Functionalized biochar from vegetable waste for phosphorus removal from aqueous solution and its potential use as a slow-release fertilizer

Cleaner Materials Pub Date : 2024-12-16 DOI:10.1016/j.clema.2024.100287

Rajesh Chanda , Toslim Jahid , Anik Karmokar , Bejoy Hossain , Md. Moktadir , Md. Saiful Islam , Nirupam Aich , Biplob Kumar Biswas

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Abstract

Agricultural runoff of phosphorus leads to the loss of this critical nutrient into the waterbodies and causes environmental problems like eutrophication. To tackle the growing concern, functionalized biochar as an adsorbent provides a sustainable method to capture the phosphorus from wastewater. Additionally, the P-laden biochar as a slow-release fertilizer improves plant nutrient uptake and crop yield. In this work, metal chloride-doped biochar derived from non-edible vegetable waste was prepared and applied as an adsorbent. Zinc chloride-doped biochar (ZBC) showed a better phosphorus adsorption capacity of 47.83 mg/g among the prepared biochar. The desorption study suggested that around 42 % of total adsorbed P was released within 336 h. The growth of mung plants over 70 days was monitored, along with mung bean yield, to assess the effectiveness of P-laden ZBC as a slow-release phosphorus fertilizer. The presented approach of non-edible waste valorization into slow-release fertilizer could contribute to tackling nutrient depletion and achieving a circular economy.

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从蔬菜垃圾中提取的功能化生物炭用于去除水溶液中的磷及其作为缓释肥料的潜在用途

磷的农业径流导致这种关键营养物质流失到水体中，并导致富营养化等环境问题。为了解决这一日益增长的问题，功能化生物炭作为吸附剂提供了一种可持续的方法来捕获废水中的磷。此外，含磷生物炭作为缓释肥料可提高植物养分吸收和作物产量。本研究以非食用蔬菜废料为原料制备了掺杂金属氯化物的生物炭，并将其作为吸附剂进行应用。在制备的生物炭中，氯化锌掺杂生物炭（ZBC）的磷吸附量为47.83 mg/g。解吸研究表明，在336小时内，约42%的总吸附磷被释放。在70天的时间里，我们监测了绿豆产量和绿植物的生长情况，以评估载磷ZBC作为缓释磷肥的有效性。提出的将不可食用废物转化为缓释肥料的方法有助于解决养分枯竭和实现循环经济。

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来源期刊

Cleaner Materials

CiteScore

9.20

自引率

0.00%

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