artículo académico

• Effect of drying method on the surface properties of cellulose nanofibril films.  SCIENTIFIC REPORTS.  16(1). 2026
• Interaction of Nanofibrillated cellulose with lignin nanoparticles: Effects on CNF-LNP composite properties.  CARBOHYDRATE POLYMER TECHNOLOGIES AND APPLICATIONS.  9. 2025
• The impact of humidity on fractionation of Eucalyptus globulus pinchips using alkaline DES of potassium carbonate and glycerol.  CELLULOSE.  1-10. 2025
• Effect of enzyme lignin oxidation by laccase on the enzymatic-mechanical production process of lignocellulose nanofibrils from mechanical pulp.  CELLULOSE.  31(6):3545-3560. 2024
• Relationships between Size Distribution, Morphological Characteristics, and Viscosity of Cellulose Nanofibril Dispersions.  POLYMERS.  14(18). 2022
• The role of lignin in the production process and characterization of lignocellulose nanofibril suspensions.  CELLULOSE.  29(16):8637-8650. 2022
• Effect of the chemical and structural characteristics of pulps of eucalyptus and Pinus of the deconstruction ofthe cell wall during the production of cellulose nanofibrils.  CELLULOSE.  28(9):5387-5399. 2021
• Eucalyptus globulus bark valorization: Production of fibers by Neutral Sulphite Semi-Chemical Process for Liner Paper Manufacture.  FLORESTA E AMBIENTE.  28(2). 2021
• Impact of the Enzyme Charge on the Production and Morphological Features of Cellulose Nanofibrils.  POLYMERS.  13(19). 2021
• Obtaining vegetable fibers from the bark of Eucalyptus globulus by neutral sulfite process and Organosolv.  CELULOSA Y PAPEL.  34(1):16-21. 2018