Ground Fire Legacy Effects on Water-Dynamics of Volcanic Tropical Soils

IF 2 Q3 SOIL SCIENCE

Spanish Journal of Soil Science Pub Date : 2023-10-23 DOI:10.3389/sjss.2023.11757

Luis D. Olivares-Martinez, Alberto Gomez-Tagle, Jorge Mataix-Solera

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引用次数: 0

Abstract

The forest floor is a critical component in maintaining the life cycles of forest ecosystems. It normally includes organic soil horizons, known as duff and litter, which are prone to be rapidly consumed after flaming and smoldering fires. This work aims to understand the legacy effects of surface and ground fires on the infiltration capacity of a volcanic forest soil. We studied five sites with fires recorded in the last 20 years. All of them are located in pine-oak forests of the volcanic mountain region in central Mexico with a temperate climate and Andic soil properties. Tension-infiltration tests were carried out to determine hydraulic conductivity and the number of active macropores. After each test, cores were taken to evaluate in a laboratory setting, where soil water repellency at different moisture concentrations and the integrative dynamic repellency index were determined. Field-saturated hydraulic conductivity was moderately high in all sites, with mean values of 13 and 42 mm·h −1 for burned and control plots, respectively. A non-linear relationship was found between recurrence and type of fires with the concentration of active pores and several dynamic water repellency parameters. This work confirmed the presence of latent combustion in these temperate neotropical forests. The changes in soil water repellency and hydraulic conductivity detected do not necessarily imply an exceeded soil infiltration capacity. However, many of the fires in this region are associated with increasing agricultural activities, so further studies are needed to determine if higher fire frequencies could exceed the resilience capacity of the soils triggering land degradation.

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地面火灾对热带火山土壤水动力学的影响

森林地面是维持森林生态系统生命周期的关键组成部分。它通常包括有机土壤层，被称为沙土和凋落物，它们很容易在燃烧和阴燃的火灾后迅速消耗。这项工作旨在了解地表和地面火灾对火山森林土壤渗透能力的遗留影响。我们研究了过去20年里有火灾记录的5个地点。它们都位于墨西哥中部火山山区的松栎林中，气候温和，土壤肥沃。通过拉伸-渗透试验测定了水导率和活性大孔隙的数量。每次测试后，取岩心在实验室环境中进行评估，在不同水分浓度下测定土壤的拒水性和综合动态拒水指数。所有试验点的现场饱和水力导率均较高，燃烧和对照试验点的平均值分别为13和42 mm·h−1。发现火灾的复发和类型与活性孔隙浓度和几个动态拒水参数之间存在非线性关系。这项工作证实了这些温带新热带森林中存在潜在燃烧。检测到的土壤拒水性和导电性的变化并不一定意味着土壤入渗能力超过。然而，该地区的许多火灾与农业活动的增加有关，因此需要进一步研究以确定较高的火灾频率是否会超过引发土地退化的土壤的恢复能力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Spanish Journal of Soil Science SOIL SCIENCE-

CiteScore

2.20

自引率

0.00%

发文量

期刊介绍： The Spanish Journal of Soil Science (SJSS) is a peer-reviewed journal with open access for the publication of Soil Science research, which is published every four months. This publication welcomes works from all parts of the world and different geographic areas. It aims to publish original, innovative, and high-quality scientific papers related to field and laboratory research on all basic and applied aspects of Soil Science. The journal is also interested in interdisciplinary studies linked to soil research, short communications presenting new findings and applications, and invited state of art reviews. The journal focuses on all the different areas of Soil Science represented by the Spanish Society of Soil Science: soil genesis, morphology and micromorphology, physics, chemistry, biology, mineralogy, biochemistry and its functions, classification, survey, and soil information systems; soil fertility and plant nutrition, hydrology and geomorphology; soil evaluation and land use planning; soil protection and conservation; soil degradation and remediation; soil quality; soil-plant relationships; soils and land use change; sustainability of ecosystems; soils and environmental quality; methods of soil analysis; pedometrics; new techniques and soil education. Other fields with growing interest include: digital soil mapping, soil nanotechnology, the modelling of biological and biochemical processes, mechanisms and processes responsible for the mobilization and immobilization of nutrients, organic matter stabilization, biogeochemical nutrient cycles, the influence of climatic change on soil processes and soil-plant relationships, carbon sequestration, and the role of soils in climatic change and ecological and environmental processes.