Direct speciation of soil phosphorus (P) by linear combination fitting (LCF) of P K-edge XANES spectra requires a standard set of spectra representing all major P species supposed to be present in the investigated soil. Here, available spectra of free- and cation-bound inositol hexakisphosphate (IHP), representing organic P, and of Fe, Al and Ca phosphate minerals are supplemented with spectra of adsorbed P binding forms. First, various soil constituents assumed to be potentially relevant for P sorption were compared with respect to their retention efficiency for orthophosphate and IHP at P levels typical for soils. Then, P K-edge XANES spectra for orthophosphate and IHP retained by the most relevant constituents were acquired. The spectra were compared with each other as well as with spectra of Ca, Al or Fe orthophosphate and IHP precipitates. Orthophosphate and IHP were retained particularly efficiently by ferrihydrite, boehmite, Al-saturated montmorillonite and Al-saturated soil organic matter (SOM), but far less efficiently by hematite, Ca-saturated montmorillonite and Ca-saturated SOM. P retention by dolomite was negligible. Calcite retained a large portion of the applied IHP, but no orthophosphate. The respective P K-edge XANES spectra of orthophosphate and IHP adsorbed to ferrihydrite, boehmite, Al-saturated montmorillonite and Al-saturated SOM differ from each other. They also are different from the spectra of amorphous FePO4, amorphous or crystalline AlPO4, Ca phosphates and free IHP. Inclusion of reference spectra of orthophosphate as well as IHP adsorbed to P-retaining soil minerals in addition to spectra of free or cation-bound IHP, AlPO4, FePO4 and Ca phosphate minerals in linear combination fitting exercises results in improved fit quality and a more realistic soil P speciation. A standard set of P K-edge XANES spectra of the most relevant adsorbed P binding forms in soils is presented.
Examining in situ processes in the soil
rhizosphere
requires spatial information on physical and chemical properties under
undisturbed conditions. We developed a correlative imaging workflow
for targeted sampling of roots in their three-dimensional (3D) context
and assessed the imprint of roots on chemical properties of the root–soil
contact zone at micrometer to millimeter scale. Maize (Zea mays) was grown in 15N-labeled soil
columns and pulse-labeled with 13CO2 to visualize
the spatial distribution of carbon inputs and nitrogen uptake together
with the redistribution of other elements. Soil columns were scanned
by X-ray computed tomography (X-ray CT) at low resolution (45 μm)
to enable image-guided subsampling of specific root segments. Resin-embedded
subsamples were then analyzed by X-ray CT at high resolution (10 μm)
for their 3D structure and chemical gradients around roots using micro-X-ray
fluorescence spectroscopy (μXRF), nanoscale secondary ion mass
spectrometry (NanoSIMS), and laser-ablation isotope ratio mass spectrometry
(LA-IRMS). Concentration gradients, particularly of calcium and sulfur,
with different spatial extents could be identified by μXRF.
NanoSIMS and LA-IRMS detected the release of 13C into soil
up to a distance of 100 μm from the root surface, whereas 15N accumulated preferentially in the root cells. We conclude
that combining targeted sampling of the soil–root system and
correlative microscopy opens new avenues for unraveling rhizosphere
processes in situ.
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