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Study on aging resistance of AAAS grafted in situ on paper documents

  • Deli Zeng , Huiming Fan EMAIL logo , Shanshan Huang , Fengyu Li , Yunfei Liao , Ge Ge and Jianan Liu EMAIL logo
Published/Copyright: December 7, 2022
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Nordic Pulp & Paper Research Journal
From the journal Nordic Pulp & Paper Research Journal Volume 38 Issue 1

Abstract

Due to the complex storage environment, paper documents will suffer different degrees of damage during storage. Studying the aging behavior of paper after strengthening treatment is an important aspect of evaluate the effect of strengthening agent treatment. In this paper, the aging resistance properties of base paper, APTES, AEAPMDMS, and APTES/AEAPMDMS reinforced samples after dry heat aging and moist heat aging were studied. The results show that in the early stage of aging, the amorphous region of the fiber is mainly degraded gradually. With the passage of time, the crystalline region of cellulose is also degraded continuously, and the crystalline region of cellulose is degraded more significantly during moist heat aging. Compared with the base paper, the AAAS reinforced paper sample can significantly slow down the aging and degradation of the paper sample and has better aging resistance.

Keywords: accelerate aging; alkoxysilane; documents protection; paper durability; reinforcement

Funding source: State Key Laboratory of Pulp and Paper Engineering

Award Identifier / Grant number: 2020ZR03

Funding statement: This work was supported by Guangzhou Dadian, Science and Technology Plan Projects of Guangzhou City, China (No. GZDD201808); Lingnan Literature Protection Research Center of Guangzhou City, China (No. 202103260039); and State Key Laboratory of Pulp and Paper Engineering, China (No. 2020ZR03).

  1. Conflict of interest: The authors declare no conflicts of interest.

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Received: 2022-10-13
Accepted: 2022-11-08
Published Online: 2022-12-07
Published in Print: 2023-03-28

© 2023 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Biorefining
  3. Microwave heating rate and dielectric properties of some agricultural wastes
  4. Chemical pulping
  5. Adapting the kraft cooking process in glycerol media. Studies of impregnation kinetics
  6. Paper technology
  7. Numerical simulation of heat pump drying system for paper exhaust hood
  8. Using machine learning to predict paperboard properties – a case study
  9. Paper physics
  10. Wet creping of paperboard
  11. Experimental investigation into paper dust formation during knife edge cutting on a laboratory scale
  12. Bending stiffness and moment capacity of cardboard obtained from three-point and elastica bending tests
  13. Paper chemistry
  14. Application of TMP-DCMC-BBR/KH-791-SiO2/HPDSP multifunctional protective fluid in paper protection
  15. Study on aging resistance of AAAS grafted in situ on paper documents
  16. Coating
  17. Flexible graphene oxide/polyacrylonitrile composite films with efficient ultraviolet shielding and high transparency for the protection of paper-based artifacts
  18. Activated carbon paper as ethylene adsorber
  19. Printing
  20. Effect of progressive deinking and reprinting on inkjet-printed paper
  21. Digital printing systems and office papers interactions and the effects on print quality
  22. Packaging
  23. Comparison of methods to characterize the penetration of hot melt adhesive into paper
  24. A study on forming limit diagram and laminated stamping of paperboard
  25. Environmental Impact
  26. Ultrafiltration and reuse opportunities of sectorial effluents from a kraft pulp mill in Brazil
  27. CaCO3 solubility in the process water of recycled containerboard mills
  28. Miscellaneous
  29. Feasibility for the preparation of aerogels with celluloses extracted mildly from waste palm leaves
https://doi.org/10.1515/npprj-2022-0085
Keywords for this article
accelerate aging; alkoxysilane; documents protection; paper durability; reinforcement

Articles in the same Issue

  1. Frontmatter
  2. Biorefining
  3. Microwave heating rate and dielectric properties of some agricultural wastes
  4. Chemical pulping
  5. Adapting the kraft cooking process in glycerol media. Studies of impregnation kinetics
  6. Paper technology
  7. Numerical simulation of heat pump drying system for paper exhaust hood
  8. Using machine learning to predict paperboard properties – a case study
  9. Paper physics
  10. Wet creping of paperboard
  11. Experimental investigation into paper dust formation during knife edge cutting on a laboratory scale
  12. Bending stiffness and moment capacity of cardboard obtained from three-point and elastica bending tests
  13. Paper chemistry
  14. Application of TMP-DCMC-BBR/KH-791-SiO2/HPDSP multifunctional protective fluid in paper protection
  15. Study on aging resistance of AAAS grafted in situ on paper documents
  16. Coating
  17. Flexible graphene oxide/polyacrylonitrile composite films with efficient ultraviolet shielding and high transparency for the protection of paper-based artifacts
  18. Activated carbon paper as ethylene adsorber
  19. Printing
  20. Effect of progressive deinking and reprinting on inkjet-printed paper
  21. Digital printing systems and office papers interactions and the effects on print quality
  22. Packaging
  23. Comparison of methods to characterize the penetration of hot melt adhesive into paper
  24. A study on forming limit diagram and laminated stamping of paperboard
  25. Environmental Impact
  26. Ultrafiltration and reuse opportunities of sectorial effluents from a kraft pulp mill in Brazil
  27. CaCO3 solubility in the process water of recycled containerboard mills
  28. Miscellaneous
  29. Feasibility for the preparation of aerogels with celluloses extracted mildly from waste palm leaves
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