The contribution of near surface geophysics to measure soil related terroir factors in viticulture: A review

IF 5.6 1区农林科学 Q1 SOIL SCIENCE

Geoderma Pub Date : 2024-08-19 DOI:10.1016/j.geoderma.2024.116983

Cornelis van Leeuwen , Myriam Schmutz , Laure de Rességuier

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Abstract

Wine quality is affected by environmental factors in the location where the vines are cultivated, in particular the soil and the climate. Major soil-related factors influencing vine development, yield, and berry composition (and thus wine quality) include soil water availability, soil temperature, and soil nutrients, particularly nitrogen. These can be impacted by soil depth and soil compaction. Mapping these factors with classical field-based methods is constraining and expensive. Near surface geophysics (NSG) can be useful in increasing the resolution of data acquisition and, possibly, its cost. Among these techniques, many are already commercially available, but some of them, including Magnetic Resonance Sounding, Induced Polarization and Spectral Analysis of Surface Waves, require a high degree of expertise for acquisition and processing. These should be further developed in order to enlarge the application possibilities. This article reviews soil-related parameters relevant to terroir expression in vineyards and how these can be measured with NSG techniques.

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近地表地球物理学对测量葡萄栽培中与土壤相关的风土因素的贡献：综述

葡萄酒质量受葡萄种植地的环境因素影响，尤其是土壤和气候。影响葡萄树生长、产量和浆果成分（进而影响葡萄酒质量）的主要土壤相关因素包括土壤水分供应、土壤温度和土壤养分，尤其是氮。这些因素会受到土壤深度和土壤压实度的影响。用传统的实地方法绘制这些因素的图谱既受限制又昂贵。近地表地球物理学（NSG）可以提高数据采集的分辨率，并在可能的情况下降低成本。在这些技术中，有许多已经可以在市场上买到，但其中一些技术，包括磁共振探测、诱导极化和表面波频谱分析，在采集和处理方面需要很高的专业知识。应进一步开发这些技术，以扩大应用范围。本文回顾了与葡萄园风土相关的土壤参数，以及如何利用 NSG 技术测量这些参数。

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

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.