Linking atomic force microscopy with nanothermal analysis to assess microspatial distribution of material characteristics in young soils

Mouvenchery, Yamuna Kunhi; Miltner, Anja; Schurig, Christian; Kästner, Matthias; Schaumann, Gabriele E.

doi:10.1002/jpln.201500082

Cited by 5 publications

(2 citation statements)

References 54 publications

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“…Since 2010, AFM has been applied beyond life sciences, accepting the challenge using surface probing methods on more complex samples via operating AFM in advanced modes. This includes the simultaneous recording of topography and nanomechanical properties of minerals, microorganisms, and organic matter individually and collectively (Table 2), but also of natural materials separated from soil and sediments (Mouvenchery et al., 2016; Eusterhues et al., submitted; Figure 2) or even soil microaggregates (Gazze et al., 2018).…”

Section: Analyses Of Individual Aggregatesmentioning

confidence: 99%

Architecture of soil microaggregates: Advanced methodologies to explore properties and functions

Amelung,

Tang,

Siebers

et al. 2023

J. Plant Nutr. Soil Sci.

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The functions of soils are intimately linked to their three‐dimensional pore space and the associated biogeochemical interfaces, mirrored in the complex structure that developed during pedogenesis. Under stress overload, soil disintegrates into smaller compound structures, conventionally named aggregates. Microaggregates (<250 µm) are recognized as the most stable soil structural units. They are built of mineral, organic, and biotic materials, provide habitats for a vast diversity of microorganisms, and are closely involved in the cycling of matter and energy. However, exploring the architecture of soil microaggregates and their linkage to soil functions remains a challenging but demanding scientific endeavor. With the advent of complementary spectromicroscopic and tomographic techniques, we can now assess and visualize the size, composition, and porosity of microaggregates and the spatial arrangement of their interior building units. Their combinations with advanced experimental pedology, multi‐isotope labeling experiments, and computational approaches pave the way to investigate microaggregate turnover and stability, explore their role in element cycling, and unravel the intricate linkage between structure and function. However, spectromicroscopic techniques operate at different scales and resolutions, and have specific requirements for sample preparation and microaggregate isolation; hence, special attention must be paid to both the separation of microaggregates in a reproducible manner and the synopsis of the geography of information that originates from the diverse complementary instrumental techniques. The latter calls for further development of strategies for synlocation and synscaling beyond the present state of correlative analysis. Here, we present examples of recent scientific progress and review both options and challenges of the joint application of cutting‐edge techniques to achieve a sophisticated picture of the properties and functions of soil microaggregates.

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Section: Analyses Of Individual Aggregatesmentioning

confidence: 99%

Architecture of soil microaggregates: Advanced methodologies to explore properties and functions

Amelung,

Tang,

Siebers

et al. 2023

J. Plant Nutr. Soil Sci.

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show abstract

“…12 Recent technological advances, centred on enhanced feedback electronics and new scanning modes, now allow significantly better accuracy in probe-surface tracking, enabling novel AFM characterisation of more heterogeneous samples 13,14 and, as a result, AFM is becoming increasingly applied in soil studies. [15][16][17][18] In the present work, a standardized approach to analyzing soil aggregate topography with high spatial resolution nanomechanical mapping is developed using AFM. The combination of AFM imaging and probe selection has been first optimised: probes with short tips (such as probes 1 and 2 in Fig.…”

mentioning

confidence: 99%

Organic matter identifies the nano-mechanical properties of native soil aggregates

et al. 2018

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Localized variations at the nanoscale in soil aggregates and in the spatial organisation of soil organic matter (SOM) are critical to understanding the factors involved in soil composition and turnover. However soil nanoscience has been hampered by the lack of suitable methods to determine soil biophysical properties at nanometre spatial resolution with minimal sample preparation. Here we introduce for the first time an Atomic Force Microscopy (AFM)-based Quantitative Nano-Mechanical mapping (QNM) approach that allows the characterisation of the role of SOM in controlling surface nano-mechanical properties of soil aggregates. SOM coverage resulted in an increased roughness and surface variability of soil, as well as in decreased stiffness and adhesive properties. The latter also correlates with nano- to macro-wettability features as determined by contact angle measurements and Water Drop Penetration Time (WDPT) testing. AFM thus represents an ideal quantitative tool to complement existing techniques within the emerging field of soil nanoscience.

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SOM and Microbes—What Is Left From Microbial Life

Kästner

Miltner

2018

The Future of Soil Carbon

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Linking atomic force microscopy with nanothermal analysis to assess microspatial distribution of material characteristics in young soils

Cited by 5 publications

References 54 publications

Architecture of soil microaggregates: Advanced methodologies to explore properties and functions

Architecture of soil microaggregates: Advanced methodologies to explore properties and functions

Organic matter identifies the nano-mechanical properties of native soil aggregates

SOM and Microbes—What Is Left From Microbial Life

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