To reduce plastic pollution, it is of interest to develop biodegradable molded fiber products from recovered cellulose-containing residues as an alternative to single-use plastics. Primary questions to be addressed include how to compound molded fiber products from the recycling of paper or cardboard and agricultural residual wastes via combined vacuum thermo-forming and post-drying or synergistic cold and hot press approaches. In addition, consumers will have high expectations regarding barriers for moisture and grease. It is proposed here to produce uniform barrier molded fiber products via a Pickering emulsion approach with chemically recycled waxes from thermolysis of waste polyolefins. It is further proposed to develop a closed-loop process for recyclable molded products and up-cycling lignocellulosic fibers reinforced biomass-derivable vitrimer bio-composites for sustainable packaging. The development of molded fiber products makes it possible to mitigate the usage of single-use plastics.
Link to HumenChem
Download PDFBarrier Molded Fiber Products Based on Recovery and Up-cycling of Paper and Agricultural Wastes via a Pickering Emulsion Approach
Jinlong Zhang
To reduce plastic pollution, it is of interest to develop biodegradable molded fiber products from recovered cellulose-containing residues as an alternative to single-use plastics. Primary questions to be addressed include how to compound molded fiber products from the recycling of paper or cardboard and agricultural residual wastes via combined vacuum thermo-forming and post-drying or synergistic cold and hot press approaches. In addition, consumers will have high expectations regarding barriers for moisture and grease. It is proposed here to produce uniform barrier molded fiber products via a Pickering emulsion approach with chemically recycled waxes from thermolysis of waste polyolefins. It is further proposed to develop a closed-loop process for recyclable molded products and up-cycling lignocellulosic fibers reinforced biomass-derivable vitrimer bio-composites for sustainable packaging. The development of molded fiber products makes it possible to mitigate the usage of single-use plastics.
DOI: 10./biores.20.1.7-10
Keywords: Molded fiber products; Close-loop recycling; Polyolefin pyrolysis; Pickering emulsions
Contact information: School for Engineering of Matter, Transport and Energy, Arizona State University, Tempe, AZ , USA; : ,
Molded Fiber Products as an Alternative to Single-Use Plastics
Single-use plastics, primarily from petroleum-based polymeric materials, are the most used material for packaging containers, shopping bags or pouches, and table-wares. However, disposal of single-use plastics at the end of their service life causes serious environmental pollution. This has prompted tremendous effects toward developing alternative sustainable materials. Molded fiber products composed of natural fibers (e.g., wood pulps and bamboo fibers) are highly regarded in terms of biodegradability, recycling, light weight, and food compatibility. They are considered as promising alternatives to single-used plastic products. The primary compounding approaches involve thermoforming or combined cold and hot pressing. The typical protocols of molded fiber products are composed of two main processes, namely, pulp preparation and a molding process involving vacuum forming or cold pressing, and then a drying process.
Large amounts of paper waste and agricultural residues generated each year are not appropriately managed. With environmental concerns rising, there is more incitive to recycle agricultural residues, and paper and cardboard wastes. The content of cellulose or lignocellulosic fibers in these recovered materials are good sources for molding fiber products (Lo et al. ), e.g., disposals of single-used paper cups from Coca Cola in Atlanta and Starbuck in Seattle, shopping paper bags or pouches from Jet Paper Bags in New Jersey, and wood fiber wastes in primary States of Maine, North Carolina, and Oregon, and sugarcane bagasse residues in main States of Louisiana, Florida, and Hawaii. The resulting molded fiber products currently perform the roles of cutlery, cups, and packaging containers and promising as fiber bottles and caps as alternatives of expanded polystyrene containers, polyethylene terephthalate plastic bottles and polypropylene bottle caps.
Molded Fiber Products with Enhanced Barriers, Close-Loop Chemical Recycling, Up-cycling, and Biodegradability via Pickering Emulsions
Resistance to water and grease are crucial for many applications of molded fiber products. Due to the intrinsic hydrophilic character of lignocellulosic fibers, there is a need for eco-friendly barrier layers. Waxes as coating materials are common approaches to enhance barrier properties of packaging materials in industry. However, the large production and utilization of petroleum-based waxes inevitably causes toxic gases emissions, thereby enhancing barrier properties at the cost of sustainability. Alternatively, the development of natural waxes has attracted attention such as barrier coatings, e.g., soybean oil and beeswax. However, the plant- and animal- bio-waxes have intrinsic limitations in terms of types and sources for the barrier coating industry. Recently, the up-cycling of waste polyethylene (PE, e.g., high-density and low-density PE) and their mixtures of polypropylene to produce waxes and fatty acids in high yields and purities as chemically recycled waxes have been reported via a gradient-temperature thermolysis method (Xu et al. ). A follow-up method to chemically recycle waxes from PE and metallic PE was optimized in terms of yield and purity with table salts. However, enhancing barriers of molded fiber products with up-cycling waxes is challenging owing to their hydrophobic nature with low solubility in aqueous solution and poor compatibility with molded fiber product surface. Although waterborne polyurethane, polylactic acid (PLA), or polybutylene succinate (PBS) as coatings are an alternative approach, there are intrinsic restrictions. The use of an oil-in-water Pickering emulsion as a carrier of waxes is an interesting perspective to produce uniform hydrophobic coatings. By stabilizing the waxy droplets with a coating of nanocellulose (CNC), hemicellulose, or its derived xylan nanocrystal (XNC) (Meng et al. ; Hao et al. ), it is possible to produce uniform coatings and subsequently impart fiber surfaces with hydrophobicity. However, CNC, hemicellulose, or XNC stabilizers need to be tailored to optimize their amphiphilicity to produce Pickering emulsion with a long-term stability. The straightforward methods are grafting aldehyde groups on CNC or the hemicellulose and XNC backbone from periodate oxidation or its reducing end with diverse amine compounds with different structures and varied carbon lengths of alkyl groups via a Schiff base reaction, e.g., methylamine, ethylamine, isopropyl amine, and benzylamine (Solomons and Fryhle ). Alternative approaches are polyelectrolyte interactions such as coacervation or electrostatic interactions with negatively charged CNC, hemicellulose, or XNC and oppositely charged synthetic polyelectrolytes via controlled radical polymerization, e.g., reversible addition-fragmentation chain-transfer and atom transfer radical polymerization (Odian ). In addition to water and grease barriers, the rod- or platelet- like CNC, hemicellulose and XNC nanoparticles also contributes to gas barrier performance, e.g., oxygen and carbon dioxide barriers. To further enhance grease barriers, biodegradable poly(lactic acid) PLA or poly(butylene succinate) PBS, as synergistic agents for up-cycling of waxes dissolved in the oil phase, make it possible to enhance molded fiber products with both enhanced water and grease barrier performance in addition to gas barriers. Other fillers such as nano-clay and nanotube stabilizers can also be considered for Pickering emulsion coatings. The follow-up question is about the close-loop recycling and up-recycling of molded fiber products. Similarly to the chemical recycling of barrier papers, molded fiber products can be cut into small pieces and then resuspended as fibers with the use of sodium hydroxide at low concentrations. The re-pulped and remolded products are expected to maintain mechanical performance under ideal scenarios to achieve the ideal close-loop chemical recycling with multiple cycles. Alternatively, the re-pulped fibers make it possible to be compounded into fiber sheets, then infused with biodegradable PLA- or PBS- based vitrimer materials, and subsequently compounded via hot-press lamination for the preparation of high-performance lignocellulosic fibers reinforced biomass-derived vitrimer bio-composites. Such products can be applied in biodegradable cutlery, composite packaging, and shape memory and self-healing functional composites (Clarke et al. ). Thanks to the reversibly dynamic covalent structures of vitrimer materials, the composite materials also make it possible to achieve chemical recycling multiple times (Wu et al. ).
Another question is the biodegradable performance of molded fiber products and up-cycling lignocellulosic fibers reinforced composites, especially degradation in ocean environments. Soil burials and marine-water field trials are primarily methods for their biodegradable performance evaluation. The variation in terms of molecular weight and crystallization can be tracked to in-situ evaluate biodegradable performance, e.g., size exclusion chromatography and differential scanning calorimetry. Therefore, barrier molded fiber products have potential for diverse applications in packaging industries, and its market potential in USA for next 10 years is promising. The next step is committed to promote the barrier molded fiber products toward the real USA market from the lab-scale mode by start-up companies with the endorsements from USA venture capital fundings, e.g., seed fundings. Overall, the prospective and lucrative barrier molded fiber product market are promising in the next 10 years despite its current status in its infancy of product development.
References Cited
Clarke, R. W., Rognerud, E. G., Puente-Urbina, A., Barnes, D., Murdy, P., McGraw, M. L., Newkirk, J. M., Beach, R., Wrubel, J. A., Hamernik, L. J., Chism, K. A., Baer, A. L., Beckham, G. T., Murray, R. E., and Rorrer, N. A. (). “Manufacture and testing of biomass-derivable thermosets for wind blade recycling,” Science 385(), 854-860. DOI: 10./science.adp
Hao, X., Lv, Z. W., Wang, H. R., Rao, J., Liu, Q. L., Lu, B. Z., and Peng, F. (). “Top-down production of sustainable and scalable hemicellulose nanocrystals,” Biomacromolecules 23(11), -. DOI: 10./acs.biomac.2c
Lo, C. H., Wade, K. R., Parker, K. G., Mutukumira, A. N., and Sloane, M. (). “Sustainable paper-based packaging from hemp hurd fiber: A potential material for thermoformed molded fiber packaging,” BioResources 19(1), -. DOI: 10./biores.19.1.-
Meng, Z. J., Sawada, D., Laine, C., Ogawa, Y., Virtanen, T., Nishiyama, Y., Tammelin, T., and Kontturi, E. (). “Bottom-up construction of xylan nanocrystals in dimethyl sulfoxide,” Biomacromolecules 22(2), 898-906. DOI: 10./acs.biomac.0c
Odian, G. (). Principles of Polymerization, 4th Ed., New Jersey, United States.
Solomons, T. W. G., and Fryhle, C. B. (). Organic Chemistry, 10th Ed., Hoboken, NJ, United States.
Wu, X. Y., Hartmann, P., Berne, D., De Bruyn, M., Cuminet, F., Wang, Z. W., Zechner, J. M., Boese, A. D., Placet, V., Caillol, S., and Barta, K. (). “Closed-loop recyclability of a biomass-derived epoxy-amine thermoset by methanolysis,” Science 384(), article . DOI: 10./science.adj
Xu, Z., Munyaneza, N. E., Zhang, Q. K., Sun, M. Q., Posada, C., Venturo, P., Rorrer, N. A., Miscall, J., Sumpter, B. G., and Liu, G. L. (). “Chemical upcycling of polyethylene, polypropylene, and mixtures to high-value surfactants,” Science 381(), 666-671. DOI: 10./science.adh09
In the global shift towards sustainable living, the foodservice industry is embracing eco-friendly alternatives to traditional plastic tableware. Sugarcane bagasse, the fibrous residue left after extracting juice from sugarcane stalks, has emerged as a promising material for biodegradable and compostable tableware. However, a common question arises: How does this natural material resist water and oil without compromising its environmental benefits?
At InNature Pack, we have developed a multi-faceted approach that enhances the water and oil resistance of sugarcane bagasse tableware while maintaining its compostability. In this article, we’ll explore how we achieve water and oil resistance through advanced manufacturing, smart material engineering, and targeted surface treatments—while remaining true to our sustainable mission.
In real-world foodservice applications—hot soups, greasy dishes, oily snacks—tableware must withstand moisture and oil exposure without softening, leaking, or losing its shape. For traditional plastic products, this is easy—but at an environmental cost. For natural fiber-based alternatives like sugarcane bagasse, achieving similar performance requires a deeper understanding of fiber chemistry and processing.
Our R&D team has worked extensively to overcome this technical challenge without sacrificing compostability or safety. What follows is a breakdown of our three-pronged solution: structural engineering, material modification, and optional coatings.
The first line of defense against water and oil lies in how the product is formed.
For more information, please visit Barrier Coatings for Pulp Molded Tableware.
At InNature Pack, we use a high-pressure thermoforming process, applying temperatures between 180–200°C. This step is more than just shaping—it’s a transformative process that impacts the microstructure of the product.
Under these conditions, the cellulose fibers in the bagasse undergo hydrogen bonding, where hydroxyl groups on the fiber surfaces form intermolecular bridges. These natural bonds pull the fibers tightly together, reducing gaps and creating a low-porosity structure that acts as a physical barrier to water and oil.
This dense matrix is the foundation of our resistance performance. Unlike low-pressure molded pulp products (such as traditional egg cartons), our high-pressure bagasse items have a noticeably smoother surface, stronger edges, and enhanced barrier properties—all achieved without synthetic liners.
To further enhance durability and liquid resistance, we apply fiber optimization techniques during pulping.
Our formula involves blending short sugarcane fibers with long bamboo fibers. Here’s why:
This complementary fiber arrangement creates a mechanically robust and chemically stable substrate that delays liquid penetration—especially useful for holding hot or greasy foods for extended periods.
Scientific literature supports this approach. Fiber hybridization has been shown to improve both wet and dry strength, while reducing the overall water absorption rate of molded pulp products (ScienceDirect, ).
Beyond physical structure, we also modify the internal chemistry of the material by introducing food-grade hydrophobic agents during pulp preparation.
A key example is alkyl ketene dimer (AKD), a compound widely used in the paper industry. When added to the pulp slurry, AKD forms covalent bonds with the hydroxyl groups in cellulose. This reaction reduces the surface energy of the fibers, making them inherently water-repellent.
The advantages of internal sizing include:
All additives used by InNature Pack are BfR and FDA-compliant, ensuring complete food safety.
For applications that demand enhanced water and oil resistance—such as takeaway containers for hot, greasy foods or utensils requiring high stiffness—optional surface treatments are available. These solutions preserve the compostability of molded fiber products while offering additional performance.
Lamination involves adhering a thin layer of biodegradable film (often PLA or PBAT-based) onto the molded pulp surface. This method offers superior barrier properties compared to coatings and results in a smoother, glossier finish. Lamination is commonly used for premium or delivery-focused packaging that demands extended resistance to leakage or contamination.
This involves applying a biodegradable, water- and oil-resistant coating to the surface of the molded product after thermoforming. Commonly used coatings include water-based dispersions and biopolymer layers . Surface coating creates a protective film that helps reduce liquid absorption and improve resistance to grease—particularly valuable for foods with prolonged contact or higher oil content.
While coatings are effective, they can wear off more quickly under high-moisture or prolonged use conditions compared to laminated surfaces. We recommend using these coatings only when necessary to ensure the product remains lightweight, food safe and compostable.
Sustainability is at the core of our operations. All materials and additives used in our tableware are certified compostable, meeting international standards such as EN. Under industrial composting conditions, our products break down into carbon dioxide, water, and biomass within 90 days, leaving no toxic residues.
Furthermore, our manufacturing processes are designed to minimize environmental impact. We employ closed-loop water systems and energy-efficient machinery to reduce resource consumption. By utilizing agricultural by-products like bagasse and bamboo fibers, we contribute to waste reduction and promote the circular economy
Despite ongoing improvements, molded fiber tableware—like all materials—has its limitations under extreme use conditions:
That said, the industry continues to explore advanced solutions aimed at balancing functionality and sustainability:
These ongoing efforts across the fiber packaging sector are expected to broaden application scenarios, especially in foodservice, without compromising environmental benefits.
Sugarcane bagasse tableware represents a sustainable and practical solution for the foodservice industry. Through advanced manufacturing techniques, material modifications, and optional surface treatments, we have developed products that meet the demands of modern foodservice while aligning with environmental goals.
At InNature Pack, we are committed to continuous innovation and sustainability. Our approach ensures that you don’t have to compromise between performance and environmental responsibility.
Interested in learning more or requesting samples? Contact us today to explore how our sugarcane bagasse tableware can meet your needs.
A: Yes. Our tableware is designed to withstand hot liquids and oils up to 100°C without leaking or deforming, thanks to the combination of dense fiber structures and hydrophobic additives.
A: Absolutely. All additives are food-grade and comply with international safety standards. They do not affect the taste or safety of the food.
A: Our products are microwave-safe for reheating purposes and can be used in freezers without compromising structural integrity.
If you are looking for more details, kindly visit high temperature cured silicone resin.