“南海Ⅰ号”沉船木材降解特征变化

doi:10.11707/j.1001-7488.LYKX20250398

摘要/Abstract

摘要：

目的: 分析“南海Ⅰ号”沉船木材降解特征变化，科学评估其保存状况，为沉船保护修复方案的制定提供理论依据和技术支撑。方法: 以“南海Ⅰ号”沉船具代表性的四号舱、七号舱和十一号舱为研究对象，于2023、2024年开展系统性监测分析。针对5类沉船构件共30个监测点位，采集考古木材样品41份，采用光学显微镜进行树种鉴定，并观察木材降解的解剖构造特征；测定样品的最大含水率和基本密度等物理特性指标；应用衰减全反射?傅里叶变换红外光谱（ATR-FTIR）获取样品的化学结构信息，并利用主成分分析对ATR-FTIR光谱数据进行处理。结果: “南海Ⅰ号”沉船所选构件用材以硬木松为主（占比62%），3个舱室木材降解程度相似，降解由表及里，但不同舱室和监测点位木材呈现不同的差异性降解特征。四号舱A3、A6监测点位木材保存状况相对稳定，A12监测点位半纤维素/木质素比值（H/L）2023—2024年存在显著差异，表明该点位多糖组分发生明显降解。七号舱A23和A33监测点位木材出现新的增强峰，H/L显著提高，随着船体脱盐清理，木材受外源污染物影响减轻，保存状况相较2023年有所改善；A30监测点位木材经去除外源污染物处理后，保存状况保持稳定。十一号舱A52和A58监测点位木材保存状况保持稳定，A48监测点位木材在1 725、1 645 cm^-1处吸收峰强度降低，略有降解趋势。结论: “南海Ⅰ号”沉船木材保存状况较差，呈中度至重度降解水平；不同舱室乃至同一舱室内不同点位木材保存状况存在差异；A12、A48等降解严重区域需要加强保护措施，A23、A33等受外源物影响区域需要开展系统性清理和动态监测。

关键词: "南海Ⅰ号"沉船, 降解特征, 解剖构造, 化学结构, 保存状况

Abstract:

Objective: In this study, the degradation degrees of archaeological wood samples of three typical compartments of the “Nanhai Ⅰ” shipwreck was tested and analyzed by multi-dimensional testing methods, aiming to scientifically evaluate their preservation condition and provide theoretical basis and technical support for the protection and restoration of the shipwreck. Method: The representative cabins 4, 7 and 11 of the “Nanhai Ⅰ” shipwreck were targeted, and the systematic monitoring and analysis was conducted in 2023 and 2024. A total of 41 archaeological wood samples were collected from 30 monitoring sites for 5 types of shipwreck components. Optical microscopy was used to identify tree species, and the anatomical features of wood degradation were systematically observed. The maximum water content (MWC) and basic density (BD) of the wood samples were measured. Attenuated total reflection–Fourier transform infrared spectroscopy (ATR–FTIR) was used to obtain the chemical structure information of archaeological wood samples, and principal component analysis (PCA) was applied to process the ATR–FTIR spectral data. Result: The materials for the selected components of the “Nanhai Ⅰ” shipwreck were mainly hardwood pines (Pinus sp.), accounting for 62%. The shipwreck timber from three cabins exhibited similar degradation conditions. The wood degradation progressed from the surface inward, yet exhibited various degradation characteristics across different cabins and monitoring points. Specifically, the wood preservation condition at monitoring points A3 and A6 in cabin 4 remained relatively stable, while point A12 showed a notable difference in the hemicellulose/lignin ratio (H/L) between 2023 and 2024, indicating pronounced degradation of polysaccharide components at this site. In cabin 7, monitoring points A23 and A33 exhibited new enhancement peaks in the wood, with a significant increase in H/L values. With the desalination cleaning of the ship, the wood was less affected by external pollutants, and its preservation condition improved compared with 2023. At point A30, after the removal of exogenous pollutants, the preservation condition remained stable. In cabin 11, points A52 and A58 maintained stable preservation conditions, whereas point A48 displayed reduced absorption peak intensities at 1 725 cm^-1 and 1 645 cm^-1, indicating degradation in the wood. Conclusion: The wood preservation condition of the “Nanhai Ⅰ” shipwreck is poor and is primarily in a moderate to severe state of degradation. There are differences in preservation condition of wood in different compartments or different monitoring sites in the same compartment. Monitoring sites with serious degradation, such as A12 and A48, need to strengthen protection measures, and other sites affected by exogenous substances, such as A23 and A33, need to carry out systematic cleaning and dynamic monitoring.

Key words: “Nanhai Ⅰ” shipwreck, degradation characteristics, anatomical feature, chemical structure, preservation condition

中图分类号:

S781
S718.3

汪嘉君,王红,郭娟,李乃胜,杨有天,殷亚方. “南海Ⅰ号”沉船木材降解特征变化[J]. 林业科学, 2026, 62(6): 46-55.

Jiajun Wang,Hong Wang,Juan Guo,Naisheng Li,Youtian Yang,Yafang Yin. Variation of Wood Degradation Characteristics in “Nanhai Ⅰ” Shipwreck[J]. Scientia Silvae Sinicae, 2026, 62(6): 46-55.

图/表 10

图1

表1

“南海Ⅰ号”沉船考古木材样品采样信息①"

样品编号 Sample No.	舱位 Cabin	采样部位 Sampling site	是否采样 Sampling or not		树种Tree species	保存状况 Preservation condition
样品编号 Sample No.	舱位 Cabin	采样部位 Sampling site	2023	2024	树种Tree species	2023	2024
A1	四号舱 Cabin 4	隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A2		船壳板Hull plates		√	硬木松Pinus sp.		重度降解 Severe degradation
A3		船壳板Hull plates	√	√	杉木Cunninghamia lanceolata	中度至重度降解 Moderate to severe degradation	重度降解 Severe degradation
A6		船壳板Hull plates	√	√	硬木松Pinus sp.	重度降解 Severe degradation	重度降解 Severe degradation
A9		船壳板Hull plates		√	硬木松Pinus sp.		重度降解 Severe degradation
A11		甲板Deck		√	杉木Cunninghamia lanceolata		重度降解 Severe degradation
A12		隔舱板Partition board	√	√	硬木松Pinus sp.	重度降解 Severe degradation	重度降解 Severe degradation
A18		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A19		隔舱板Partition board		√	—		—
A20		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A21	七号舱 Cabin 7	桅面梁Mast surface beam		√	樟木Cinnamomum sp.		重度降解 Severe degradation
A23		加强筋Stiffener	√	√	樟木Cinnamomum sp.	重度降解 Severe degradation	重度降解 Severe degradation
A24		船壳板Hull plates		√	软木松Pinus sp.		重度降解 Severe degradation
A25		隔舱板Partition board		√	软木松Pinus sp.		重度降解 Severe degradation
A28		船壳板Hull plates	√	√	杉木Cunninghamia lanceolata	重度降解 Severe degradation	重度降解 Severe degradation
A30		船壳板Hull plates	√	√	硬木松Pinus sp.	重度降解 Severe degradation	重度降解 Severe degradation
A32		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A33		隔舱板Partition board	√	√	硬木松Pinus sp.	中度至重度降解 Moderate to severe degradation	中度至重度降解 Moderate to severe degradation
A37		加强筋Stiffener		√	樟木Cinnamomum sp.		重度降解 Severe degradation
A39		船壳板Hull plates		√	硬木松Pinus sp.		重度降解 Severe degradation
A41	十一号舱 Cabin 11	隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A43		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A44		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A45		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A48		船壳板Hull plates	√	√	杉木Cunninghamia lanceolata	重度降解 Severe degradation	重度降解 Severe degradation
A50		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A52		隔舱板Partition board		√	硬木松Pinus sp.	重度降解 Severe degradation	重度降解 Severe degradation
A53		甲板Deck		√	杉木Cunninghamia lanceolata		中度降解 Moderate degradation
A54		隔舱板Partition board		√	硬木松Pinus sp.		重度降解 Severe degradation
A58		船壳板Hull plates	√	√	杉木Cunninghamia lanceolata	重度降解 Severe degradation	重度降解 Severe degradation

表1

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表2

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表3

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图6

图7

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样品编号 Sample No.	基本密度 Basic density/(g·cm^?3)	最大含水率 Maximum water content (%)
A3	0.179	473
A6	0.160	559
A12	0.165	550
A23	0.139	646
A28	0.137	652
A30	0.250	334
A33	0.466	164
A48	0.174	527
A52	0.233	383
A58	0.154	590

四号舱Cabin 4		七号舱Cabin 7		十一号舱Cabin 11
A1	0.81±0.07	A21	0.79±0.08	A41	0.63±0.02
A2	0.62±0.01	A23	0.76±0.02	A43	0.68±0.02
A3	0.62±0.04	A24	0.68±0.04	A44	0.68±0.02
A6	0.62±0.01	A25	0.83±0.01	A45	0.62±0.02
A9	0.59±0.03	A28	0.74±0.12	A48	0.56±0.01
A11	0.59±0.02	A30	0.68±0.02	A50	0.87±0.04
A12	0.65±0.02	A32	0.71±0.03	A52	0.61±0.04
A18	0.85±0.04	A33	0.90±0.10	A53	0.85±0.07
A19	1.06±0.08	A37	0.75±0.03	A54	0.72±0.03
A20	0.62±0.04	A39	0.62±0.02	A58	0.55±0.01

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