Artículos AdFhttps://hdl.handle.net/10259/43302026-06-03T02:37:36Z2026-06-03T02:37:36ZThymol-Based Natural Deep Eutectic Solvents under Pressure: A Novel Platform for Green SolventsOzkilinc, OzgeBol Arreba, AlfredoSoler, Miguel AngelFogolari, FedericoAparicio Martínez, Santiagohttps://hdl.handle.net/10259/117632026-06-02T00:05:40Z2025-09-01T00:00:00ZThymol-Based Natural Deep Eutectic Solvents under Pressure: A Novel Platform for Green Solvents
Ozkilinc, Ozge; Bol Arreba, Alfredo; Soler, Miguel Angel; Fogolari, Federico; Aparicio Martínez, Santiago
Deep eutectic solvents (DESs) are emerging green alternatives to traditional solvents, yet their behavior under high pressure (HP) remains underexplored. This study examines two thymol-based eutectic mixtures─thymol:1,8-cineole (1:1) and thymol:camphor (1:1)─using a combined experimental and molecular dynamics approach. Pressure–volume–temperature (PVT) measurements were conducted across 0.1–60 MPa and 293.15–343.15 K. The two systems displayed expected density trends but exhibited markedly different internal pressure responses: a maximum for the camphor system and a shallow minimum for the cineole mixture. Molecular dynamics simulations revealed more frequent hydrogen bonding and greater structural organization in the camphor system, highlighting how molecular structure affects interactions. Changes in hydrogen bonding and internal pressure remained within 25% over the entire pressure range. These results provide molecular-level insight into pressure effects on DESs, guiding their future application in chemical processing and materials science under nonambient conditions
2025-09-01T00:00:00ZMolecular layering and CO₂ selectivity in graphene-supported natural deep eutectic solvent films: An in-silico investigationRozas Azcona, SaraAguilar Cuesta, NuriaMarcos Villa, Pedro A.Bol Arreba, AlfredoAparicio Martínez, Santiagohttps://hdl.handle.net/10259/117172026-05-27T00:05:17Z2026-01-01T00:00:00ZMolecular layering and CO₂ selectivity in graphene-supported natural deep eutectic solvent films: An in-silico investigation
Rozas Azcona, Sara; Aguilar Cuesta, Nuria; Marcos Villa, Pedro A.; Bol Arreba, Alfredo; Aparicio Martínez, Santiago
A multiscale computational study was conducted to investigate graphene-supported thin films composed of a
natural deep eutectic solvent (NADES) formed by menthol and decanoic acid (MENTH:DA), with a focus on
applications in sustainable CO₂ capture. Density functional theory (DFT) and molecular dynamics (MD) simulations were employed to elucidate interfacial structuring, molecular interactions, and gas adsorption behavior.
DFT results indicated a strong interaction between decanoic acid and the graphene surface (− 35.88 kJ/mol),
characterized by a parallel orientation that maximizes van der Waals interactions. In contrast, menthol displayed
weaker adsorption energies (− 5.15 kJ/mol) and a predominantly perpendicular orientation. MD simulations
revealed the formation of distinct adsorption layers, with decanoic acid enriched in the first layer and menthol in
the second, while the NADES hydrogen-bonding network remained largely intact. CO₂ exhibited preferential
adsorption over flue gas components (N₂, H₂O, O₂), with substantial accumulation in both the first and second
interfacial layers. Approximately 50% of the CO₂ content from flue gas mixtures was retained within the
structured region. Adsorption performance was found to be largely independent of temperature (303− 323K) and
NADES film thickness (20–50 Å). These results provide fundamental insight into NADES–graphene interactions
and highlight the potential of type V, naturally derived deep eutectic solvents as selective and environmentally
benign materials for CO₂ separation technologie
2026-01-01T00:00:00ZMolecular mechanisms of β-cyclodextrin solubilization in natural deep eutectic solvents: A quantum chemical investigationHuerta Sainz, Sergio de laEscobedo Monge, María AntonietaEscobedo-Monge, Marlene FabiolaBol Arreba, AlfredoMarcos Villa, Pedro A.Atilhan, MertAparicio Martínez, Santiagohttps://hdl.handle.net/10259/114392026-02-27T01:05:48Z2026-02-01T00:00:00ZMolecular mechanisms of β-cyclodextrin solubilization in natural deep eutectic solvents: A quantum chemical investigation
Huerta Sainz, Sergio de la; Escobedo Monge, María Antonieta; Escobedo-Monge, Marlene Fabiola; Bol Arreba, Alfredo; Marcos Villa, Pedro A.; Atilhan, Mert; Aparicio Martínez, Santiago
Cyclodextrins, particularly β-cyclodextrin (β-CD), exhibit remarkable host-guest complexation capabilities due to their unique toroidal structures. Natural deep eutectic solvents (NADES), biocompatible mixtures of readily available components, represent sustainable alternatives to conventional solvents with tunable physicochemical properties. This work investigates the molecular interplay between β-CD and NADES, focusing on their potential to create sustainable, multifunctional materials. Two configurations were explored: (i) β-CD dissolved in NADES and (ii) β-CD acting as a NADES component. Using density functional theory simulations, the study examined intermolecular forces, confinement effects, and molecular topology to characterize host–guest interactions between atomistic models of selected NADES (menthol + thymol and menthol + decanoic acid) and β-CD complexes. Energetic and kinetic analyses provided insights into the driving forces and timescales of complexation processes. The findings contribute to a mechanistic understanding of NADES–CD systems, enabling rational selection of solvent compositions and cyclodextrin forms for optimized guest encapsulation and targeted functionalities.
2026-02-01T00:00:00ZNature's tool kit: Designing biocompatible and affordable NADES for sustainable extraction of plant bioactivesHuerta Sainz, Sergio de laEscobedo Monge, María AntonietaMarcos Villa, Pedro A.Esteban-Ollo, José AntonioMontejo-Gil, LauraConde-Rioll, MaríaAtilhan, MertBol Arreba, AlfredoAparicio Martínez, Santiagohttps://hdl.handle.net/10259/114382026-02-27T01:05:47Z2025-03-01T00:00:00ZNature's tool kit: Designing biocompatible and affordable NADES for sustainable extraction of plant bioactives
Huerta Sainz, Sergio de la; Escobedo Monge, María Antonieta; Marcos Villa, Pedro A.; Esteban-Ollo, José Antonio; Montejo-Gil, Laura; Conde-Rioll, María; Atilhan, Mert; Bol Arreba, Alfredo; Aparicio Martínez, Santiago
Conventional extraction of valuable plant compounds often relies on hazardous volatile organic solvents (VOCs), posing environmental and health risks. This study explores a sustainable alternative using Natural Deep Eutectic Solvents (NADES) designed in-silico through the Conductor-like Screening Model for Realistic Solvents methodology (COSMO-RS) for efficient extraction of target plant metabolites. A library of NADES with varying compositions was designed using COSMO-RS to predict their physicochemical properties and affinity for target natural compounds, selecting the most promising candidates in terms of versatility, cost-effectiveness and biocompatibility. To complete the study, a predictive Artificial Intelligence based method (Decision Trees) was developed for reverse design of NADES for target bioactive compounds from energetic and structural molecular descriptors. From a compendium of 58 plant metabolites of interest and 66 natural compounds as NADES components, nearly 3000 solubility in silico tests were conducted and a total of 12 NADES were selected. Three solubility models were created, and a clear dependance of the target compound properties was observed.
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