Effective Extraction of a Heavy Oil Resource by an Environmentally Friendly Green Solvent: Limonene.

Mathews, Tanya Ann; Azzu, Paul; Cortes, Jairo; Hasçakir, Berna

doi:10.2118/210138-ms

Cited by 2 publications

(1 citation statement)

References 44 publications

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“…In this context, terpenes have emerged as promising candidates. They are widely spread in nature and are produced as by‐products of various industries [6–13].…”

Section: Introductionmentioning

confidence: 99%

Limonene: A scented and versatile tropospheric free radical deactivator

Francisco‐Márquez

Galano

2023

Int J of Quantum Chemistry

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The reactions of limonene with various free radicals (•OCH3, •OBr, •SH, •OOH, and •OOCH3) were investigated along the 273.15–312.15 K temperature range. To that purpose the density functional theory was used, at the M06‐2X/6–311+g(d,p) level. Two reaction mechanisms, hydrogen atom transfer (HAT) and radical adduct formation (RAF) were considered. It was found that the relative reactivity of the studied radicals toward limonene is: •SH > •OBr > •OCH3 > •OOH > •OOCH3. HAT was identified as the dominant mechanism for •OOH and •OOCH3, while RAF contributes the most to the reactions involving •OCH3, •OBr, and •SH. The obtained Arrhenius expressions are: k(•OCH3) = 1.58 × 10−13 e−1.59/RT, k(•OBr) = 3.55 × 10−12 e+1.82/RT, k(•SH) = 3.30 × 10−11 e+0.79/RT, k(•OOH) = 1.33 × 10−15 e−5.99/RT, and k(•OOCH3) = 5.88 × 10−17 e−6.26/RT. According to them, the reactions of •OBr and •SH become slower as temperature rises from 273.15 to 312.15 K, while for the other radicals the reactions rate increases with temperature. The subsequent tropospheric fate of the most abundant •OBr adduct was also investigated in the same temperature range, considering O2 addition to this radical (step 2) and the reaction of the peroxyl radical yielded in this step 2 with NO. The latter is predicted to take place in two steps: the NO addition (3a) and the NO2 elimination (3b). The corresponding Arrhenius expression are k2 = 3.56 × 10−15 e+1.43/RT and k3b = 1.35 × 1014 e−31.65/RT. Step 3a was found to be barrierless. To our best knowledge, all the data provided here is reported for the first time. Thus, it would hopefully contribute to enhance the knowledge necessary for the full understanding (and accurate modeling) of the troposphere.

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“…In this context, terpenes have emerged as promising candidates. They are widely spread in nature and are produced as by‐products of various industries [6–13].…”

Section: Introductionmentioning

confidence: 99%

Limonene: A scented and versatile tropospheric free radical deactivator

Francisco‐Márquez

Galano

2023

Int J of Quantum Chemistry

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Unlocking Sustainable Solutions: Exploring Terpene-Based Green Solvents for Enhanced Heavy Oil Recovery

Mathews,

Azzu,

Hascakir

2024

Energy Fuels

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The increasing global demand for heavy oil and bitumen underscores the need for innovative extraction techniques that address the challenges of high viscosity and low mobility. Traditional steam injection methods have been effective, but they are criticized for excessive water usage and significant carbon dioxide emissions. In response, this study investigates the use of terpenes�specifically limonene, citronella, turpentine, and beta-pinene�as sustainable and environmentally friendly solvents, comparing their performance with that of toluene, a commonly used but toxic solvent. This research involved 11 core flooding experiments using three different heavy oil samples (O1, O2, and O3) to assess the solvency and recovery efficiency of terpenes. Each experiment aimed to evaluate how terpenes influence oil recovery under varying conditions of steam and carbon dioxide injection and varying oil viscosities. Produced oil and water samples were collected at 20 min intervals and analyzed for emulsion stability and oil quality using TGA/DSC, while displacement efficiency was assessed through spent rock analysis. Results demonstrated that limonene, beta-pinene, and turpentine achieved oil recovery efficiencies comparable to toluene, approximately 75%, confirming their effectiveness as organic solvents. All terpenes acted as demulsifiers, enhancing the quality of the oil during production. Additionally, the study found that while steam-solvent injection negatively impacted oil recovery, carbon dioxide proved to be an effective secondary agent for enhancing oil production in lowerviscosity oils without compromising oil quality. The study concludes that terpenes hold promise as safe, effective, and sustainable solvents for heavy oil recovery. Their nontoxic nature, ease of handling, and effective performance position them as viable alternatives to conventional, harmful solvents like toluene. Furthermore, the use of carbon dioxide as a secondary injection medium offers a method to improve efficiency and reduce environmental impact, reinforcing the potential of terpene-based solvents in environmentally conscious heavy oil recovery practices. This research contributes valuable insights into the adoption of green solvents for advancing sustainable extraction methods.

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Effective Extraction of a Heavy Oil Resource by an Environmentally Friendly Green Solvent: Limonene.

Cited by 2 publications

References 44 publications

Limonene: A scented and versatile tropospheric free radical deactivator

Limonene: A scented and versatile tropospheric free radical deactivator

Unlocking Sustainable Solutions: Exploring Terpene-Based Green Solvents for Enhanced Heavy Oil Recovery

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