TY - JOUR
T1 - Evaluating the particle densities of subarctic soils using pedotransfer functions and vis–NIR spectroscopy
AU - Weber, Peter L.
AU - Hermansen, Cecilie
AU - Norgaard, Trine
AU - Pesch, Charles
AU - Møldrup, Per
AU - Greve, Mogens Humlekrog
AU - Arthur, Emmanuel
AU - de Jonge, Lis Wollesen
PY - 2022/7/1
Y1 - 2022/7/1
N2 - The particle density (ρ
s) is a fundamental physical property needed for calculating the soil porosity and phase distributions. While ρ
s is often estimated using soil organic matter (SOM) content and particle size distribution, the specific densities of each soil component remain unclear in a subarctic agricultural setting. This study aimed to evaluate the ρ
s of soils from Southwest Greenland using a three-compartment model (3CM) based on the mixing ratio of SOM derived from loss-on-ignition, mineral particles <20 μm (FC), and mineral particles ≥20 μm (CC). We further evaluated the accuracy of the 3CM against pedotransfer functions (PTFs) and visible near-infrared (vis–NIR) spectroscopic models. A total of 324 soil samples from 16 Greenlandic agricultural fields were investigated, covering a wide range in SOM content (0.021–0.602 kg kg
–1) and clay content (0.020–0.185 kg kg
–1). Despite their high SOM content, the Greenlandic soils exhibited relatively high ρ
s (1.936–3.044 Mg m
–3), which together with a large SOM/organic carbon ratio of 2.16 indicated a high SOM density of 1.493 Mg m
–3. The 3CM fit on all soils indicated FC and CC densities of 3.047 and 2.713 Mg m
–3, respectively, while a subset of soils (n = 203) from the same geological setting resulted in FC and CC densities of 2.738 and 2.731 Mg m
–3. Prediction accuracy of the 3CM (RMSE = 0.067 Mg m
–3) was similar to PTFs (RMSE = 0.068–0.070 Mg m
–3) and better than vis–NIR spectroscopic models (RMSE = 0.091 Mg m
–3).
AB - The particle density (ρ
s) is a fundamental physical property needed for calculating the soil porosity and phase distributions. While ρ
s is often estimated using soil organic matter (SOM) content and particle size distribution, the specific densities of each soil component remain unclear in a subarctic agricultural setting. This study aimed to evaluate the ρ
s of soils from Southwest Greenland using a three-compartment model (3CM) based on the mixing ratio of SOM derived from loss-on-ignition, mineral particles <20 μm (FC), and mineral particles ≥20 μm (CC). We further evaluated the accuracy of the 3CM against pedotransfer functions (PTFs) and visible near-infrared (vis–NIR) spectroscopic models. A total of 324 soil samples from 16 Greenlandic agricultural fields were investigated, covering a wide range in SOM content (0.021–0.602 kg kg
–1) and clay content (0.020–0.185 kg kg
–1). Despite their high SOM content, the Greenlandic soils exhibited relatively high ρ
s (1.936–3.044 Mg m
–3), which together with a large SOM/organic carbon ratio of 2.16 indicated a high SOM density of 1.493 Mg m
–3. The 3CM fit on all soils indicated FC and CC densities of 3.047 and 2.713 Mg m
–3, respectively, while a subset of soils (n = 203) from the same geological setting resulted in FC and CC densities of 2.738 and 2.731 Mg m
–3. Prediction accuracy of the 3CM (RMSE = 0.067 Mg m
–3) was similar to PTFs (RMSE = 0.068–0.070 Mg m
–3) and better than vis–NIR spectroscopic models (RMSE = 0.091 Mg m
–3).
UR - http://www.scopus.com/inward/record.url?scp=85131520051&partnerID=8YFLogxK
U2 - 10.1002/saj2.20410
DO - 10.1002/saj2.20410
M3 - Journal article
SN - 0361-5995
VL - 86
SP - 964
EP - 978
JO - Soil Science Society of America Journal
JF - Soil Science Society of America Journal
IS - 4
ER -