A Crucial Role for Technology in Sustainable Agriculture

IF 2.3 Q1 AGRICULTURE, MULTIDISCIPLINARY ACS agricultural science & technology Pub Date : 2024-02-13 DOI:10.1021/acsagscitech.3c00426

Brent Brower-Toland, Julia L. Stevens, Lyle Ralston, Kevin Kosola and Thomas L. Slewinski*,

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Abstract

The impacts of climate change, particularly extreme weather events, will increase the likelihood of crop failure in the future. As such, the need for the development of climate-resilient crops that increase agricultural efficiency and sustain sustainable land use is critical to food security. Conservation agriculture, including practices such as reduced tillage, continuous cover, and crop rotation, provides a foundation for safeguarding agricultural systems. To support the widespread adoption of these practices, it will be necessary to make technological advancements through machinery breakthroughs, automation, advanced genetics, and biotechnology. Here we review approaches that integrate biotechnology and new breeding techniques to protect the yield into a conservation framework to accelerate sustainable intensification. By designing crops to function in the optimal planting configurations, improved crop rotational systems, and smart soil nutrient management, we can grow even more with less.

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技术在可持续农业中的关键作用

气候变化的影响，特别是极端天气事件，将增加未来作物歉收的可能性。因此，需要开发能抵御气候变化的作物，提高农业效率，维持土地的可持续利用，这对粮食安全至关重要。保护性农业，包括减少耕作、连续覆盖和轮作等做法，为保护农业系统奠定了基础。为了支持这些做法的广泛采用，有必要通过机械突破、自动化、先进遗传学和生物技术来实现技术进步。在此，我们回顾了将生物技术和新型育种技术融入保护框架以保护产量的方法，从而加快可持续集约化进程。通过设计作物的最佳种植配置、改进作物轮作系统和智能土壤养分管理，我们可以以更少的投入获得更多的产出。

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来源期刊

ACS agricultural science & technology

CiteScore

2.80

自引率

0.00%

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