Effect of Urea-Calcium Sulfate Cocrystal Nitrogen Fertilizer on Sorghum Productivity and Soil N2O Emissions

Bista, Prakriti; Eisa, Mohamed; Ragauskaitė, Dovilė; Sapkota, Sundar; Baltrušaitis, Jonas; Ghimire, Rajan

doi:10.3390/su15108010

Cited by 6 publications

(1 citation statement)

References 51 publications

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“…It is worth noting that the greenhouse gas potential of N 2 O is approximately 300 times more potent than CO 2 . – The implications of N loss extend beyond environmental concerns and intersect with energy pollution. Specifically, the production of NH 3 , a precursor to urea, has been implicated in significant energy consumption accounting for an estimated 3–5% of the total yield from natural gas and between 1 and 2% of the world’s energy resources. , Furthermore, due to the large influx of urea into the environment as a mineral fertilizer, it significantly contributes to the dissolved organic nitrogen in rainwater and aqueous aerosols . As a prominent urea source within the aerosols, emissions from the cattle have also been proposed .…”

Section: Introductionmentioning

confidence: 99%

Interactions of Urea Surfaces with Water as Relative Humidity Obtained from Dynamic Vapor Sorption Experiments, In Situ Single-Particle Raman Spectroscopy, and Ab Initio Calculations

Eisa,

Ragauskaitė,

Shi

et al. 2023

ACS Earth Space Chem.

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Urea is a critical nitrogen carrier molecule that is abundant in the environment due to its anthropogenic activity to enhance crop growth. The intrinsic link between its high solubility and volatilization, resulting in the reactive nitrogen species and CO2, especially under excessive relative humidity (RH) conditions, suggests that the urea hydrolysis-initiated decomposition reaction can be affecting the global nitrogen balance. Fundamental analysis of water as RH adsorption on urea particle surfaces was performed using a combination of dynamic vapor sorption (DVS) experiments, in situ single-particle Raman spectroscopy, and ab initio calculations. The DVS data acquired exhibited three RH adsorption regimes with urea with 74% RH dramatically changing adsorbate–urea interactions from monolayer- to multilayer-induced deliquescence. Several empirical kinetic models were utilized to understand the RH interaction with urea surfaces, and the Guggenheim–Anderson–de Boer model provided a good description of the adsorption at <60% RH values, while a Van Campen model was used to fit the data acquired during the urea crystal deliquescence. The experimental water sorption rate using the Van Campen model showed a gradual rise from 0.02 mg/min at 80% to 0.08 mg/min at 95% in agreement with Van Campen’s model of increasing trend, albeit at higher rates ranging from 0.03 mg/min at 80% to 0.1 mg/min at 95%. In situ Raman spectroscopy combined with optical images of a single particle showed that the urea 1009 cm–1 peak full width at half-maximum can provide in-depth information on the transient phenomena taking place on the urea particle surface as well as in the partially liquefied environment. Finally, density functional theory results suggested that Wulff’s reconstruction of a single urea crystal depended on the presence of higher crystalline planes; particularly, the (111) facet became significant together with (101) and (110), while in the presence of bulk H2O, (101) became the dominant facet. The results presented in this work will allow for a better understanding of urea–water vapor interactions in the environment at the molecular level including its potential for aerosol formation in the regions of high agricultural activity. Further, this study will allow us to better understand urea partitioning into soil pore volume where high RH is prevalent. Finally, it will provide a microscopic, single-particle understanding of the urea transformations in moist environments and pave the way for a new, nitrogen-efficient material fertilizer design.

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Section: Introductionmentioning

confidence: 99%

Interactions of Urea Surfaces with Water as Relative Humidity Obtained from Dynamic Vapor Sorption Experiments, In Situ Single-Particle Raman Spectroscopy, and Ab Initio Calculations

Eisa,

Ragauskaitė,

Shi

et al. 2023

ACS Earth Space Chem.

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Utilization of industrial by‐product gypsum to prepare urea gypsum cocrystals as a sustained release fertilizer: A review

Zhao,

Jia,

Fang

et al. 2024

Asia-Pacific J Chem Eng

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The large‐scale accumulation of industrial by‐product gypsum has led to land embezzlement and serious environmental pollution. Meanwhile, as a predominantly used nitrogen fertilizer, urea shows a disadvantage of high solubility in soil. Therefore, it can hydrolyze into large amounts of ammonium salts so rapidly that cannot be absorbed efficiently by crops. The sustainable method of using industrial by‐product gypsum to synthesize urea gypsum cocrystals is a promising way to solve above challenges. The synthesized urea gypsum shows low aqueous solubility and hygroscopicity, which can be used as sustained release fertilizer. In this review, the present status regarding urea gypsum is systematically reviewed, including its development history, preparation methods, impact of different raw materials, evaluation of products performance, and large‐scale trials. This review aims to reveal the current situation, identify current gaps, and provide suggestions for future investigations concerning urea gypsum.

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Understanding urea polymorphism and cocrystallization to develop enhanced fertilizers: A review

Nagaraju,

Jange,

Wassgren

et al. 2024

Journal of Environmental Chemical Engineering

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Effect of Urea-Calcium Sulfate Cocrystal Nitrogen Fertilizer on Sorghum Productivity and Soil N2O Emissions

Cited by 6 publications

References 51 publications

Interactions of Urea Surfaces with Water as Relative Humidity Obtained from Dynamic Vapor Sorption Experiments, In Situ Single-Particle Raman Spectroscopy, and Ab Initio Calculations

Interactions of Urea Surfaces with Water as Relative Humidity Obtained from Dynamic Vapor Sorption Experiments, In Situ Single-Particle Raman Spectroscopy, and Ab Initio Calculations

Utilization of industrial by‐product gypsum to prepare urea gypsum cocrystals as a sustained release fertilizer: A review

Understanding urea polymorphism and cocrystallization to develop enhanced fertilizers: A review

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