Spectroscopic and Microscopic Study of Peroxyformic Pulping of Agave Waste

Hernández-Hernández, H.M.; Chanona-Pérez, Jorge; Vega, Alberto; Ligero, Pablo; Farrera-Rebollo, Reynold R.; Mendoza-Pérez, Jorge A.; Calderón‐Domínguez, Georgina; Vera, Norma Güemes

doi:10.1017/s1431927616011818

Cited by 14 publications

(9 citation statements)

References 44 publications

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“…The bands in 1629-1612 cm −1 , 1319 cm −1 ,1313 cm −1 , 1141 cm −1 , 1231 cm −1 , 768 cm −1 , 669 cm −1 can be ascribed to the vibration by the presence of Lignin. Those peaks can be attributed to the vibration of C=C bonds present in lignin and C=O of carbonyl groups and the presence of N-H bonds and C = S.The identified adsorption bands in the spectra are similar to agave bagasse (Hernandez-Hernandez et al, 2016;Cruz-Olivares et al, 2010;Velazquez-Jimenez et al, 2013;Flores-Alamo et al, 2015;Romero-Cano et al, 2016). Fig.…”

Section: Microscopy and Spectroscopy Studies 341 Ftir Of Agave Atrovirens Epidermis Wastementioning

confidence: 56%

“…Also, in this case the disappearance of Mg is observed. The molecules responsible for the biosorption can be lignin, chlorophyll, cellulose, and hemicellulose, which have groups and metals that can participate in the biosorption process, mainly the carboxyl, hydroxyl and metals groups of the porphyrin ring of chlorophyll (Hernandez-Hernandez et al, 2016;Velazquez-Jimenez et al, 2013).…”

Section: Scanning Electron Microscopy (Sem) Analysismentioning

confidence: 99%

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Determination of Biosorption Mechanism in Biomass of Agave, Using Spectroscopic and Microscopic Techniques for the Purification of Contaminated Water

et al. 2019

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Section: Microscopy and Spectroscopy Studies 341 Ftir Of Agave Atrovirens Epidermis Wastementioning

confidence: 56%

Section: Scanning Electron Microscopy (Sem) Analysismentioning

confidence: 99%

Determination of Biosorption Mechanism in Biomass of Agave, Using Spectroscopic and Microscopic Techniques for the Purification of Contaminated Water

et al. 2019

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“…In this step, fibers are extracted by hydrolysis of the lignin and hemicellulose. Acid hydrolysis depolymerizes the lignocellulosic material, increasing the amorphous cellulose, which favors the release of sugars and improves their digestibility and fermentability [19,76,94]. Diluted acid is the most effective way to achieve high efficiency in hemicellulose depolymerization, but also to degrade the amorphous regions and to obtain cellulose nanocrystals [39].…”

Section: Chemical Pretreatmentsmentioning

confidence: 99%

Agave By-Products: An Overview of Their Nutraceutical Value, Current Applications, and Processing Methods

et al. 2021

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Agave, commonly known as “maguey” is an important part of the Mexican tradition and economy, and is mainly used for the production of alcoholic beverages, such as tequila. Industrial exploitation generates by-products, including leaves, bagasse, and fibers, that can be re-valorized. Agave is composed of cellulose, hemicellulose, lignin, fructans, and pectin, as well as simple carbohydrates. Regarding functional properties, fructans content makes agave a potential source of prebiotics with the capability to lower blood glucose and enhance lipid homeostasis when it is incorporated as a prebiotic ingredient in cookies and granola bars. Agave also has phytochemicals, such as saponins and flavonoids, conferring anti-inflammatory, antioxidant, antimicrobial, and anticancer properties, among other benefits. Agave fibers are used for polymer-based composite reinforcement and elaboration, due to their thermo-mechanical properties. Agave bagasse is considered a promising biofuel feedstock, attributed to its high-water efficiency and biomass productivity, as well as its high carbohydrate content. The optimization of physical and chemical pretreatments, enzymatic saccharification and fermentation are key for biofuel production. Emerging technologies, such as ultrasound, can provide an alternative to current pretreatment processes. In conclusion, agaves are a rich source of by-products with a wide range of potential industrial applications, therefore novel processing methods are being explored for a sustainable re-valorization of these residues.

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“…Coletta et al utilized this confocal microscopy to investigate the effect of alkali and acid pretreatments on the delignification of sugarcane bagasse [45]. Other non-bast natural fibers, such as agave plant fibers and wood tracheids, have also been investigated through fluorescence confocal microscopy [44,46,47]. The methods utilized by Hilda et al were replicated in this study and applied to bast fibers in order to characterize the lignin content in commercially available fibers and investigate its relationship to material properties and their variation [46].…”

Section: Introductionmentioning

confidence: 99%

Assessment of Mechanical Property Variation of As-Processed Bast Fibers

et al. 2019

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Hemp, flax, and kenaf are bast fibers with promising material characteristics to sustainably displace synthetic fibers used in composites; however, their use in composite applications is hindered by high material property variability. More widespread adoption and application, as well as improved quality methods, of fibers is contingent on the reduction of this variability. Efforts made herein to assess variability in as-processed fibers and methods were found to identify key sources of variability by investigating four areas: cross-sectional area approximation, physical defects, color and stem diameter, and fiber composition. Using fiber gage lengths closer to those found in composites, different geometric approximations of cross-sectional areas resulted in mean elliptical approximation showing the lowest variability across all fiber types. Next, by removing fibers exhibiting physical defects, maximum variation in tested flax fibers was reduced from 66% to 49% for ultimate tensile strength and 74% to 36% for elastic modulus. Additionally, fibers of darker color were found to have lower mechanical property variation than lighter or spotted fibers, and those coming from smaller stem diameters were found to be stronger than fibers from large stem diameters. Finally, contrary to previous findings with other lignocellulosics, clear trends between the lignin content in a fiber and its mechanical properties were not readily evident. Overall, these factors combined to significantly reduce mechanical property variation, while identifying the underlying contributing parameters.

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Spectroscopic and Microscopic Study of Peroxyformic Pulping of Agave Waste

Cited by 14 publications

References 44 publications

Determination of Biosorption Mechanism in Biomass of Agave, Using Spectroscopic and Microscopic Techniques for the Purification of Contaminated Water

Determination of Biosorption Mechanism in Biomass of Agave, Using Spectroscopic and Microscopic Techniques for the Purification of Contaminated Water

Agave By-Products: An Overview of Their Nutraceutical Value, Current Applications, and Processing Methods

Assessment of Mechanical Property Variation of As-Processed Bast Fibers

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