纸张与纸质文物脱酸材料近期研究与展望

doi:10.6023/A22110475

摘要/Abstract

纸张和纸质文物是书写和保存信息的主要载体, 具有重要的价值. 酸化降解是纸张目前面临的主要问题之一, 脱酸处理是减缓纸张酸化降解速率和延长纸张保存寿命的有效手段. 因此, 安全有效脱酸材料的开发与使用已成为纸张脱酸研究必不可少的方面. 通常, 氨基/胺类化合物、镁/钙等的碱性化合物因其纸张相容性好、碱性适宜、成本低且安全低毒被认为是较为优良的纸张脱酸材料. 本综述总结了近年来液相脱酸法中常用脱酸材料的研究进展, 包括脱酸材料的分类、制备方法以及纸张脱酸效果与材料结构之间的关系. 最后, 讨论了脱酸材料面临的挑战与发展.

关键词: 纸张, 酸化降解, 脱酸材料, 纸质文物保护

Paper and paper-based cultural relics are of great value as the main carriers for writing and preserving information. Acid-catalyzed hydrolysis is one of the most fatal reactions for paper degradation, and deacidification would effectively slow down the rate of its degradation and prolong the life time of paper. Therefore, the design and application of deacidifying materials with safety and effectiveness is the indispensable requirement for the protection of paper and paper-based cultural relics. Generally, alkaline materials, such as amino/amine compounds, magnesium/calcium hydroxides, oxides, carbonates are the mostly used deacidifying materials for their good paper compatibility, suitable alkalinity, low cost and low toxicity, which exhibit considerable paper deacidification performance. In this review, the recent research progresses of deacidifying materials on liquid phase deacidification process were reviewed, including the categories of deacidifying materials, preparation methods and the relationship between paper deacidification performance and structures of deacidifying materials, finally, the challenges and development of deacidifying materials were also discussed. For classification purpose according to chemical structure, deacidifying materials can be divided into four categories: ionic form, molecular form, micro/nano-scale form and composite form. The deacidifying materials with molecular form can significantly improve the mechanical properties of paper and show a certain deacidification effect, it is necessary to control the improvement of mechanical properties within reasonable ranges while considering the effective deacidification performance. Micro/nano-scale materials with large surface area, good penetration and high efficiency are the widely used deacidifying materials, which can achieve better deacidification effects at lower concentrations. The controlled alkalinity, high dispersion and suspension stability in solvents and uniform distribution in paper fibers of micro/nano-scale materials are highly demanded. Additionally, ionic form materials can interact with paper fibers more evenly through homogeneous deacidification process, but their alkaline reserve is relatively insufficient. And more insight is demanded into the co-existence stability of composite deacidifying materials and its contribution to paper protection.

Key words: paper, acid degradation, deacidifying materials, protection of paper-based cultural relics

引用此文

金姗姗, 王思浓. 纸张与纸质文物脱酸材料近期研究与展望[J]. 化学学报, 2023, 81(3): 309-318.

Shanshan Jin, Sinong Wang. Recent Research and Prospect of Deacidifying Materials for Paper and Paper-based Cultural Relics[J]. Acta Chimica Sinica, 2023, 81(3): 309-318.

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序号	纸张		成分	方法	脱酸材料		脱酸材料结构	溶剂
a^[19]	自然老化旧书			浸泡	3-氨基丙基三甲氧基硅烷	ATMS		乙醇
					3-氨基-2,2-二甲基丙基三甲氧基硅烷	AMTMS
					3-氨丙基三乙氧基硅烷	ATES
					3-氨丙基甲基二乙氧基硅烷	AMDES
					3-(N,N-二甲基氨基)丙基三甲氧基硅烷	DMATMS
b^[20]	P1	>95% CL SWP		浸泡	3-氨丙基甲基二乙氧基硅烷	AMDES		HMDSO
	P2	75% WP 25% SWP
	自然老化B1928
c^[26]	P3		CL (>95%)	浸泡	3-(N,N-二甲基氨基)丙基甲基二乙氧基硅烷	DMAPDES		HMDSO
d^[21]	P4		>95% CL SWP	浸泡	3-氨丙基甲基二乙氧基硅烷	AMDES		HMDSO
d^[21]	P4		>95% CL SWP	浸泡喷涂	3-氨丙基三乙氧基硅烷	APTES		HMDSO
序号	纸张		成分	方法	脱酸材料		脱酸材料结构	溶剂
				浸泡喷涂	APTES-AMDES 共聚物	APTES-AMDES		HMDSO/ 无溶剂
e^[27]	宣纸			浸泡	N-氨乙基-3-氨丙基- 三乙氧基硅烷	AETAPTES		乙醇
f^[28]	打印纸			浸泡	γ-缩水甘油醚氧丙基三甲氧基硅烷	KH560		乙醇
g^[23]	S1 (1986) WP			浸泡	甲基硅酸钾	PMS		水
	BDP
	宣纸		SWP>75% CL
h^[24]	滤纸			浸泡	水溶性聚酰胺	PAAOH		水
i^[29]	色谱纸			浸泡	硼烷叔丁胺络合物	TBAB
					硼烷氨络合物	AB
					硼烷N,N-二异丙基乙胺络合物	DIPEAB
					硼烷二甲胺络合物	DMAB
					硼烷吗啡络合物	MB
					硼烷三乙胺络合物	TEAB
					硼烷三甲胺络合物	TMAB

序号	纸张		成分	方法	脱酸材料		脱酸材料结构	溶剂
a^[19]	自然老化旧书			浸泡	3-氨基丙基三甲氧基硅烷	ATMS		乙醇
					3-氨基-2,2-二甲基丙基三甲氧基硅烷	AMTMS
					3-氨丙基三乙氧基硅烷	ATES
					3-氨丙基甲基二乙氧基硅烷	AMDES
					3-(N,N-二甲基氨基)丙基三甲氧基硅烷	DMATMS
b^[20]	P1	>95% CL SWP		浸泡	3-氨丙基甲基二乙氧基硅烷	AMDES		HMDSO
	P2	75% WP 25% SWP
	自然老化B1928
c^[26]	P3		CL (>95%)	浸泡	3-(N,N-二甲基氨基)丙基甲基二乙氧基硅烷	DMAPDES		HMDSO
d^[21]	P4		>95% CL SWP	浸泡	3-氨丙基甲基二乙氧基硅烷	AMDES		HMDSO
d^[21]	P4		>95% CL SWP	浸泡喷涂	3-氨丙基三乙氧基硅烷	APTES		HMDSO
序号	纸张		成分	方法	脱酸材料		脱酸材料结构	溶剂
				浸泡喷涂	APTES-AMDES 共聚物	APTES-AMDES		HMDSO/ 无溶剂
e^[27]	宣纸			浸泡	N-氨乙基-3-氨丙基- 三乙氧基硅烷	AETAPTES		乙醇
f^[28]	打印纸			浸泡	γ-缩水甘油醚氧丙基三甲氧基硅烷	KH560		乙醇
g^[23]	S1 (1986) WP			浸泡	甲基硅酸钾	PMS		水
	BDP
	宣纸		SWP>75% CL
h^[24]	滤纸			浸泡	水溶性聚酰胺	PAAOH		水
i^[29]	色谱纸			浸泡	硼烷叔丁胺络合物	TBAB
					硼烷氨络合物	AB
					硼烷N,N-二异丙基乙胺络合物	DIPEAB
					硼烷二甲胺络合物	DMAB
					硼烷吗啡络合物	MB
					硼烷三乙胺络合物	TEAB
					硼烷三甲胺络合物	TMAB

序号	纸张	成分	方法	脱酸剂	溶剂
a^[47]	S1	BSP	浸泡	Ca(OH)₂	水
b^[48]	Whatman paper		浸泡喷涂涂刷	Mg(OH)₂	异丙醇
c^[49]	韦托法		涂刷	CH₃OMgOCOOCH₃	水
d^[48]	Whatman paper		浸泡喷涂涂刷	Nano-Mg(OH)₂	异丙醇
e^[40]	《马克思恩格斯选集第二卷》1972 年出版		超声雾化	Ca(OH)₂	水
f^[37]	杂志		浸泡超临界CO₂	Ca(OH)₂	水/乙醇
g^[41]	BP		浸泡	Nano-Mg(OH)₂-SDS	水
h^[35]	S2	70% HWBP 30% SWBP 20% PFAK	喷洒	Nano-Ca(OH)₂	环己烷
i^[36]	文件		浸泡	Nano-Ca(OH)₂	水/异丙醇
j^[34]	油画纸			Nano-Ca(OH)₂	乙醇/正丙醇
k^[46]	P1	90% GW 10% SWBP 20% KLAS	浸泡	Nano-Ca(OH)₂	乙醇
k^[46]	P2	75% GW 25% SWBP 20% KLAS	浸泡	Nano-Ca(OH)₂	异丙醇
l^[39]	MWP-1920/1940		亚临界	Nano-Ca(OH)₂	R134a (超临界)
l^[39]	Newspaper in 1962		亚临界	Nano-Ca(OH)₂	R134a (超临界)
m^[43]	宣纸新闻纸机制纸		浸泡	MgO oleic acid-modified	环己烷
n^[44]	纸张(种类未知)		浸泡	MgO-Hal	羟丙基纤维素水溶液
o^[46]	P1	90% GW 10% SWBP 20% KLAS	浸泡	Nano-CaCO₃	乙醇
o^[46]	P2	75% GW 25% SWBP 20% KLAS	浸泡	Nano-CaCO₃	异丙醇
p^[45]	含有酸性油墨的纸		涂刷	Nano-Ca(C₂H₅COO)₂	乙醇
q^[37]	Standard paper		浸泡超临界CO₂	Mg(CH₃COO)₂	水/乙醇
r^[32]	手稿(1350; 1712; 1576)		浸泡	Ca(HCO₃)₂ Mg(HCO₃)₂	水
s^[50]	古籍修复时拆下的护页纸		浸泡	NaHCO₃	水
t^[51]	报纸		超临界	Na₂B₄O₇•10H₂O	水/乙醇、超临界CO₂

序号	纸张	成分	方法	脱酸剂	溶剂
a^[47]	S1	BSP	浸泡	Ca(OH)₂	水
b^[48]	Whatman paper		浸泡喷涂涂刷	Mg(OH)₂	异丙醇
c^[49]	韦托法		涂刷	CH₃OMgOCOOCH₃	水
d^[48]	Whatman paper		浸泡喷涂涂刷	Nano-Mg(OH)₂	异丙醇
e^[40]	《马克思恩格斯选集第二卷》1972 年出版		超声雾化	Ca(OH)₂	水
f^[37]	杂志		浸泡超临界CO₂	Ca(OH)₂	水/乙醇
g^[41]	BP		浸泡	Nano-Mg(OH)₂-SDS	水
h^[35]	S2	70% HWBP 30% SWBP 20% PFAK	喷洒	Nano-Ca(OH)₂	环己烷
i^[36]	文件		浸泡	Nano-Ca(OH)₂	水/异丙醇
j^[34]	油画纸			Nano-Ca(OH)₂	乙醇/正丙醇
k^[46]	P1	90% GW 10% SWBP 20% KLAS	浸泡	Nano-Ca(OH)₂	乙醇
k^[46]	P2	75% GW 25% SWBP 20% KLAS	浸泡	Nano-Ca(OH)₂	异丙醇
l^[39]	MWP-1920/1940		亚临界	Nano-Ca(OH)₂	R134a (超临界)
l^[39]	Newspaper in 1962		亚临界	Nano-Ca(OH)₂	R134a (超临界)
m^[43]	宣纸新闻纸机制纸		浸泡	MgO oleic acid-modified	环己烷
n^[44]	纸张(种类未知)		浸泡	MgO-Hal	羟丙基纤维素水溶液
o^[46]	P1	90% GW 10% SWBP 20% KLAS	浸泡	Nano-CaCO₃	乙醇
o^[46]	P2	75% GW 25% SWBP 20% KLAS	浸泡	Nano-CaCO₃	异丙醇
p^[45]	含有酸性油墨的纸		涂刷	Nano-Ca(C₂H₅COO)₂	乙醇
q^[37]	Standard paper		浸泡超临界CO₂	Mg(CH₃COO)₂	水/乙醇
r^[32]	手稿(1350; 1712; 1576)		浸泡	Ca(HCO₃)₂ Mg(HCO₃)₂	水
s^[50]	古籍修复时拆下的护页纸		浸泡	NaHCO₃	水
t^[51]	报纸		超临界	Na₂B₄O₇•10H₂O	水/乙醇、超临界CO₂

序号	纸张	纸浆	方式	脱酸剂	溶剂
a^[52]	中性纸酸性纸	BSP	浸泡涂刷	MC/Ca(OH)₂	水
b^[54]	滤纸	100%纤维素	浸泡	TMSC/Mg(OH)₂	HMDSO
b^[54]	德国木浆纸	50% WP＋50% CP	浸泡	TMSC/Mg(OH)₂	HMDSO
c^[55]	模拟宣纸/WP		涂刷	EC/Mg(OH)₂	乙醇
d^[56]	纸张		浸泡喷洒	MgO/Ca(OH)₂/ETA	HMDSO
e^[53]	模拟老化纸		雾化	NaCO₃/Ca(C₃H₅O₂)₂/纤维素纳米晶体	水
f^[57]	报纸		涂刷	羧甲基纤维素/小麦淀粉浆糊/Ca(OH)₂	水