All Issue

2024 Vol.56, Issue 2 Preview Page

Research Article

Effect of Mechanical-Chemical Pretreatment at Room Temperature on Properties of Cellulose and Cellulose Solution

상온에서의 기계적-화학적 전처리가 셀룰로오스 및 용액 특성에 미치는 영향

Se-Young Oh1
,
Feng Xu1
,
Byoung-Uk Cho2
오 세영1
,
서 풍1
,
조 병욱2
1Dept. of Paper Science & Engineering, College of Forest and Environmental Sciences, Kangwon National University
2Dept. of Paper Material Science & Engineering, College of Forest and Environmental Science, Kangwon National University
1강원대학교 산림환경과학대학 제지공학과, 학생
2강원대학교 산림환경과학대학 종이소재과학전공, 교수
Corresponding author: E-Mail: bucho@kangwon.ac.kr (Address: Dept. of Paper Material Science & Engineering, Kangwon National University, Chunchon, Republic of Korea)
30 April 2024. pp. 12-21
PDF XML Citation
Abstract

The high degree of polymerization (DP) of cellulose makes it difficult to dissolve the cellulose fibers and increases the viscosity of the dissolved cellulose solution, which limits the ability to produce small particles of beads by using small needles or nozzles by dropping or spraying methods. This study explores the development of a technology to control the DP of cellulose of a chemical pulp through a mechanochemical pretreatment at room temperature. The chemical pulp was pretreated by three methods (ethanol-hydrochloric acid pretreatment, ball milling pretreatment, or acid-ball milling pretreatment), and the effects on fiber and cellulose properties, cellulose solution properties, and bead size were explored. Our findings reveal that wet ball milling pretreatment with acid is more effective in reducing DP of cellulose than acid treatment or ball milling treatment alone. The DP of cellulose of chemical pulp was reduced from 1400 to 400 after 1 h of acid-ball milling treatment at room temperature. The reduction in the DP of cellulose decreased the viscosity and surface tension of the cellulose solution, which affected the size of cellulose beads. In addition, the acid-ball milling pretreatment resulted shortening of fiber length and external fibrillation, and did not affect the crystal structure of cellulose-I, unlike the ball milling treatment, which destroyed the fiber morphology and the cellulose crystal structure.

Keywords
Acid hydrolysis
ball milling
mechanochemical pretreatment
degree of polymerization
TEAOH/urea solvents
cellulose solution
References
1

Sen, S., Martin, J. D., and Argyropoulos, D. S, Review of cellulose non-derivatizing solvent interactions with emphasis on activity in inorganic molten salt hydrates, ACS Sustainable Chemistry & Engineering 1(8):858-870 (2013).

10.1021/sc400085a
2

Wang, H., Gurau, G., and Rogers, R. D., Ionic liquid processing of cellulose, Chemical Society Reviews 41(4):1519-1537 (2012).

10.1039/c2cs15311d22266483
3

Wendler, F., Todi, L. N., and Meister, F., Thermostability of imidazolium ionic liquids as direct solvents for cellulose, Thermochimica Acta 528:76-84 (2012).

10.1016/j.tca.2011.11.015
4

Gericke, M., Trygg, J., and Fardim, P. Functional cellulose beads: Preparation, characterization, and applications, Chemical Reviews 113(7):4812-4836 (2013).

10.1021/cr300242j23540980
5

Han, J. S. and Seo, Y. B., Study of cotton linter solubility in different alkaline cellulose solvent systems and its film properties, J. of Korea TAPPI 49(3):79-86 (2017).

10.7584/JKTAPPI.2017.06.49.3.79
6

Ryu, J. A., Kim, K. J., Ahn, E. B., and Eom, T. J., Dissolution of cellulosic material with glycol ether/NaOH aqueous solution, J. of Korea TAPPI 51(1):19-27 (2019).

10.7584/JKTAPPI.2019.02.51.1.19
7

Lee, S. G., Oh, S. Y., and Cho, B. U., Dissolution of HwBKP with [Bmim]Cl-DMF solvent and production of cellulose beads: Effect of mixing ratio of solvents, J. of Korea TAPPI 54(2):27-36 (2022).

10.7584/JKTAPPI.2022.04.54.2.27
8

Cai, J. and Zhang, L., Rapid dissolution of cellulose in LiOH/urea and NaOH/urea aqueous solutions, Macromolecular Bioscience 5(6):539-548 (2005).

10.1002/mabi.20040022215954076
9

Qi, H., Chang, C., and Zhang, L., Effects of temperature and molecular weight on dissolution of celluloe in NaOH/urea aqueous solution, Cellulose 15:779-787 (2008).

10.1007/s10570-008-9230-8
10

Abushammala, H. and Mao, J., A review of the partial and complete dissolution and fractionation of wood and lignocelluloses using imidazolium ionic liquids, Polymers 12:195 (2020).

10.3390/polym1201019531940847PMC7023464
11

Kihlman, M., Aldaeus, F., Chedid, F., and Germagård, U., Effect of various pulp properties on the solubility of cellulose in sodium hydroxide solutions, Holzforschung 66:601-606 (2012).

10.1515/hf-2011-0220
12

Morton, J. H., Viscosity/DP relationships for celulose dissolved in cuprammonum and cupriethylene diamine solvents, In Proceedings of Cellucon '94, In The Chemistry and Processing of Wood and Plant Fibrous Material, Buckeye Cellulose Co., Memphis, USA, pp. 151-158 (1996).

10.1533/9781845698690.151
13

Liu, J., Zhang, J., Zhang, B., Zhang, X., Xu, L., Zhang, J., He, J., and Liu, C. Y., Determination of intrinsic viscosity-molecular weight relationship for cellulose in BmimAc/DMSO solutions, Cellulose 23:2341-2348 (2016).

10.1007/s10570-016-0967-1
14

Trygg, J. and Fardim, P., Enhancement of cellulose dissolution in water-based solvent via ethanol-hydrochloric acid pretreatment, Cellulose 18:987-994 (2011).

10.1007/s10570-011-9550-y
15

Håkansson, H. and Ahlgren, P., Acid hydrolysis of some industrial pulps: Effect of hydrolysis conditions and raw material, Cellulose 12:177-183 (2005).

10.1007/s10570-004-1038-6
16

Shi, Z., Yang, Q., Kuga, S., and Matsumoto, Y., Dissolution of wood pulp in aqueous NaOH/urea solution in via dilute acid pretreatment, J. of Agricultural and Food Chemistry 63:6113-6119 (2015).

10.1021/acs.jafc.5b0171426101792
17

Avolio, R., Bonadies, I., Capitani, D., Errico, M. E., Gentile, G., and Avella, M. A multitechnique approach to assess the effect of ball milling on cellulose, Carbohydrate Polymers 87(1):265-273 (2012).

10.1016/j.carbpol.2011.07.04734662960
18

Hu, H., Zhang, Y., Liu, X., Huang, Z., Chen, Y., Yang, M., Qin, X., and Feng, Z., Structural changes and enhanced accessibility of natural cellulose pretreated by mechanical activation, Polymer Bulletin 71:453-464 (2014).

10.1007/s00289-013-1070-5
19

Shi, Z., Liu, Y., Xu, H., Yang, Q., Xiong, C., Kuga, S., and Matsumoto, Y. Facile dissolution of wood pulp in aqueous NaOH/urea solution by ball milling pretreatment, Industrial Crops and Products 118:48-52 (2018).

10.1016/j.indcrop.2018.03.035
20

Duan, C., Verma, S. K., Li, J., Ma, X., and Ni, Y., Viscosity control and reactivity improvement of cellulose fibers by cellulase treatment, Cellulose 23:269-276 (2016).

10.1007/s10570-015-0822-9
21

Hwang, Y., Jeong, M. J., and Park, H. J., Changes in the physical properties of the cotton linter paper irradiated by a gamma ray and electron beam, J. of Korea TAPPI 54(6):51-59 (2022).

10.7584/JKTAPPI.2022.12.54.6.51
22

James, S. L., Adams, C. J., Bolm, C., Braga, D., Collier, P., Friščić, T., Grepioni, F., Harris, K. D. M., Hyette, G., Jones, W., Krebs, A., Mack, H., Maini, L., Orpen, A. G., Parkin, I. P., Shearouse, W. C., Steed, J. W., and Waddel, D. C., Mechnochemistry: Opportunities for new and clear synthesis, Chemical Society Reviews 41(1):413-447 (2012).

10.1039/C1CS15171A21892512
23

Kuga, S. and Wu, M., Mechanochemistry of cellulose, Cellulose 26:215-225 (2019).

10.1007/s10570-018-2197-1
24

Sirviö, J. A. and Heiskanen, J. P. Room-temperature dissolution and chemical modification of cellulose in aqueous tetraethylammonium hydroxide-carbamide solutions, Cellulose 27(4):1933-1950 (2020).

10.1007/s10570-019-02907-x
25

KS M ISO 5351, Pulps - Determination of limiting viscosity number in cupri-ethylenediamine (CED) solution, Korean Standards Association (2020).

26

Trygg, J., Trivedi, P., and Fardim, P., Controlled depolymerisation of cellulose to a given degree of polymerisation, Cellulose Chemistry and Technology 50(5-6):557-567 (2016).

27

Segal, L. G. J. M. A., Creely, J. J., Martin Jr, A. E., and Conrad, C. M. An empirical method for estimating the degree of crystallinity of native cellulose using the X-ray diffractometer, Textile Research Journal 29(10):786-794 (1959).

10.1177/004051755902901003
28

Zhang, L., Tsuzuki, T., and Wang, X. Preparation of cellulose nanofiber from softwood pulp by ball milling, Cellulose 22:1729-1741 (2015).

10.1007/s10570-015-0582-6
29

Davanliu, A., Lee, J. D., Basu, S. and Kumar, R., Effect of viscosity and surface tension on breakup and coalescence of bicomponent sprays, Chemical Engineering Science 131:243-255 (2015).

10.1016/j.ces.2015.03.057
30

Sakai, T. and Hoshino, N., Production of uniform droplets by longitudinal vibration of audio frequency, J. of Chemical Engineering of Japan 13(4):263-268 (1980).

10.1252/jcej.13.263
31

Del Gaudio, R., Colombo, P., Colombo, G., Russo, P., and Sonvico, F., Mechanisms of formation and disintegration of alginate beads obtained by prilling, International J. of Pharmaceutics 302:1-9 (2005).

10.1016/j.ijpharm.2005.05.04116102925
Information
  • Publisher :Korea Technical Association of The Pulp and Paper Industry
  • Publisher(Ko) :한국펄프종이공학회
  • Journal Title :Journal of Korea TAPPI
  • Journal Title(Ko) :펄프종이기술
  • Volume : 56
  • No :2
  • Pages :12-21
  • Received Date : 2024-02-28
  • Revised Date : 2024-04-02
  • Accepted Date : 2024-04-03
  • DOI :https://doi.org/10.7584/JKTAPPI.2024.4.56.2.12
Journal Informaiton Journal of Korea TAPPI Journal of Korea TAPPI
Online Submission
  • scopus
  • NRF
  • KOFST
  • crossref crossmark
  • crossref cited-by
  • crosscheck
  • orcid
Journal Informaiton Journal Informaiton - close