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引用次数: 0
摘要
水压力是葡萄酒非典型老化(ATA)的主要原因,其特征是令人不悦的嗅觉感受。ATA 的主要感官和化学标志是 2-氨基苯乙酮(AAP)。在起泡葡萄酒(SW)二次发酵前及早检测出 ATA 对生产高品质产品至关重要。气候变化引起的干旱严重影响了农业,包括葡萄种植业,尤其是土壤较浅、可用水量(AWC)减少的葡萄园。本研究考察了用于酿制 SW 的基酒(BW)中 AWC 与 ATA 之间的关系。十个葡萄园被分为三个 AWC 类别(低、中、高)。在两个生长季中对水分胁迫水平进行了监测,以探究其对植物生产行为和 AAP 发展的影响。在第一个年份,干旱条件导致所有 AWC 等级的 BW 都可能受到 ATA 污染。这种影响因AWC而异,低AWC葡萄园承受的压力更大,生产出的BW的AAP水平更高,植被生产失衡。与此相反,下一季降雨量异常,导致一些BW可能受到ATA的影响,但AWC等级之间的AAP含量或植被生产平衡没有明显差异。总之,在低AWC土壤上生长的葡萄树,其BW出现问题的风险较高,尤其是在干旱的年份。
Exploring the relationship between field available water capacity (AWC) and atypical aging (ATA) development in base wines.
Hydric stress is a leading cause of atypical aging (ATA) in wine, characterized by unpleasant olfactory notes. The main sensorial and chemical marker of ATA is 2-aminoacetophenone (AAP). Early detection of ATA before the second fermentation in sparkling wines (SWs) is crucial for producing high-quality products. Climate change-induced droughts significantly impact agriculture, including grape farming, particularly in vineyards with shallow soils and reduced available water capacity (AWC). This study examined the relationship between AWC and ATA in base wines (BWs) intended for SW production. Ten vineyards were classified into three AWC categories (low, medium, and high). Hydric stress levels were monitored over two growing seasons to explore their effects on vegeto-productive behavior and AAP development. During the first vintage, drought conditions led to potentially ATA-tainted BWs across all AWC classes. The impact varied with AWC, with low-AWC vineyards experiencing higher stress and producing BWs with elevated AAP levels and vegeto-productive imbalance. In contrast, the following season had unusual rainfall, resulting in some potentially ATA-affected BWs, but no significant differences in AAP content or vegeto-productive balance among the AWC classes were observed. In conclusion, grapevines on low-AWC soils are at a higher risk of producing faulty BWs, particularly in dry vintages.
期刊介绍:
The goal of the Journal of Food Science is to offer scientists, researchers, and other food professionals the opportunity to share knowledge of scientific advancements in the myriad disciplines affecting their work, through a respected peer-reviewed publication. The Journal of Food Science serves as an international forum for vital research and developments in food science.
The range of topics covered in the journal include:
-Concise Reviews and Hypotheses in Food Science
-New Horizons in Food Research
-Integrated Food Science
-Food Chemistry
-Food Engineering, Materials Science, and Nanotechnology
-Food Microbiology and Safety
-Sensory and Consumer Sciences
-Health, Nutrition, and Food
-Toxicology and Chemical Food Safety
The Journal of Food Science publishes peer-reviewed articles that cover all aspects of food science, including safety and nutrition. Reviews should be 15 to 50 typewritten pages (including tables, figures, and references), should provide in-depth coverage of a narrowly defined topic, and should embody careful evaluation (weaknesses, strengths, explanation of discrepancies in results among similar studies) of all pertinent studies, so that insightful interpretations and conclusions can be presented. Hypothesis papers are especially appropriate in pioneering areas of research or important areas that are afflicted by scientific controversy.
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