利用基于完整样本的新光谱 PTF 预测土壤容重

IF 5.6 1区 农林科学 Q1 SOIL SCIENCE
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引用次数: 0

摘要

在大面积地区,采集样本和测量土壤容重(BD)往往需要耗费大量人力和物力。与此相反,土壤光谱易于测量,便于预测土壤容重。然而,文献表明,在地面和/或筛分样品上扫描光谱时对土壤物理结构的破坏可能会阻碍光谱技术准确预测体积密度的能力。此外,由于一些与 BD 具有高度相关性的土壤特性(如土壤有机质 (SOM))在大多数土壤数据库中都是常规测量和可用的,因此与使用土壤特性或光谱相比,将它们与土壤光谱耦合可能会改善 BD 预测。因此,在本研究中,我们提出了一种新的光谱土壤转移函数(spectral PTF),该函数将完整样本上测量到的土壤可见光和近红外光谱与其他土壤特性结合起来,以准确预测 BD(BD = f(土壤光谱,土壤特性)),这不同于仅使用土壤特性(BD = f(土壤特性))或仅使用光谱(BD = f(土壤光谱))的传统 PTF。在本研究中,我们采集了中国东北地区 586 个地点的表层土(0-20 厘米)和底层土(20-40 厘米)样本,覆盖面积达 109 万平方公里,这些地点均为高 SOM 含量的黑土。选取了五种常规测量的土壤特性:利用偏最小二乘法回归校准了具有一种、两种和三种土壤特性的各种光谱 PTF。交叉验证结果表明,当使用 SOM + MC + Silt 或 SOM + MC 时,传统 PTF 对底土的 BD 预测 R 值为 0.51,RMSE 为 0.11 g-cm。与底土相比,表土和所有土层(表土+底土)的 BD 预测精度较低,并且在 BD 值超过 1.5 g-cm 时出现了饱和效应。出乎意料的是,虽然土壤光谱是在完整样本上测量的,但其 BD 预测准确度并没有高于传统的 PTF。不过,在光谱 PTF 中加入土壤属性可以提高预测精度,并改善高 BD 值的饱和效应。无论样品是表层土、底层土还是所有土层,带有单一土壤特性(MC)的最佳光谱 PTF 都具有可接受的 BD 预测性能,R≥0.49,RPD>1.4,RPIQ>1.7。此外,具有两种或三种土壤特性的光谱 PTF 预测性能稍好,并且在不同的土壤特性组合中预测结果更稳定。这些结果表明,土壤特性和光谱在 BD 预测中是不可替代的。我们的研究证明了光谱 PTF 在准确预测 BD 方面的潜力,并为利用土壤光谱预测其他土壤性质提供了启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Predicting the soil bulk density using a new spectral PTF based on intact samples

Sample collection and measurement of soil bulk density (BD) are often labor-intensive and expensive in large regions. Conversely, soil spectra are easy to measure and facilitate BD prediction. However, the literature suggests that the damage to the physical structure of soil during scanning spectra on the ground and/or sieved samples might hinder the capacity of spectral technology to accurately predict BD. In addition, because some soil properties that have high correlations with BD, such as the soil organic matter (SOM), are routinely measured and available in most soil databases, coupling them with soil spectra may improve BD prediction compared to using soil properties or spectra. Therefore, in this study, we propose a novel spectral pedo-transfer function (spectral PTF) that couples the measured visible and near-infrared spectra of soils on intact samples and other soil properties to accurately predict the BD (BD = f (soil spectra, soil properties)), which is different from the traditional PTF that uses only soil properties (BD = f (soil properties)) or spectra alone (BD = f (soil spectra)). In this study, we collected topsoil (0–20 cm) and subsoil (20–40 cm) samples from 586 sites in Northeast China, covering a large area of 1.09 million km2 characterized by black soils with high SOM contents. Five routinely measured soil properties were selected: SOM, moisture content (MC), Sand, Silt, and Clay, and various spectral PTFs with one, two, and three soil properties were calibrated using the partial least square regression. The cross-validation results show that the traditional PTF can only predict BD for subsoil with an R2 of 0.51 and an RMSE of 0.11 g·cm−3 when using SOM + MC + Silt or SOM + MC. Compared to subsoil, topsoil and all layers (topsoil + subsoil) had a lower BD prediction accuracy, and a saturation effect was observed for BD values above 1.5 g·cm−3. Unexpectedly, the soil spectra did not provide a higher BD prediction accuracy than traditional PTFs, although the spectra were measured on intact samples. However, adding soil properties to the spectral PTF improved the prediction accuracy and saturation effect for high BD values. The optimal spectral PTF with a single soil property (MC) showed an acceptable BD prediction performance with R2≥0.49, RPD>1.4, and RPIQ>1.7 regardless of whether the sample was topsoil, subsoil, or all layers. Furthermore, the spectral PTF with two or three soil properties yielded a slightly better prediction performance and a more stable prediction among different combinations of soil properties. These results indicate that soil properties and spectra are irreplaceable for BD prediction. Our study demonstrates the potential of spectral PTFs for the accurate prediction of BD and offers insights into the prediction of other soil properties using soil spectra.

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来源期刊
Geoderma
Geoderma 农林科学-土壤科学
CiteScore
11.80
自引率
6.60%
发文量
597
审稿时长
58 days
期刊介绍: Geoderma - the global journal of soil science - welcomes authors, readers and soil research from all parts of the world, encourages worldwide soil studies, and embraces all aspects of soil science and its associated pedagogy. The journal particularly welcomes interdisciplinary work focusing on dynamic soil processes and functions across space and time.
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