Lifting the profile of deep soil carbon in New Zealand’s managed planted forests

IF 5.8 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Carbon Balance and Management Pub Date : 2025-08-14 DOI:10.1186/s13021-025-00323-2

Loretta G. Garrett, Katherine A. Heckman, Angela R. Possinger, Brian D. Strahm, Jeff A. Hatten, Fiona P. Fields, Steve A. Wakelin

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Abstract

Background

Forest soils are a globally significant carbon-store, including in deep layers (> 30 cm depth). However, there is high uncertainty regarding the response of deep soil organic carbon (DSOC) to climate change and the resulting impact on the total OC budget for forest ecosystems. Managed forests have an opportunity to reduce the risk of DSOC loss with climate change, however, the basic understanding of DSOC is lacking. Planted forests in New Zealand are managed with very limited knowledge of DSOC, both in the amount and the capacity of the soil to continue to store carbon with climate change. In this study, we explore DSOC stocks to at least 2 m depth at 15 planted forest sties in New Zealand. We also explore DSOC radiocarbon age and soil mineralogy, then contextualise our results within international SOC datasets and climate change vulnerability frameworks to identify research priorities for New Zealand’s planted forest soils.

Results

DSOC stocks and soil mineralogy in New Zealand’s planted forests were diverse both horizontally across soil types and vertically throughout the soil profile. Critically, limiting measurements of SOC to the top 30 cm misses more than half of the SOC stocks present to at least 2 m depth (mean 57%; range 33–72%). At depth, mineral-associated OC was the dominant fraction of DSOC (average > 90%) and was on average much older (> 1000 years) than the current planted forest land use (< 100 years).

Conclusions

This small case study highlights that New Zealand’s planted forests contain substantial stocks of DSOC, much of which is older than the current forest land use. The deep soils were dominated by reactive metals, and although the age of DSOC suggest long-term stability, the large contribution of reactive metal-mediated SOC stabilisation may indicate vulnerability to warming soil temperatures relative to other climate change factors. There is a pressing need to expand soil sampling to greater depths and establish a robust SOC baseline for New Zealand’s planted forests. This is essential for enabling spatial predictions of DSOC dynamics under future climate scenarios, identify the key controls on DSOC persistence, and concomitant impacts on forest ecosystem function and resilience.

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提高新西兰管理人工林深层土壤碳含量

森林土壤是全球重要的碳储存库，包括在深层（30厘米深）。然而，深层土壤有机碳（DSOC）对气候变化的响应及其对森林生态系统总有机碳收支的影响存在很大的不确定性。管理森林有机会降低气候变化导致的DSOC损失风险，然而，缺乏对DSOC的基本认识。在管理新西兰的人工林时，人们对DSOC的了解非常有限，无论是在土壤的数量还是土壤在气候变化中继续储存碳的能力方面。在这项研究中，我们对新西兰15个人工林至少2 m深度的DSOC储量进行了研究。我们还探索了DSOC放射性碳年龄和土壤矿物学，然后将我们的结果置于国际SOC数据集和气候变化脆弱性框架中，以确定新西兰种植森林土壤的研究重点。结果新西兰人工林土壤有机碳储量和土壤矿物学在水平方向上和垂直方向上均存在差异。至关重要的是，将有机碳的测量限制在顶部30厘米，至少2米深度的有机碳储量超过一半(平均57%；33 - 72%)。在深层，矿物相关OC是DSOC的主要部分（平均为90%），并且平均比目前的人工林土地利用（100年）要古老得多（1000年）。这个小的案例研究强调了新西兰的人工林含有大量的DSOC储量，其中大部分比目前的森林土地利用更古老。深层土壤以活性金属为主，虽然DSOC的年龄表明长期稳定，但相对于其他气候变化因素，活性金属介导的有机碳稳定的巨大贡献可能表明土壤温度变暖对土壤的脆弱性。目前迫切需要将土壤采样扩大到更深的深度，并为新西兰的人工林建立一个可靠的有机碳基线。这对于实现未来气候情景下DSOC动态的空间预测、确定DSOC持久性的关键控制因素以及对森林生态系统功能和恢复力的影响至关重要。

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

Carbon Balance and Management Environmental Science-Management, Monitoring, Policy and Law

CiteScore

7.60

自引率

0.00%

发文量

审稿时长

14 weeks

期刊介绍： Carbon Balance and Management is an open access, peer-reviewed online journal that encompasses all aspects of research aimed at developing a comprehensive policy relevant to the understanding of the global carbon cycle. The global carbon cycle involves important couplings between climate, atmospheric CO2 and the terrestrial and oceanic biospheres. The current transformation of the carbon cycle due to changes in climate and atmospheric composition is widely recognized as potentially dangerous for the biosphere and for the well-being of humankind, and therefore monitoring, understanding and predicting the evolution of the carbon cycle in the context of the whole biosphere (both terrestrial and marine) is a challenge to the scientific community. This demands interdisciplinary research and new approaches for studying geographical and temporal distributions of carbon pools and fluxes, control and feedback mechanisms of the carbon-climate system, points of intervention and windows of opportunity for managing the carbon-climate-human system. Carbon Balance and Management is a medium for researchers in the field to convey the results of their research across disciplinary boundaries. Through this dissemination of research, the journal aims to support the work of the Intergovernmental Panel for Climate Change (IPCC) and to provide governmental and non-governmental organizations with instantaneous access to continually emerging knowledge, including paradigm shifts and consensual views.