Add to ORKGUranium-series (U-series) isotopes are fractionated in soils, sediments and natural waters by erosion and weathering processes. Recent applications of U-series isotopes to sedimentary deposits have enabled the landscape response to glacial-interglacial climate change to be studied. This thesis focuses on the developing comminution dating (or the comminution age) technique that utilises U isotopes to constrain the time elapsed since mineral grains were reduced to ca. \u3c63μm in size. Applied to hillslope and fluvial systems, the comminution age represents the sediment residence time, and applied to sedimentary deposits of known depositional age, the palaeo sediment residence time can be constrained
As climate is changing rapidly, there is an increasing need to understand how water and soil resourc...
Studying how catchment erosion has responded to past climate change can help us to better understand...
Studying how catchment erosion has responded to past climate change can help us better understand no...
Uranium-series (U-series) isotopes are fractionated in soils, sediments and natural waters by erosio...
Understanding how erosional and sediment transport processes have responded to past environmental ch...
Obtaining quantitative information about the timescales associated with sediment transport, storage,...
Quantifying the rates of landscape evolution in response to climate change is inhibited by the diffi...
The uranium-series isotope signatures of the suspended and dissolved load of rivers have emerged as ...
Uranium isotope ratios have been determined for the fine-grained detrital fraction of Pleistocene Wi...
Uranium (U) isotopes are useful for constraining the timescales of weathering and erosion processes....
© 2020 Elsevier Ltd Uranium (U) isotopes can be used to estimate the comminution age of sediments, i...
The time elapsed since detrital minerals were reduced to <63μm by weathering can be constrained by a...
The uranium isotope composition ( 234 U and 238 U) of detrital matter has become an essential tool f...
Uranium-series (U-series) analyses are an essential component of many research projects in Earth and...
The uranium-series isotopic compositions of soils and sediments evolve in response to time and weath...
As climate is changing rapidly, there is an increasing need to understand how water and soil resourc...
Studying how catchment erosion has responded to past climate change can help us to better understand...
Studying how catchment erosion has responded to past climate change can help us better understand no...
Uranium-series (U-series) isotopes are fractionated in soils, sediments and natural waters by erosio...
Understanding how erosional and sediment transport processes have responded to past environmental ch...
Obtaining quantitative information about the timescales associated with sediment transport, storage,...
Quantifying the rates of landscape evolution in response to climate change is inhibited by the diffi...
The uranium-series isotope signatures of the suspended and dissolved load of rivers have emerged as ...
Uranium isotope ratios have been determined for the fine-grained detrital fraction of Pleistocene Wi...
Uranium (U) isotopes are useful for constraining the timescales of weathering and erosion processes....
© 2020 Elsevier Ltd Uranium (U) isotopes can be used to estimate the comminution age of sediments, i...
The time elapsed since detrital minerals were reduced to <63μm by weathering can be constrained by a...
The uranium isotope composition ( 234 U and 238 U) of detrital matter has become an essential tool f...
Uranium-series (U-series) analyses are an essential component of many research projects in Earth and...
The uranium-series isotopic compositions of soils and sediments evolve in response to time and weath...
As climate is changing rapidly, there is an increasing need to understand how water and soil resourc...
Studying how catchment erosion has responded to past climate change can help us to better understand...
Studying how catchment erosion has responded to past climate change can help us better understand no...