Quantifying the importance of biotic and abiotic drivers in creating lags in soil {CO2} efflux. 20:8461.
.
2018. Biotic soil-plant interaction processes explain most of hysteretic soil {CO2} efflux response to temperature in cross-factorial mesocosm experiment. Scientific Reports. 10:905.
.
2020. Interferometric {Ground} {Cancellation} for {Above} {Ground} {Biomass} {Estimation}. IEEE Transactions on Geoscience and Remote Sensing. 58:6410–6419.
.
2020. Ecological emergence of thermal clines in body size. Global Change Biology. 19:3062–3068.
.
2013. .
2018. Assessing the performance of indicators resulting from three-component {Freeman}–{Durden} polarimetric {SAR} interferometry decomposition at {P}-and {L}-band in estimating tropical forest aboveground biomass. International Journal of Remote Sensing. 41:433–454.
.
2020. Chapter {One} - {A} multitrophic perspective on biodiversity–ecosystem functioning research. Advances in {Ecological} {Research}. 61:1–54.
.
2019. Compositional response of {Amazon} forests to climate change. Global Change Biology.
.
2018. Few multiyear precipitation–reduction experiments find a shift in the productivity–precipitation relationship. Global Change Biology. 22:2570–2581.
.
2016. .
2020. Stoichiometric consequences of size-selective mortality: {An} experimental test using the {Japanese} medaka ({Oryzias} latipes). Science of The Total Environment. 724:138193.
.
2020. Stoichiometric consequences of size-selective mortality: {An} experimental test using the {Japanese} medaka ({Oryzias} latipes). Science of The Total Environment. 724:138193.
.
2020. Stoichiometric consequences of size-selective mortality: {An} experimental test using the {Japanese} medaka ({Oryzias} latipes). Science of The Total Environment. 724:138193.
.
2020. Environmental {DNA} provides information on sediment sources: {A} study in catchments affected by {Fukushima} radioactive fallout. Science of The Total Environment. 665:873–881.
.
2019. Estimating leaf mass per area and equivalent water thickness based on leaf optical properties: {Potential} and limitations of physical modeling and machine learning. Remote Sensing of Environment. 231:110959.
.
2019. The {Impact} of {Competition} and {Allelopathy} on the {Trade}-{Off} between {Plant} {Defense} and {Growth} in {Two} {Contrasting} {Tree} {Species}. Frontiers in Plant Science. 7:594.
.
2016. {DNA} from lake sediments reveals long-term ecosystem changes after a biological invasion. Science Advances. 4:eaar4292.
.
2018. .
2018. .
2018. .
2020. A simulation method to infer tree allometry and forest structure from airborne laser scanning and forest inventories. Remote Sensing of Environment. 251:112056.
.
2020. Spatial distribution of points. Handbook of {Spatial} {Analysis}. :71–111.
.
2018. Response to {Editor} to the comment by {Schipper} to our paper entitled “{Continuous} soil carbon storage of old permanent pastures in {Amazonia}”. Global Change Biology. 24:e732–e733.
.
2018. Bottom-up and top-down control of dispersal across major organismal groups. Nature Ecology and Evolution. 2:1859–1863.
.
2018. Climate controls over the net carbon uptake period and amplitude of net ecosystem production in temperate and boreal ecosystems. Agricultural and Forest Meteorology. 243:9–18.
.
2017.