Ozone dose-response relationships for tropical crops reveal potential threat to legume and wheat production, but not to millets.. 2020.
Ozone impacts on vegetation in a nitrogen enriched and changing climate. Environmental Pollution. 208:898-908.. 2016.
Ozone pollution will compromise efforts to increase global wheat production.. Global Change Biology. 24:3560-3574.. 2018.
Ozone risk assessment for agricultural crops in Europe: Further development of stomatal flux and flux-response relationships for European wheat and potato. Atmospheric Environment. 41:3022-3040.. 2007.
Ozone - the persistent menace: interactions with the N cycle and climate change. Current Opinion in Environmental Sustainability. 9-10:9-19.. 2014.
Predicting community sensitivity to ozone, using Ellenberg Indicator values. Environmental Pollution. 146:744-753.. 2007.
Relationship between site-specific nitrogen concentrations in mosses and measured wet bulk atmospheric nitrogen deposition across Europe. Environmental Pollution. 194:50-59.. 2014.
A Site-Specific Analysis of the Implications of a Changing Ozone Profile and Climate for Stomatal Ozone Fluxes in Europe.. 2019.
Spatially valid data of atmospheric deposition of heavy metals and nitrogen derived by moss surveys for pollution risk assessments of ecosystems (vol 23, pg 10457, 2016). Environmental Science and Pollution Research. 23:21123-21124.. 2016.
A synthesis of AOT40-based response functions and critical levels of ozone for agricultural and horticultural crops. Atmospheric Environment. 41:2630-2643.. 2007.
Temporal trends (1990-2000) in the concentration of cadmium, lead and mercury in mosses across Europe. Environmental Pollution. 151:368-376.. 2008.
Temporal trends in the concentration of arsenic, chromium, copper, iron, nickel, vanadium and zinc in mosses across Europe. Atmospheric Environment. 41:6673-6687.. 2007.
Terrestrial mosses as biomonitors of atmospheric POPs pollution: A review. Environmental Pollution. 173:245-254.. 2013.