90170.3<\/a><\/p>\n ” content_last_edited=”on|desktop” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Natural genetic variation underlying the negative effect of elevated CO2 on ionome composition in Arabidopsis thaliana. <\/em>eLife<\/i> 12:RP90170. https:\/\/doi.org\/10.7554\/eLife.90170.3<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 43<\/span> Ganault, P., Nahmani, J., \u2026 Milcu, A. (2024)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Earthworms and plants can decrease soil greenhouse gas emissions by modulating soil moisture fluctuations and soil macroporosity in a mesocosm experiment. Plos one. https:\/\/doi.org\/10.1371\/journal.pone.0289859<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Earthworms and plants can decrease soil greenhouse gas emissions by modulating soil moisture fluctuations and soil macroporosity in a mesocosm experiment. Plos one. https:\/\/doi.org\/10.1371\/journal.pone.0289859<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Earthworms and plants can decrease soil greenhouse gas emissions by modulating soil moisture fluctuations and soil macroporosity in a mesocosm experiment. Plos one. https:\/\/doi.org\/10.1371\/journal.pone.0289859<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 42**<\/span> Forey, O., Milcu, A., \u2026 Sauze, J. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Data from: Earthworms do not increase greenhouse gas emissions (CO2<\/sub> and N2<\/sub>O) in an ecotron experiment simulating a three-crop rotation system, Dryad, 2739988 bytes<\/em>. https:\/\/doi.org\/10.5061\/DRYAD.MGQNK9955<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Data from: Earthworms do not increase greenhouse gas emissions (CO2<\/sub> and N2<\/sub>O) in an ecotron experiment simulating a three-crop rotation system, Dryad, 2739988 bytes<\/em>. https:\/\/doi.org\/10.5061\/DRYAD.MGQNK9955<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Data from: Earthworms do not increase greenhouse gas emissions (CO2<\/sub> and N2<\/sub>O) in an ecotron experiment simulating a three-crop rotation system, Dryad, 2739988 bytes<\/em>. https:\/\/doi.org\/10.5061\/DRYAD.MGQNK9955<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_4,1_4,1_4,1_4″ make_equal=”on” _builder_version=”4.26.0″ _module_preset=”default” custom_padding=”25px|||||” global_colors_info=”{}”][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 41<\/span> Forey, O., Sauze, J., \u2026 Milcu, A. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Earthworms do not increase greenhouse gas emissions (CO2<\/sub> and N2<\/sub>O) in an ecotron experiment simulating a three-crop rotation system, Sci. Rep., 13<\/em>. https:\/\/doi.org\/10.1038\/s41598-023-48765-3<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Earthworms do not increase greenhouse gas emissions (CO2<\/sub> and N2<\/sub>O) in an ecotron experiment simulating a three-crop rotation system, Sci. Rep., 13<\/em>. https:\/\/doi.org\/10.1038\/s41598-023-48765-3<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Earthworms do not increase greenhouse gas emissions (CO2<\/sub> and N2<\/sub>O) in an ecotron experiment simulating a three-crop rotation system, Sci. Rep., 13<\/em>. https:\/\/doi.org\/10.1038\/s41598-023-48765-3<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 40<\/span> Siegwart, L., Piton, G., \u2026 Bertrand, I. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Carbon and nutrient colimitations control the microbial response to fresh organic carbon inputs in soil at different depths, Geoderma<\/em>, 440. https:\/\/doi.org\/10.1016\/j.geoderma.2023.116729<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Carbon and nutrient colimitations control the microbial response to fresh organic carbon inputs in soil at different depths, Geoderma<\/em>, 440. https:\/\/doi.org\/10.1016\/j.geoderma.2023.116729<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Carbon and nutrient colimitations control the microbial response to fresh organic carbon inputs in soil at different depths, Geoderma<\/em>, 440. https:\/\/doi.org\/10.1016\/j.geoderma.2023.116729<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 39<\/span> Voigt, C., Alexandre, A., \u2026 Og\u00e9e, J. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Examination of the parameters controlling the triple oxygen isotope composition of grass leaf water and phytoliths at a Mediterranean site: a model\u2013data approach, Biogeosciences<\/em>, 20, 2161\u20132187. https:\/\/doi.org\/10.5194\/bg-20-2161-2023<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Examination of the parameters controlling the triple oxygen isotope composition of grass leaf water and phytoliths at a Mediterranean site: a model\u2013data approach, Biogeosciences<\/em>, 20, 2161\u20132187. https:\/\/doi.org\/10.5194\/bg-20-2161-2023<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Examination of the parameters controlling the triple oxygen isotope composition of grass leaf water and phytoliths at a Mediterranean site: a model\u2013data approach, Biogeosciences<\/em>, 20, 2161\u20132187. https:\/\/doi.org\/10.5194\/bg-20-2161-2023<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 38*<\/span> Marx, V. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Soil researchers dig deeper into dirt\u2019s complexity. Nature Methods<\/em>, 20, 1131-1134.https:\/\/doi.org\/10.1038\/s41592-023-01962-4 <\/a> <\/p>\n ” content_phone=”<\/p>\n <\/span>Soil researchers dig deeper into dirt\u2019s complexity. Nature Methods<\/em>, 20, 1131-1134.https:\/\/doi.org\/10.1038\/s41592-023-01962-4 <\/a> <\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Soil researchers dig deeper into dirt\u2019s complexity. Nature Methods<\/em>, 20, 1131-1134.https:\/\/doi.org\/10.1038\/s41592-023-01962-4 <\/a> <\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_4,1_4,1_4,1_4″ make_equal=”on” _builder_version=”4.26.0″ _module_preset=”default” custom_padding=”25px|||||” global_colors_info=”{}”][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 37<\/span> Gillespie, L. M., Prada-Salcedo, L. D., \u2026 H\u00e4ttenschwiler, S. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Taxonomical and functional responses of microbial communities from forest soils of differing tree species diversity to drying-rewetting cycles. Pedobiologia<\/em>, 150875. https:\/\/doi.org\/10.1016\/j.pedobi.2023.150875<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Taxonomical and functional responses of microbial communities from forest soils of differing tree species diversity to drying-rewetting cycles. Pedobiologia<\/em>, 150875. https:\/\/doi.org\/10.1016\/j.pedobi.2023.150875<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Taxonomical and functional responses of microbial communities from forest soils of differing tree species diversity to drying-rewetting cycles. Pedobiologia<\/em>, 150875. https:\/\/doi.org\/10.1016\/j.pedobi.2023.150875<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 36<\/span> Paul, C., Piel, C., \u2026 Landais, A. (2023)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Determination of respiration and photosynthesis fractionation factors for atmospheric dioxygen inferred from a vegetatio-soil-atmosphere analogue of the terrestrial biosphere in closed chambers. Biogeoscience, <\/em>20, 1047-1062. https:\/\/doi.org\/10.5194\/bg-20-1047-2023<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Determination of respiration and photosynthesis fractionation factors for atmospheric dioxygen inferred from a vegetatio-soil-atmosphere analogue of the terrestrial biosphere in closed chambers. Biogeoscience, <\/em>20, 1047-1062. https:\/\/doi.org\/10.5194\/bg-20-1047-2023<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Determination of respiration and photosynthesis fractionation factors for atmospheric dioxygen inferred from a vegetatio-soil-atmosphere analogue of the terrestrial biosphere in closed chambers. Biogeoscience, <\/em>20, 1047-1062. https:\/\/doi.org\/10.5194\/bg-20-1047-2023<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 35<\/span> Voigt, C., Vallet-Coulomb, C., \u2026 Alexandre, A. (2021)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>17<\/sup>O-excess and d-excess of atmospheric water vapor measured by cavity ring-down spectrometry: Evidence of a matrix effect and implication for the calibration procedure. Rapid Communications in Mass Spectrometry<\/em>:1\u201316. https:\/\/doi\/10.1002\/rcm.9227<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>17<\/sup>O-excess and d-excess of atmospheric water vapor measured by cavity ring-down spectrometry: Evidence of a matrix effect and implication for the calibration procedure. Rapid Communications in Mass Spectrometry<\/em>:1\u201316. https:\/\/doi\/10.1002\/rcm.9227<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>17<\/sup>O-excess and d-excess of atmospheric water vapor measured by cavity ring-down spectrometry: Evidence of a matrix effect and implication for the calibration procedure. Rapid Communications in Mass Spectrometry<\/em>:1\u201316. https:\/\/doi\/10.1002\/rcm.9227<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 34<\/span> Outrequin, C., Alexandre, A., \u2026 Voigt, C. (2021)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>The triple oxygen isotope composition of phytoliths, a new proxy of atmospheric relative humidity: controls of soil water isotope composition, temperature, CO2 concentration and relative humidity. Climate of the Past<\/em>, 17, 1881-1902. https:\/\/doi.org\/10.5194\/cp-17-1881-2021<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>The triple oxygen isotope composition of phytoliths, a new proxy of atmospheric relative humidity: controls of soil water isotope composition, temperature, CO2 concentration and relative humidity. Climate of the Past<\/em>, 17, 1881-1902. https:\/\/doi.org\/10.5194\/cp-17-1881-2021<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>The triple oxygen isotope composition of phytoliths, a new proxy of atmospheric relative humidity: controls of soil water isotope composition, temperature, CO2 concentration and relative humidity. Climate of the Past<\/em>, 17, 1881-1902. https:\/\/doi.org\/10.5194\/cp-17-1881-2021<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_4,1_4,1_4,1_4″ make_equal=”on” _builder_version=”4.26.0″ _module_preset=”default” custom_padding=”25px|||||” global_colors_info=”{}”][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 33<\/span> Schmidt, A., Hines, J., \u2026 Eisenhauer, N. (2021)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>The iDiv Ecotron \u2013 a flexible research platform for multitrophic biodiversity research. Authorea<\/em>. https:\/\/doi.org\/10.22541\/au.161614989.97388658\/v1<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>The iDiv Ecotron \u2013 a flexible research platform for multitrophic biodiversity research. Authorea<\/em>. https:\/\/doi.org\/10.22541\/au.161614989.97388658\/v1<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>The iDiv Ecotron \u2013 a flexible research platform for multitrophic biodiversity research. Authorea<\/em>. https:\/\/doi.org\/10.22541\/au.161614989.97388658\/v1<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 32**<\/span> Barry, K., van Ruijven, J., \u2026 Stefanie Weigelt, A. P. (2020)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Data from: Limited evidence for spatial resource partitioning across temperate grassland biodiversity experiments. Dryad<\/em>, 1\u20133. https:\/\/doi.org\/10.5061\/dryad.7c01654<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Data from: Limited evidence for spatial resource partitioning across temperate grassland biodiversity experiments. Dryad<\/em>, 1\u20133. https:\/\/doi.org\/10.5061\/dryad.7c01654<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Data from: Limited evidence for spatial resource partitioning across temperate grassland biodiversity experiments. Dryad<\/em>, 1\u20133. https:\/\/doi.org\/10.5061\/dryad.7c01654<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 31<\/span> Roy, J., Rineau, F., \u2026 Milcu, A. (2020)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Ecotrons: powerful and versatile ecosystem analysers for ecology, agronomy and environmental science. Global change biology<\/em>, 27, 1387-1407. https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/gcb.15471<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Ecotrons: powerful and versatile ecosystem analysers for ecology, agronomy and environmental science. Global change biology<\/em>, 27, 1387-1407. https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/gcb.15471<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Ecotrons: powerful and versatile ecosystem analysers for ecology, agronomy and environmental science. Global change biology<\/em>, 27, 1387-1407. https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/gcb.15471<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 30<\/span> Resco de Dios, V., Anderegg, W. R. L., \u2026 Gessler, A. (2020)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Circadian Regulation Does Not Optimize Stomatal Behaviour. Plants<\/em>, 9, 1091. https:\/\/www.mdpi.com\/2223-7747\/9\/9\/1091<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Circadian Regulation Does Not Optimize Stomatal Behaviour. Plants<\/em>, 9, 1091. https:\/\/www.mdpi.com\/2223-7747\/9\/9\/1091<\/a><\/p>\n ” content_last_edited=”on|phone” _builder_version=”4.27.3″ _module_preset=”default” text_font=”IBM Plex Sans|300|||||||” text_font_size=”16px” text_letter_spacing=”1px” width=”100%” custom_margin=”3px||||false|false” text_font_size_tablet=”16px” text_font_size_phone=”16px” text_font_size_last_edited=”on|phone” locked=”off” global_colors_info=”{}”]<\/p>\n <\/span>Circadian Regulation Does Not Optimize Stomatal Behaviour. Plants<\/em>, 9, 1091. https:\/\/www.mdpi.com\/2223-7747\/9\/9\/1091<\/a><\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_4,1_4,1_4,1_4″ make_equal=”on” _builder_version=”4.26.0″ _module_preset=”default” custom_padding=”25px|||||” global_colors_info=”{}”][et_pb_column type=”1_4″ _builder_version=”4.25.1″ _module_preset=”default” background_color=”#EBF0F5″ custom_padding=”20px|20px|20px|20px|false|false” border_radii=”on|15px|15px|15px|15px” global_colors_info=”{}”][et_pb_text _builder_version=”4.25.1″ _module_preset=”default” text_font=”IBM Plex Sans||||||||” text_text_color=”#00284B” text_font_size=”20px” custom_margin=”||0px||false|false” custom_padding=”||||false|false” locked=”off” global_colors_info=”{}”]<\/p>\n 29<\/span> Gillespie, L.M., Fromin, N., \u2026 H\u00e4ttenschwiler, S. (2020)<\/p>\n [\/et_pb_text][et_pb_text content_tablet=”<\/p>\n <\/span>Higher tree diversity increases soil microbial resistance to drought. Communications Biology<\/em>, 3:377. https:\/\/doi.org\/10.1038\/s42003-020-1112-0<\/a><\/p>\n ” content_phone=”<\/p>\n <\/span>Higher tree diversity increases soil microbial resistance to drought.