主持，科技部国家科技基础资源调查专项  “《中国木材志》修编”子课题，在研

主持，国家自然科学基金委面上基金 “水分移动中伴随木质素交联重构生成饱水考古木材细胞壁·腔形态学演变机制”，在研

主持，国家林业和草原局林草青拔人才项目“木材细胞壁的多层级结构”，已结题

主持，国家自然科学基金委青年基金 “常态下出土木材干缩湿胀经时演变及其影响机制”，已结题

主持，科技部国家重点研发计划 “海洋出水木质文物脱水材料与工艺研究”子课题，已结题

主持，中国林业科学研究院院杰出青年项目 “木射线分化过程中细胞壁多层级结构演变”，已结题

主持，中国林业科学研究院院优秀青年项目 “饱水木质文物精细构造与加固机理”，已结题

代表性文章：

1)      王红，汪嘉君*，张治国，殷亚方，郭娟*. 饱水木质文物的变色机理及脱色保护研究进展. 材料导报, 2026, 40(13), 25060018.

2)      郭娟，焦立超，何拓，马灵玉，姜笑梅，殷亚方. 木材定量解剖研究新进展. 林业科学, 2025, 61(2), 204-218.

3)      郭娟，尹丽娟，马灵玉，姜笑梅，孟秋露，姚立宏. 木射线结构特征与分析方法的研究进展. 林业工程学报, 2025, 10(5), 14-24.

4)      Yin L., Ma L., Jiang X., Zhang Y., Wei Y., Cao Y., Yao L., Guo J.* Positional differences in the micro- and ultra- structural variations of ray parenchyma cells during the transformation from sapwood to heartwood. Frontiers in Plant Science, 2024, 15, 1431818.

5)      Wei Y., Zheng C., Ma L., Jiang X., Yin Y., Guo J.* Inter- and intra-growth ring variations of wood carbon fractions in Pinus tabuliformis. Holzforschung, 2024, 78(3), 137-147.

6)      魏裕沛, 郭娟*, 殷亚方. 树木木质部含碳率变化规律研究进展. 世界林业研究, 2024, 37(3), 60-66.

7)      Guo Y., Jiao L., Wang J., Ma L., Lu Y., Zhang Y., Guo J.*, Yin Y.* Analyses of high spatial resolution datasets analyses identify genes associated with multi-layered secondary cell wall thickening in Pinus bungeana. Annals of Botany, 2024, 133(7), 953-968.

8)      Ma L., Meng Q., Jiang X., Ge Z., Cao Z., Wei Y., Jiao L., Yin Y., Guo J.* Spatial organization and connectivity of wood rays in Pinus massoniana xylem based on high-resolution μCT-assisted network analysis. Planta, 2023, 258, 28.

9)      Wang J., Jia H. Daniel G., Gao J., Jiang X., Ma L., Yue S.*, Guo J.*, Yin Y*. Insights into asynchronous changes of cell wall polymers accumulated in different cell types during conifer xylem differentiation. Carbohydrate Polymers, 2023, 316, 121076.

10)   Guo J., Chen J., Meng Q., Ploszczanski L., Liu J., Luo R., Jin T., Siedlaczek P., Lichtenegger H.C., Yin Y., Rennhofer H. Molecular and crystal structures of cellulose in severely deteriorated archaeological wood. Cellulose, 2022, 29, 9549–9568.

11)   Chen J, Liu S, Yin L, Cao H, Xi G, Zhang Z, Liu J, Luo R, Han L, Yin Y, Guo J*. Non-destructive preservation state estimation of waterlogged archaeological wooden artifacts. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2023, 285, 121840.

12)   Yin L, Jiang X, Ma L, Liu S, He T, Jiao L, Yin Y, Yao L*, Guo J*. Anatomical adaptions of pits in two types of ray parenchyma cells in Populus tomentosa during the xylem differentiation. Journal of Plant Physiology, 2022, 278, 153830.

13)   Guo J., Chen J., Li R., Liu Q., Luo R., Jiao L., Yin Y. Thermoporometry of waterlogged archaeological wood insights into the change of pore traits after the water-removal by supercritical drying. Thermochimica Acta, 2022, 715, 179297.

14)   Han L., Guo J.*, Tian X., Jiang X., Yin Y. Evaluation of PEG and sugars consolidated fragile waterlogged archaeological wood using nanoindentation and ATR-FTIR imaging. International Biodeterioration & Biodegradation, 2022, 170, 105390.

15)   韩刘杨，韩向娜，田兴玲，周海宾，殷亚方，郭娟*. 红外光谱和热重分析法评估三种加固剂对“小白礁 I 号”考古木材微力学性能的影响. 光谱学与光谱分析, 2022, 42(5), 1529-1534.

16)   Meng Q., Feng F., Wang J., He T., Jiang X., Zhang Y., Yin Y., Li N.*, Guo J.* Ray traits of juvenile wood and mature wood: Pinus massoniana and Cunninghamia lanceolata. Forests, 2021, 12, 1277.

17)   Guo J., Zhang M., Liu J., Luo R., Yan T., Yang T., Jiang X., Dong M., Yin Y.* Evaluation of the Deterioration State of Archaeological Wooden Artifacts: A Non-destructive Protocol based on Direct Analysis in Real Time – Mass Spectrometry (DART-MS) coupled to Chemometrics. Analytical Chemistry, 2020, 14, 9908–9915.

18)   Han L., Tian X., Keplinger T., Zhou H., Li R., Svedström K., Burgert I., Yin Y., Guo J.* Even visually intact cell walls in waterlogged archaeological wood are chemically deteriorated and mechanically fragile: a case of a 170 year-old shipwreck. Molecules, 2020, 25, 1113.

19)   韩刘杨, 田兴玲, 周海宾, 殷亚方, 郭娟* 饱水清代木材的构造腐朽程度及加固处理对其颜色的影响. 西南林业大学学报, 2020, 40(1), 132–138.

20)   Zhao Y., Zhao X., Iida I., Guo J.* Studies on pre-treatment by compression for wood impregnation II: the impregnation of wood compressed at different moisture content conditions. Journal of Wood Science, 2019, 65, 28.

21)   Guo J.#, Xiao L.#, Han L., Wu H., Yang T., Wu S., Yin Y.* Deterioration of cell wall in waterlogged wooden archaeological artifacts, 2400 years old. IAWA Journal, 2019, 40(4), 820-844.

22)   Zhao Y., Wang Z., Iida I., Guo J.* Studies on pre-treatment by compression for wood impregnation I: effects of compression ratio, compression direction, compression speed and compression-unloading place on the liquid impregnation of wood. Journal of Wood Science, 2018, 64(5), 551-556.

23)   Guo J.#, Zhou H., Stevanic J.S., Dong M., Yu M., Salmén L.*, Yin Y. Effects of Aging on the Cell Wall and Its Hygroscopicity of Wood in Ancient Timber Construction. Wood Science and Technology, 2018, 52(1), 131-147.

24)   Guo J.#, Guo X.#, Xiao F., Xiong C., Yin Y.* Influences of Provenance and Rotation Age on Heartwood Ratio, Stem Diameter and Radial Variation in Tracheid Dimension of Cunninghamia lanceolate. European Journal of wood and wood products, 2018, 76, 669-677.

25)   Guo J., Du W., Wang S., Yin Y.*, Gao Y*. Cellulose nanocrystals: a layered host candidate for fabricating intercalated nanocomposites. Carbohydrate Polymers, 2017, 157, 79-85.

26)   Guo J., Yin J., Zhang Y., Salmén L.*, Yin Y*. Effects of Thermos-Hygro-Mechanical (THM) treatment on the viscoelasticity of in-situ lignin. Holzforschung, 2017, 71(6), 455-460.

27)   Guo J., Du W., Gao Y., Cao Y., Yin Y*. Cellulose nanocrystals as water-in-oil Pickering emulsifiers via intercalative modification. Colloids and Surfaces A Physicochemical & Engineering aspects, 2017, 529, 634-642.

28)   Du W., Guo J.*, Li H., Gao Y.* Heterogeneously modified cellulose nanocrystals stabilized Pickering emulsion: preparation and their template application for the creation of PS microspheres with amino–-rich surfaces. ACS Sustainable Chemistry & Engineering, 2017, 5(9), 7514-7523.

29)   Guo J., Guo X., Wang S., Yin Y*. Effects of ultrasonic treatment during acid hydrolysis on the yield, particle size and structure of cellulose nanocrystals. Carbohydrate Polymers, 2016, 135, 248-255.

30)   Guo J., Rennhofer H., Yin Y.*, Lichtenegger H*. The influence of thermo-hygro-mechanical treatment on the micro- and nanoscale architecture of wood cell walls using small- and wide-angle X-ray scattering. Cellulose, 2016, 23(4), 2325-2340.

31)   Guo J., Fu K., Zhang Z., Yang L., Huang Y., Huang C., Zhu L.*, Chen D*.  Reversible thermochromism via hydrogen-bonded cocrystals of polydiacetylene and melamine. Polymer, 2016, 105, 440-448.

32)   Guo J. #, Song K.#, Salmén L.*, Yin Y*. Changes of wood cell walls in response to hygro-mechanical steam treatment. Carbohydrate polymers, 2015, 115, 207-214.

33)   郭旭霞, 郭娟*, 殷亚方. 杉木幼龄材和成熟材纤维素纳米晶体的制备及其性能. 东北林业大学学报, 2015, 43(10), 103-108.

34)   郭旭霞, 郭娟*, 卢芸, 殷亚方, 李改云. 纤维素纳米晶体尺寸控制及其检测技术研究进展. 木材工业, 2015, 29(4), 22-25.

35)   Guo J., Yang L., Zhu L.*, Chen D*. Selective detection of metal ions based on nanocrystalline ionochromic polydiacetylene. Polymer, 2013, 54, 743-749.

36)   Guo J., Chen D. Melamine/stearic acid composite nanowires and vesicles with an intercalated nanostructure prepared through NCCM method. Chinese Journal of Chemical Physics, 2012, 25(6), 708-712.

37)   Guo J., Zhu L., Jiang M., Chen D. Deliberately designed processes to physically tether the carboxyl groups of poly (pentacosadiynoic acid) to poly (vinyl alcohol) glassy matrix to make poly (pentacosadiynoic acid) thermochromically reversible in the matrix. Langmuir, 2011, 27(11), 6651-6660.

38)   Wang J., Gao J., Guo J., Ma L., Jiang X., Yu H., Li J., Hu Y., Daniel G., Yin Y. Dynamic changes of heterogeneous cell wall macromolecules in differentiating conifer xylem using cytochemical localization. International Journal of Biological Macromolecules, 2025, 284, 138150.

39)   Wei Y., Guo J., Sun Y., Wang H., Li X., Jiang X., He T., Yin Y. Breaking the barrier to rapid and non-destructive species-level wood identification using spectroscopy. Microchemical Journal, 2025, 215, 114332.

40)   高鑫，曹惠敏，郭娟，周凡，殷亚方，周永东. 预冻处理对致远舰出水木材干燥特性的影响. 木材科学与技术，2024， 38(6), 8-14.

41)   韩刘杨, 郭娟, 韩向娜, 席光兰, 田兴玲, 李仁, 陈家宝, 殷亚方. 饱水考古木材保存状况评估研究进展. 林业科学, 2024, 60(9), 183-198.

42)   王杰, 马灵玉, 郭娟, 姜笑梅, 殷亚方. 白皮松木质部分化中轴向管胞和射线细胞的微观构造与木质化研究. 木材科学与技术, 2023, 37(2), 16-24.

43)   李莞璐, 李京予, 郭娟, 杨弢, 马尔妮. 古代与现代柏木的水分吸附热力学比较研究. 北京林业大学学报, 2023, 45(4), 126-135.

44)   Lu Y., Jiao L., Sun G., Wang J., Liu S., Li R., Zhang Y., Guo Y., Guo J., Jiang X., Yin Y. Preservation status and microbial community of waterlogged archaeological woods over 7800 years old at the Jingtoushan Site, China. Wood Science & Technology, 2023,57, 537-556.

45)   Cao H., Gao X., Chen J., Xi G., Yin Y., Guo J. Changes in moisture characteristics of waterlogged archaeological wood owing to microbial degradation. Forests, 2023, 14, 9.

46)   王静, 王杰, 郭娟, 冯韵, 李喜霞, 张建国, 姜笑梅, 殷亚方, 李姗. 基于聚焦离子束—扫描电子显微技术的雪松木质部具缘纹孔三维重构. 电子显微学报, 2022, 41(1), 66-71.

47)   何拓, 焦立超, 郭娟, 殷亚方. 木材信息学：发展、应用与展望. 木材科学与技术, 2021, 35(4), 15-24.

48)   Yu M.#, Jiao L.#, Guo J., Wiedenhoeft A. C., He T., Jiang X., Yin Y. DNA barcoding of vouchered xylarium wood specimens of nine endangered Dalbergia species. Planta, 2017, 246, 1165-1176.

49)   He T., Jiao L., Yu M., Guo J., Jiang X., Yin Y.* DNA barcoding authentication for the wood of eight endangered Dalbergia timber species using machine learning approaches. Holzforschung, 2019, DOI: 10.1515/hf-2018-0076

50)   Zhang M., Zhao G., Liu B., He T., Guo J., Jiang X., Yin Y.* Wood discrimination analyses of Pterocarpus tinctorius and endangered Pterocarpus santalinus using DART-FTICR-MS coupled with multivariate statistics. IAWA Journal, 2019, DOI: 10.1163/22941932-40190224

51)   Zhang M., Zhao G., Guo J., Liu B., Jiang X., Yin Y. A GC/MS protocol for separating endangered and non-endangered Pterocarpus wood species. Materials, 2019, 24(4), 799.

52)   Du W., Deng A., Guo J., Li H., Gao Y.* An injectable self-healing hydrogel-cellulose nanocrystals conjugate with excellent mechanical strength and good biocompatibility. Carbohydrate Polymers, 2019, 223, 115084.

53)   Zhang M., Zhao G., Guo J., Wiedenhoeft A.C., Liu C.C. Yin Y.* Timber species identification from chemical fingerprints using direct analysis in real time (DART) coupled to Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS): comparison of wood samples subjected to different treatments. Holzforschung, 2019, 73(11), 975-985.

54)   Shao F., Zhang L., Guo J., Liu X., Ma W., Wilson I., Qiu D.* A comparative metabolomics analysis of the components of heartwood and sapwood in Taxus chinensis (Pilger) Rehd. Scientific Reports, 2019, 9, 17647.

55)   Han L., Guo J., Wang K., Grönquist P., Li R., Tian X., Yin Y.* Hygroscopicity of waterlogged archaeological wood from Xiaobaijiao No.1 shipwreck related to its deterioration state. Polymers, 2020, 12, 834.

56)   Jiao L, Lu Y, Zhang M, Chen Y, Wang Z, Guo Y, Xu C, Guo J, He T, Ma L, Gao W, Wang J, Zhou S, Zhang Y, Jiang X, Baas P, Yin Y. Ancient plastid genomes solve the tree species mystery of the imperial wood “Nanmu” in the Forbidden City, the largest existing wooden palace complex in the world. Plants People Planet, 2022, 1–14. https://doi.org/a10.1002/ppp3.10311

57)   Liu S, He T, Wang J, Chen J, Guo J, Jiang X, Wiedenhoeft AC, Yin Y. Can quantitative wood anatomy data coupled with machine learning analysis discriminate CITES species from their look–alikes? Wood Science and Technology, 2022, https://doi.org/10.1007/s00226-022-01404-y

58)   Zhang M, Guo J, Lu Y, Jiao L, He T, Yin Y. Similarity network fusion for aggregating headspace GC-MS and direct analysis in real time-mass spectrometry data from solid samples to enhance species identification efficiency of high-temperature heated wood. Journal of Wood Science, 2022, 68, 38.

59)   Li R, Guo J, Macchioni N, Pizzo B, Xi G, Tian X, Chen J, Sun J, Jiang X, Cao J, Zhang Z, Yin Y. Characterisation of waterlogged archaeological wood from Nanhai No.1 shipwreck by multidisciplinary diagnostic methods. Journal of Cultural Heritage, 2022, 56, 25–35.

60)   Zhong Y., Wu G., Fu F., Shen Y., Sun J., Ren H., Guo J. A novel constitutive model for the porosity related super‑large deformation and anisotropic behavior of wood under perpendicular to grain compression. Wood Science and Technology, https://doi.org/10.1007/s00226-022-01361-6

61)   尹江苹, 郭娟, 赵广杰, 殷亚方. 湿热-压缩处理木材的纤维素晶体结构变化. 林产工业, 2017, 44(7), 10-14.

罗杰, 赵有科, 郭娟, 王慧芳. 不同压缩率下杉木低分子质量酚醛树脂浸注研究. 西北农林科技大学学报, 2021, 49(7), 50-58.

获奖：

梁希科技进步奖二等奖（排名第二）

文化遗产保护青年学者论坛一等奖

著作：

《考古木材保存状态分析方法》《木材材质改良的物理与化学基础》《木材弱相结构及其失效机制》《现代林产化学工程》《文化遗产研究》《濒危和珍贵热带木材识别图鉴》《常见贸易濒危木材识别图鉴》等

专利：

一种无损鉴别檀香紫檀和染料紫檀木材及其制品的方法

改性纤维素纳米晶体、高强水凝胶材料、制备方法及应用

一种聚丙烯/纤维素插层纳米晶体组合物及其制备方法

一种聚丙烯/纤维素插层纳米晶体母粒、制备方法及其应用

一种利用包埋剂改善木质文物脆裂的徒手切片方法

一种无损快速测定木质文物保存状态的方法

一种饱水木质文物保存状态的快速无损检测方法

一种用于木质文物的微损取样器