Abstract
In this study, cellulose microfibers and cellulose nanofibers (CNF) prepared from recycled boxboard pulp using a mechanical fine friction grinder were used as reinforcements in a board sheet. Micro- and nanofibers manufactured by mechanical grinding have typically broad particle size distribution, and they can contain both micro- and nano-sized fibrils. Deep eutectic solvent of choline chloride and urea was used as a non-hydrolytic pretreatment medium for the CNF, and reference CNF were used without any chemical pretreatment. The CNF were ground using three grinding levels (grinding time) and their dosage in the board varied from 2 to 6 wt%. The results indicate that the board properties could be tailored to obtain a balance between the processability and quality of the products by adjusting the amount of CNF that was added (2–6 wt%). A preliminary cost assessment indicated that the most economical way to enhance the board strength properties was to add around 4% of CNF with a moderate grinding level (i.e., grinding energy of 3–4 kWh/kg). Overall, the strength properties of the manufactured board sheets improved by several dozen percentages when CNF was used as the reinforcement.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
The production of nano-scale cellulose fibers (nanocelluloses) and their application as reinforcements in materials have gained increasing attention due to the high strength and stiffness of the nanocelluloses combined with their small size, high surface area and aspect ratio, low weight, biodegradability, and renewability (Siró and Plackett 2010; Hassan et al. 2011; Suopajärvi et al. 2017). Cellulose nanofibrils or nanofibers (CNF) produced by mechanical disintegration of cellulose without any chemical treatments are one of the simplest types of nanomaterials based on renewable resources. CNF manufactured by mechanical treatments alone are polydisperse with a broad particle size distribution, and they can contain both micro- and nano-sized fibrils (Kangas et al. 2014). CNF have both amorphous and crystalline components, and they form of a web-like structure (Lavoine et al. 2012).
The mechanical fibrillation process causes permanent changes in the cellulose fiber structure, and it increases the bonding ability of cellulose by modifying the morphology and reducing the size of the fibers (Kamel 2007; da Costa Correia et al. 2016). Thus, some previous studies have shown that CNF can notably improve the mechanical properties of paper or board. It has been found that tensile strength and elastic modulus can be improved significantly (Eriksen et al. 2008; Hii et al. 2012; Sehaqui et al. 2013; González et al. 2013; Missoum et al. 2013; Djafari Petroudy et al. 2014; Hietala et al. 2016). High tensile strength and tensile stiffness contribute to the stacking strength of corrugated paperboard by reducing the risk of box wall bulging; thus, they are desired properties of board applications.
The global increase in packaging board and fiber products consumption has yielded a large amount of potential secondary cellulose raw materials that contribute to 25–40% of municipal solid waste (Nourbakhsh and Ashori 2010). Recycling these fiber sources and their use as raw materials for new sustainable products can preserve forest resources and minimize other environmental impacts. Moreover, fibers from recycled paper and packaging are relatively affordable and widely available. Therefore, they offer an appealing source for the production of packaging materials and novel green materials, such as CNF. The use of bio-based and recycled fiber sources to create sustainable packaging materials to replace plastics derived from fossil oil resources promotes the emerging trend of mitigating the carbon footprint of materials.
The successful liberation of nanofibrils require typically rigorous mechanical treatments due to the strong hydrogen-bonded structure of cellulosic materials. Thus, numerous different chemical pretreatments have been used to loosen the rigid structure of cellulose. Deep eutectic solvents (DESs) belong to the most promising group of novel green chemicals to enable efficient CNF production (Selkälä et al. 2016; Li et al. 2017, 2018; Sirviö 2018; Ojala et al. 2018). DESs can be derived from biodegradable and readily available green compounds that have a low toxicity (Sirviö et al. 2015). DESs are typically synthesized by complexation of the hydrogen bond acceptor (HBA), such as a halide salt of quaternary ammonium or a phosphonium cation along with a hydrogen bond donor (HBD) (e.g., urea, glycerol, or ethylene glycol), to form a mixture that exhibits a notably lower melting point than either HBA or HBD. In the present work, a DES system based on choline chloride and urea (Singh et al. 2012) was used as a pretreatment to liberate CNF from recycled boxboard using mechanical grinding. The CNF obtained from a secondary cellulose source were further used as reinforcements in board sheets. CNF produced directly from recycled board without any chemical treatments were used as the reference additives. Nanopapers were produced from the CNF to evaluate their strength properties. Moreover, the work evaluated the optimal grinding level in CNF production to maximize the energy consumption and costs of manufacturing CNF for use as board reinforcements.
Materials and methods
Raw material and chemicals
Chemicals used
Urea (97%) and choline chloride (> 98%) for DES were purchased from Borealis (Austria) and Algry Quimica (Spain), respectively. All chemicals were used as delivered, without any further purification. In the dilutions and CNF production, deionized water was used throughout the experiments.
Raw material
Recycled boxboard was obtained directly from board-container collections, and it was used as the raw material for the board sheets and the production of the CNF. The boxboard was first pulped without any additional chemicals using a Kenwood Chef Titanium XL pulper (UK) with a nominal rotor power of 1700 W, which has an operating principle similar to that of the Hobart pulper, at a consistency of 15% using a temperature of 45 °C. Pulper using a planetary type mixing during pulping procedure. The mixer and pulping bowl were manufactured in stainless steel. Pulping time was adjusted to 10 min and rotor speed 2 (i.e., ~ 250 rpm). After pulping, the recycled boxboard pulp was washed and screened using a Somerville screen (Lorentzen and Wettre, Sweden).
The conductometric titration procedure described by Rattaz et al. (2011) and Katz et al. (1984) was used to determine the charge density of the pulp. The hemicellulose content was determined with the TAPPI-T 212 om-02 standard and alkali solubility at 25 °C was determined with the TAPPI-T 235 cm-00 standard. The lignin content was determined using TAPPI-T 222 om-02 standard. Moreover, the extractive content was analyzed using SCAN-CM 49:03 standard and ash content was determined using the ISO1762 standard. The chemical properties of the board raw material are shown in Table 1. The average (length-weighted) length and width of the board fibers after washing were determined with a Valmet FS5 Fiber analyzer ultra-high definition (UHD) camera unit (Finland). Three replicates of each sample were measured, and the results were averaged and shown in Table 2.
Production of CNF from the recycled boxboard
DES of choline chloride and urea was used as a pretreatment to produce CNF from the boxboard pulp. The DES solution was produced by heating 1620 g of choline chloride and 1223 g of urea in a large beaker (5 dm3) at 100 °C until the mixture melted, after which it was placed into a water bath at 100 °C under constant stirring for approximately 5 min to obtain a clear and colorless liquid. Then, 25 g (abs) of recycled board material (dry matter content of ~ 30%) was added to the suspension and mixed for 2 h. Then, the beaker was removed from the water bath and 1000 cm3 of deionized water was added while mixing (Sirviö et al. 2015). Next, four identical DES-treated batches of boxboard pulp were combined. Then, the treated board was washed with water using a Somerville screen (Lorentzen and Wettre) until clear rinse water was obtained.
After completing the washing procedure, the DES-treated pulp was disintegrated with a Masuko supermasscolloider grinder (MKCA6-2J, Japan) using three different grinding times (grinding energy) to obtain three different CNF samples: T1, T2, and T3 (Table 3). The stones of the grinder were first carefully brought into close contact, as determined by the low friction sound, and then the pretreated pulp slurry was poured into the grinder at a consistency of 1.5%. First, the pulp was passed through the grinder three times using a zero-grinding stone gap (sample: T0); after which the stones were adjusted to negative gap values in order to start the actual fibrillation. The energy consumption of the fibrillation procedure was recorded with an energy meter (iEM3250 Schneider-Electric, France) attached to the fine friction grinder. The board pulp passed through the grinder a total of 14 times, using negative gap values of 3 times − 20 µm, 1 time − 40 µm, 1 time − 50 µm, 1 time − 60 µm, 3 times − 80 µm, and 5 times − 90 µm to obtain different board CNF (Table 3). The reference CNF samples were obtained from untreated boxboard pulp using a similar procedure. The reference samples are named: U0, U1, U2 and U3.
Manufacture and characterization of the investigated materials
Visualization of CNF and the board samples
After being subjected to different grinding energies, the board pulps were visualized using a Valmet FS5 Fiber analyzer UHD camera unit. Field emission scanning electron microscope (FESEM) (Zeiss Ultra Plus, Germany) was used for the samples obtained after a longer grinding time because of their much smaller average particle size and the need for a higher magnification. As a pretreatment, the FESEM samples were filtered using a polycarbonate membrane with a pore size of 0.2 μm (Whatman). Then, the filtration samples were rapidly frozen with liquid nitrogen and freeze-dried in a vacuum overnight. The dried samples were sputter-coated with platinum. An accelerating voltage of 5 kV and a working distance of around 5 mm was used when imaging the samples.
The surface structure of different handsheets was visualized directly from the surface of the prepared handsheets, which were sputtered with platinum before observation under the FESEM with 5 kV voltage.
Testing the strength properties of the nanopapers produced from board treated with CNF
Nanopapers were produced by filtration of 0.3 g (abs) of the fibrillated board samples on a polyvinylidene fluoride membrane (Durapore) with a pore size of 0.65 µm and a diameter of 70 mm. After filtration, the wet sheets were covered with a similar membrane and then dried with a Rapid–Köthen sheet dryer (Karl Schröder KG, Germany) under a vacuum of 0.1 bar at a temperature of 93 °C for 10 min (ISO 5269-2:2004). The samples were stored at ISO 187 standard conditions of 23 °C and 50% relative humidity. After preconditioning for at least 48 h in the standard environment, five thicknesses of the sample in different locations were measured using a precision thickness gauge (Hanatek FT3, UK), and the results were averaged. Six strips with a width of 5 mm were used for the actual strength measurements. The tensile tests were performed with a Zwick D0724587 (Switzerland) universal material testing machine using a 100 N load cell (Table 3). During the tensile tests, six replicates of each sample were tested using the standard conditions of 23 °C temperature and 50% relative humidity. The gauge length was adjusted to 40 mm at a strain rate of 4 mm/min.
Manufacturing and testing of the board handsheets
Laboratory handsheets were prepared from recycled boxboard pulp using various dosages (0%, 2%, 4%, or 6%) of CNF as a reinforcement. CNF were added directly to the pulp board slurry without any other chemical additives. Board sheets with 160 g/m2 grammage were prepared in a laboratory sheet-forming machine (Lorentzen and Wettre) according to the ISO 5269-1 standard method.
The board handsheets were conditioned before testing at 23 °C in 50% relative humidity according to the ISO 187 standard. Eight handsheets which means in practice at least eight replicates of each sample were tested using the standard conditions. The grammage and thickness of the handsheets were measured according to ISO 536 and ISO 534 standards. The tensile strength of the board handsheets was measured with a Zwick D0724587 universal material testing machine according to the ISO 1924-2 standard using 15 mm × 141 mm test strips. The internal bond strength of the paperboard (z-direction tensile strength) was measured with a Zwick D0724587 machine according to the TAPPI T541, 09/2005 standard. The tearing strength was measured with the Lorentzen and Wettre Tearing Tester according to TAPPI T414 om-12.
Results and discussion
Characteristics of the board fibers and CNF
The visual appearance of the DES-treated board fibers and CNF obtained from grinding (Fig. S1) were studied with Valmet FS5 Fiber analyzer UHD camera unit (samples T0, T1, T2, and T3). Furthermore, example images (Fig. S2) of the DES-treated CNF (T2 and T3) were obtained with FESEM. Length weighted fiber length and width of each sample are presented in Table 2. The optical resolution of FS5 UHD camera unit is close to 1 µm, which means that the smallest particles are not visible in practice and thus not included in the calculations. Length of the fibers decreased from around 0.8 mm (T0/U0) to 40 µm (T3/U3), when grinding time increased and finally led to a suspension containing mainly CNF (i.e., U3 and T3). Also fiber width decreased from around 19 µm (T0/U0) to around 2 µm (T3/U3). The proportion of fines (i.e., particles which length and width are smaller than 200 µm) were mainly in the two smallest size categories (i.e., 0–40 µm and 40–80 µm) with U3 and T3 samples while in primary board pulp (T0/U0) there is only around 5% fines. Based on the fiber analysis, the fiber properties of the DES-pretreated samples and the samples without chemical treatment (reference samples) were similar.
The surface structure of the board handsheets (160 g/m2) was visualized directly from the surface of the prepared sheets with the absence (Fig. 1a) and the presence of additional reinforcement CNF (T1, T2 and T3, Fig. 1b–d). CNF were observed on the surface of the handsheets, and smaller fibrils were visible on the surface of the sheets when the fibrillation level increased (i.e., T3 vs. T1/T2).
Energy consumption of the CNF production and the strength properties of the nanopapers
Table 3 presents the grinding energy demand for the production of the CNF reinforcements. The grinding time varied from 0 to 114 min, while the corresponding energy consumption was 0–8.8 kWh/kg of product. The consumed energy used in this research was well in line what have been noticed earlier in many publications related to mechanical fine friction grinding (Eriksen et al. 2008; Klemm et al. 2011; Laitinen et al. 2017; Ämmälä et al. 2019). The reinforcement potential of CNF was evaluated from the nanopapers fabricated directly from CNF without board fibers (Table 3). Overall, the strength properties of the CNF obtained from the DES-treated samples were better in comparison to the CNF produced using mechanical grinding without chemical pretreatment, and the strength increased as a function of grinding time. For example, the tensile strength of the nanopapers from the DES-treated CNF increased from 14.0 to 181.75 MPa (T0 and T3), while the maximum tensile strength of the reference CNF was 154.17 MPa (U3). These values are comparable to many of the recently published strength values of lignocellulosic nanopapers and films (Spence et al. 2010; Rojo et al. 2015; Visanko et al. 2017; Hietala et al. 2018).
Mechanical properties of the board handsheets
The CNF produced from recycled boxboard were used as a reinforcement in the board handsheets. During the preparation of the handsheets, the drainage time was observed to increase almost linearly (Fig. 2) as a function of the reinforced CNF dosage, which varied from 2 to 6 wt%. Moreover, the increase in the grinding time of the fibers decreased the water removal, i.e., it increased the drainage time (U1 → U2 → U3). A similar trend was observed for the DES-treated and reference CNF. However, the total retention of the board handsheets were very high (from approx. 97.5–99.5%), which was in practice 97.5% with the highest dosage of reinforcement CNF (6 wt%) and with CNF of the smallest size (U3 and T3). This indicates that the retention of the reinforcement CNF was also high without the use of any retention chemicals (around 70%).
The reinforcement of the mechanical properties of the board sheets by the addition of CNF is most likely connected to the enhanced bonding between the board fibers promoted by the CNF (da Costa Correia et al. 2016). Therefore, CNF can increase the density and stiffness of a sheet, and decrease the sheet bulk. In the present study, the highest density (Fig. 3) and lowest bulk (Fig. S3) were observed, as expected, in the board sheets with the highest amount (6 wt%) of the most fibrillated reinforcement CNF (U3). For example, the sheet density increased from 577 to 684 kg/m3, while bulk decreased from 1.73 to 1.46 cm3/g with U3. Density trends and therefore in turns bulk trends seems to be similar in both for the DES-treated and reference CNF.
The tear index and strain of the board handsheets are presented as a function of the CNF reinforcement (Fig. 4.) Both the tear index and strain increased with larger CNF dosages, except for the sheet containing U1. However, the effect of CNF on the tear strength was either relatively small or it plateaued at low dosages. Furthermore, the improvement in strain induced by CNF was very small (< 1% unit). Generally, the DES-treated CNF sample resulted in better values than the reference CNF.
To evaluate the costs attributed to using CNF as reinforcements in the board handsheet, some preliminary calculations were conducted. The estimated price of the electricity was 0.13 €/kWh; the price of recycled boxboard was 0.08 €/kg. Technical grade of urea costs around 200 €/t and choline chloride around 350 €/t (Laitinen et al. 2017). We used in these calculations recycling rate of 10 times and efficiency of chemical recycling 97% and the used consistency of pulp solution during DES-treatment was 5%. Based on calculations chemical pretreatment with used DES-system increased the raw material cost from 0.08 to 0.107 €/kg, which is around 34%. We noticed also that both the grinding level of CNF and their loading in the board sheet have a significant impact on the final price of the board. For example, increasing the T3 dosage from 2 to 6 wt% increased the final product price of the board by approximately 160–212%. Overall, the costs associated with using DES-treated CNF were around 30% higher when compared to reference CNF (Figs. S4–S6) recycled board. Because the energy consumption, chemical costs and costs associated with CNF use increased notably when the CNF grinding level increased, the most important mechanical properties of the board were compared to the energy consumption and relative manufacturing price of the strengthened recycled board to analyze the optimal use of CNF as a reinforcement.
The tensile strength of the handsheets increased almost linearly as a function of the CNF dosage (Fig. 5). CNF treated with DES enhanced the tensile strength to a greater extent than the addition of reference CNF (Fig. 5), and the highest strength value was obtained with T3. The best tensile strength index was 61% higher (i.e., T3 [6%]) than that of the reference board handsheet (34.0 kNm/kg). Moreover, it was observed that pulp from the DES-pretreatment had better strength properties in comparison to the untreated pulp. However, by considering the total chemical costs associated with the pulp slurry pretreatment, a more economical way to enhance the strength properties would be to add untreated mechanical grinded CNF as the reinforcement. Of the CNF used, the samples obtained from moderate grinding (U2) resulted in the most cost-efficient board sheets (Fig. S4). The obvious reason for this phenomenon is that the energy consumption of grinding increased significantly at the end of the grinding process (i.e., U2 → U3), while the improvement in strength properties was not as pronounced.
The trend for the tensile stiffness index of the board sheets was similar to the trend for the tensile strength index (Fig. 6). A nearly linear increase in the tensile stiffness index was observed, and a maximum increase of 27% was noted with the CNF treated with DES and the highest grinding level (T3). Furthermore, the most economical way to increase the tensile stiffness was to add the CNF with a moderate grinding level (i.e., U2, Fig. S5). For example, the 6 wt% dosage of T2 resulted in a tensile stiffness index of approximately 5.5 MNm/kg with a relative cost of 160%, while cost related to the use of the 6 wt% of U3 was approximately 190% with the stiffness index of approximately 5.3 MNm/kg.
In the best case, the tensile stress (z-direction tensile strength) was 85% higher (i.e., T3 [6%]) than that of the reference board handsheet (i.e., without grinding) (Fig. 7). However, the differences between the DES-treated CNF and the reference CNF were small. Similar to the tensile strength and stiffness values, the most cost-efficient use of reinforcement was to add the CNF with the moderate grinding levels (i.e., U2) to enhance the z-direction tensile strength (Fig. S6).
Overall, the results clearly demonstrate that the best way to improve the mechanical properties of the board sheet was to add approximately 4 wt% of untreated mechanical grinded CNF from the moderate grinding levels (those that used grinding energy 3–4 kWh/kg) as a reinforcement material. Doing so only increased the relative price of the manufactured board by 15–20%, but the tensile strength index improved 25–40%, the tensile stiffness index was 10–20%, and the z-direction tensile strength was 40–60% (Fig. S4–S6). Obviously, the board strength properties can still be improved by adding CNF with a higher grinding level (> 4 kWh/kg) or by increasing the amount of reinforced CNF (> 4 wt%), but this is not meaningful from an economic point of view. Furthermore, higher dosages of CNF from higher grinding levels would increase the drainage time and cause problems in the actual board manufacturing process. Moreover, it must be highlighted that the total chemical costs needed for the DES-pretreatment and the recycling of chemicals (i.e., urea and choline chloride) increased relative much (around 30%) of the final product price when DES-treatment is used in the CNF preparation. In summary, the results suggest that the grammage of prepared board could be decreased by adding CNF as the reinforcement material, and the treated product would still achieve similar strength properties as the original board without any reinforced fibers.
In the Table 4 have been compared improved strength properties of different paper products published in recent years. As can be noticed different nanocellulose reinforced fibers have typically a positive impact on the strength properties of various paper products, but some of research’s were used very expensive chemicals and very energy intensive grinding method like high pressure homogenization instead of mechanical grinding. Additionally, most of studies focused on paper strengthening and only a few scientific studies have focused on the effects of CNF on paperboard properties.
Conclusions
This study’s findings showed that, by selecting suitable grinding levels and dosages of CNF, it is possible to notably enhance the strength of the board sheet. Moreover, a balance between the board processing parameters (retention, drainage time) and the board mechanical properties can be achieved by tailoring the amount of CNF that is added. The strength properties of the manufactured board sheets improved several dozen percentages when CNF obtained from recycled boxboard was used as a reinforcement. It was also observed that the strength properties of the pulp from the DES-pretreatment were better than those of the untreated pulp. However when taking account chemical pretreatment with used DES-system the raw material cost increased around 34% and therefore the most economical way to improve the tensile strength properties of boards is to add untreated mechanical grinded CNF with around a 4% moderate grinding level (using a grinding energy level around 3–4 kWh/kg) directly to the board pulp slurry as the reinforcement material.
References
Ämmälä A, Laitinen O, Sirviö JA, Liimatainen H (2019) Key role of mild sulfonation of pine sawdust in the production of lignin containing microfibrillated cellulose by ultrafine wet grinding. Ind Crops Prod 140:111664. https://doi.org/10.1016/j.indcrop.2019.111664
Bossu J, Eckhart R, Czibula C et al (2019) Fine cellulosic materials produced from chemical pulp: the combined effect of morphology and rate of addition on paper properties. Nanomaterials 9:321. https://doi.org/10.3390/nano9030321
Brodin FW, Eriksen Ø (2015) Preparation of individualised lignocellulose microfibrils based on thermomechanical pulp and their effect on paper properties. Nord Pulp Pap Res J 30:443–451. https://doi.org/10.3183/npprj-2015-30-03-p443-451
da Costa Correia V, dos Santos V, Sain M et al (2016) Grinding process for the production of nanofibrillated cellulose based on unbleached and bleached bamboo organosolv pulp. Cellulose 23:2971–2987. https://doi.org/10.1007/s10570-016-0996-9
Delgado-Aguilar M, González I, Pèlach MA et al (2015a) Improvement of deinked old newspaper/old magazine pulp suspensions by means of nanofibrillated cellulose addition. Cellulose 22:789–802. https://doi.org/10.1007/s10570-014-0473-2
Delgado-Aguilar M, González Tovar I, Tarrés Q et al (2015b) Approaching a low-cost production of cellulose nanofibers for papermaking applications. BioResources. https://doi.org/10.15376/biores.10.3.5345-5355
Djafari Petroudy SR, Syverud K, Chinga-Carrasco G et al (2014) Effects of bagasse microfibrillated cellulose and cationic polyacrylamide on key properties of bagasse paper. Carbohydr Polym 99:311–318. https://doi.org/10.1016/j.carbpol.2013.07.073
Eriksen Ø, Syverud K, Gregersen Ø (2008) The use of microfibrillated cellulose produced from kraft pulp as strength enhancer in TMP paper. Nord Pulp Pap Res J 23:299–304
González I, Vilaseca F, Alcalá M et al (2013) Effect of the combination of biobeating and NFC on the physico-mechanical properties of paper. Cellulose 20:1425–1435. https://doi.org/10.1007/s10570-013-9927-1
Hassan EA, Hassan ML, Oksman K (2011) Improving bagasse pulp paper sheet properties with microfibrillated cellulose isolated from xylanase-treated bagasse. Wood Fiber Sci 43:76–82
Hassan ML, Bras J, Mauret E et al (2015) Palm rachis microfibrillated cellulose and oxidized-microfibrillated cellulose for improving paper sheets properties of unbeaten softwood and bagasse pulps. Ind Crops Prod 64:9–15. https://doi.org/10.1016/j.indcrop.2014.11.004
Hellström P, Hejnesson-Hulten A, Paulson M et al (2014) Fenton pre-treated microfibrillated cellulose evaluated as a strength enhancer in the middle ply of paperboard. Nord Pulp Pap Res J 29:732–740
Hietala M, Ämmälä A, Silvennoinen J, Liimatainen H (2016) Fluting medium strengthened by periodate–chlorite oxidized nanofibrillated celluloses. Cellulose 23:427–437. https://doi.org/10.1007/s10570-015-0801-1
Hietala M, Varrio K, Berglund L et al (2018) Potential of municipal solid waste paper as raw material for production of cellulose nanofibres. Waste Manag 80:319–326. https://doi.org/10.1016/j.wasman.2018.09.033
Hii C, Gregersen ØW, Chinga-Carrasco G, Eriksen Ø (2012) The effect of MFC on the pressability and paper properties of TMP and GCC based sheets. Nord Pulp Pap Res J 27:388
Kamel S (2007) Nanotechnology and its applications in lignocellulosic composites, a mini review. Express Polym Lett 1:546–575. https://doi.org/10.3144/expresspolymlett.2007.78
Kangas H, Lahtinen P, Sneck A et al (2014) Characterization of fibrillated celluloses. A short review and evaluation of characteristics with a combination of methods. Nord Pulp Pap Res J 29:129–143
Katz S, Beatson RP, Scallan AM (1984) The determination of strong and weak acidic groups in sulfite pulps. Sven Papperstidning 87:R48–R53
Klemm D, Kramer F, Moritz S et al (2011) Nanocelluloses: a new family of nature-based materials. Angew Chem Int Ed 50:5438–5466. https://doi.org/10.1002/anie.201001273
Laitinen O, Suopajärvi T, Österberg M, Liimatainen H (2017) Hydrophobic, superabsorbing aerogels from choline chloride-based deep eutectic solvent pretreated and silylated cellulose nanofibrils for selective oil removal. ACS Appl Mater Interfaces 9:25029–25037. https://doi.org/10.1021/acsami.7b06304
Lavoine N, Desloges I, Dufresne A, Bras J (2012) Microfibrillated cellulose—its barrier properties and applications in cellulosic materials: a review. Carbohydr Polym 90:735–764. https://doi.org/10.1016/j.carbpol.2012.05.026
Li P, Sirviö JA, Haapala A, Liimatainen H (2017) Cellulose nanofibrils from nonderivatizing urea-based deep eutectic solvent pretreatments. ACS Appl Mater Interfaces 9:2846–2855. https://doi.org/10.1021/acsami.6b13625
Li P, Sirviö JA, Asante B, Liimatainen H (2018) Recyclable deep eutectic solvent for the production of cationic nanocelluloses. Carbohydr Polym 199:219–227. https://doi.org/10.1016/j.carbpol.2018.07.024
Mashkour M, Afra E, Resalati H, Mashkour M (2015) Moderate surface acetylation of nanofibrillated cellulose for the improvement of paper strength and barrier properties. RSC Adv 5:60179–60187. https://doi.org/10.1039/C5RA08161K
Missoum K, Martoïa F, Belgacem MN, Bras J (2013) Effect of chemically modified nanofibrillated cellulose addition on the properties of fiber-based materials. Ind Crops Prod 48:98–105. https://doi.org/10.1016/j.indcrop.2013.04.013
Nourbakhsh A, Ashori A (2010) Particleboard made from waste paper treated with maleic anhydride. Waste Manag Res 28:51–55. https://doi.org/10.1177/0734242X09336463
Ojala J, Visanko M, Laitinen O et al (2018) Emulsion stabilization with functionalized cellulose nanoparticles fabricated using deep eutectic solvents. Molecules 23:2765. https://doi.org/10.3390/molecules23112765
Rattaz A, Mishra SP, Chabot B, Daneault C (2011) Cellulose nanofibres by sonocatalysed-TEMPO-oxidation. Cellulose 18:585–593. https://doi.org/10.1007/s10570-011-9529-8
Rojo E, Peresin MS, Sampson WW et al (2015) Comprehensive elucidation of the effect of residual lignin on the physical, barrier, mechanical and surface properties of nanocellulose films. Green Chem 17:1853–1866. https://doi.org/10.1039/C4GC02398F
Sehaqui H, Zhou Q, Berglund LA (2013) Nanofibrillated cellulose for enhancement of strength in high-density paper structures. Nord Pulp Pap Res J 28:182–189
Selkälä T, Sirviö JA, Lorite GS, Liimatainen H (2016) Anionically stabilized cellulose nanofibrils through succinylation pretreatment in urea-lithium chloride deep eutectic solvent. Chemsuschem. https://doi.org/10.1002/cssc.201600903
Singh BS, Lobo HR, Shankarling GS (2012) Choline chloride based eutectic solvents: magical catalytic system for carbon-carbon bond formation in the rapid synthesis of β-hydroxy functionalized derivatives. Catal Commun 24:70–74. https://doi.org/10.1016/j.catcom.2012.03.021
Siró I, Plackett D (2010) Microfibrillated cellulose and new nanocomposite materials: a review. Cellulose 17:459–494. https://doi.org/10.1007/s10570-010-9405-y
Sirviö JA (2018) Cationization of lignocellulosic fibers with betaine in deep eutectic solvent: facile route to charge stabilized cellulose and wood nanofibers. Carbohydr Polym 198:34–40. https://doi.org/10.1016/j.carbpol.2018.06.051
Sirviö JA, Visanko M, Liimatainen H (2015) Deep eutectic solvent system based on choline chloride-urea as a pre-treatment for nanofibrillation of wood cellulose. Green Chem 17:3401–3406. https://doi.org/10.1039/C5GC00398A
Spence KL, Venditti RA, Rojas OJ et al (2010) The effect of chemical composition on microfibrillar cellulose films from wood pulps: water interactions and physical properties for packaging applications. Cellulose 17:835–848. https://doi.org/10.1007/s10570-010-9424-8
Su J, Zhang L, Batchelor W, Garnier G (2014) Paper engineered with cellulosic additives: effect of length scale. Cellulose 21:2901–2911. https://doi.org/10.1007/s10570-014-0298-z
Suopajärvi T, Sirviö JA, Liimatainen H (2017) Nanofibrillation of deep eutectic solvent-treated paper and board cellulose pulps. Carbohydr Polym 169:167–175. https://doi.org/10.1016/j.carbpol.2017.04.009
Tajik M, Torshizi HJ, Resalati H, Hamzeh Y (2018) Effects of cationic starch in the presence of cellulose nanofibrils on structural, optical and strength properties of paper from soda bagasse pulp. Carbohydr Polym 194:1–8. https://doi.org/10.1016/j.carbpol.2018.04.026
Visanko M, Sirviö JA, Piltonen P et al (2017) Mechanical fabrication of high-strength and redispersible wood nanofibers from unbleached groundwood pulp. Cellulose 24:4173–4187. https://doi.org/10.1007/s10570-017-1406-7
Acknowledgments
Open access funding provided by University of Oulu including Oulu University Hospital. The authors would like to acknowledge the funding provided by the Council of Oulu Region, granted by the European Regional Development Fund of the European Union for the New bioproducts and—chemicals from cellulose side streams using DES-based refining concept project (SelDES).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Laitinen, O., Suopajärvi, T. & Liimatainen, H. Enhancing packaging board properties using micro- and nanofibers prepared from recycled board. Cellulose 27, 7215–7225 (2020). https://doi.org/10.1007/s10570-020-03264-w
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10570-020-03264-w