基于聚集诱导发光材料的潜指印光学显现技术研究进展

doi:10.11949/0438-1157.20250450

化工学报 ›› 2025, Vol. 76 ›› Issue (12): 6236-6257.DOI: 10.11949/0438-1157.20250450

基于聚集诱导发光材料的潜指印光学显现技术研究进展

梁帅¹^,²(), 高树辉¹(), 闫永丽³, 王贵容¹, 屈音璇¹

^1.中国人民公安大学侦查学院，北京 100038
^2.天津公安警官职业学院，天津 300000
^3.中国科学院化学研究所光化学实验室，北京 100190

收稿日期:2025-04-28 修回日期:2025-06-12 出版日期:2025-12-31 发布日期:2026-01-23
通讯作者: 高树辉
作者简介:梁帅（1989—），男，博士研究生，副教授，15320186705@163.com
基金资助:
中央高校基本科研业务费项目(2023JKF01ZK11);国家重点研发计划(2023YFC3303700);天津公安警官职业学院科研项目(JYKT-202505);天津公安警官职业学院科研项目(JYDY-202514)

Research progress of latent fingerprint optical visualization technology based on aggregation induced emission materials

Shuai LIANG¹^,²(), Shuhui GAO¹(), Yongli YAN³, Guirong WANG¹, Yinxuan QU¹

^1.School of Investigation, People’s Public Security University of China, Beijing 100038, China
^2.TianJin Public Security Profession College, Tianjin 450000, China
^3.Laboratory of Photochemistry, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, China

Received:2025-04-28 Revised:2025-06-12 Online:2025-12-31 Published:2026-01-23
Contact: Shuhui GAO

摘要/Abstract

摘要：

潜指印的显现和提取是法庭科学领域的关键技术之一，传统方法在显现效率、三级特征清晰度、适用客体范围及生物兼容性等方面存在诸多局限。聚集诱导发光（AIE）材料因其独特光学特性为该领域提供了新思路。系统综述AIE材料（AIEgens）的发光机制及其在潜指印光学显现中的应用进展，涵盖覆盖350～750 nm波段的激光增益材料开发及微网雾化技术实践。重点阐释基于分子内运动受限机制的AIE显现机理，并从作用机制、发光模式与显现方法三方面评述应用现状。同时分析当前研究的局限，并展望指纹评价标准体系完善、显现性能提升及技术创新等发展趋势，为潜指印原位可视化、痕量物质检测及生物检材无损提取提供理论依据与技术参考。

关键词: 聚集诱导发光, 纳米材料, 电化学, 成像, 光致发光, 潜指印

Abstract:

The visualization and extraction of latent fingerprints is a key technology in forensic science. Traditional methods have many limitations in terms of visualization efficiency, tertiary feature clarity, applicable object range, and biocompatibility. Aggregation-induced emission (AIE) materials, offering unique optical properties, have provided new perspectives for this field. This review systematically summarizes the luminescence mechanisms of AIEgens and their application progress in the optical visualization of latent fingerprints. It encompasses the development of laser gain materials covering the 350—750 nm wavelength range and the practical implementation of micro-mesh nebulization technology. The review highlights the AIE-based visualization mechanism grounded in the restriction of intramolecular motion. It further critically assesses the current application status from three key aspects: the underlying interaction mechanisms, luminescence modes, and visualization methodologies. Concurrently, limitations in current research are analyzed. Future development trends are also prospected, including the establishment of standardized fingerprint evaluation systems, enhancement of visualization performance, and innovation in technical approaches. This work aims to provide theoretical and technical foundations for the in-situ visualization of latent fingerprints, trace substance detection, and non-destructive extraction of biological evidence.

Key words: aggregation-induced emission, nanomaterials, electrochemistry, imaging, photoluminescence, latent fingerprints

中图分类号:

TQ 422

梁帅, 高树辉, 闫永丽, 王贵容, 屈音璇. 基于聚集诱导发光材料的潜指印光学显现技术研究进展[J]. 化工学报, 2025, 76(12): 6236-6257.

Shuai LIANG, Shuhui GAO, Yongli YAN, Guirong WANG, Yinxuan QU. Research progress of latent fingerprint optical visualization technology based on aggregation induced emission materials[J]. CIESC Journal, 2025, 76(12): 6236-6257.

图/表 27

图1 AIEgens类别及结构示意图[26-37]

Fig.1 AIEgens classification and structure formula[26-37]

图2 Jablonski能级图[38]

Fig.2 Jablonski energy level diagram[38]

图3 荧光、磷光、延迟荧光的发光机理示意图

Figs.3 Luminescence mechanism of material fluorescence, phosphorescence and delayed fluorescence

图4 AIE材料的发光过程示意图[40]

Fig.4 Luminescence process of AIE materia[40]

图5 不同激光增益材料及化学结构示意图

Fig.5 Schematic diagram of different laser gain materials and their chemical structures

表1 潜指印组成物质主要成分、含量及部分物质的化学结构［51-52］

Table 1 Main components and their contents in latent fingerprint residues and chemical structures of some substances［51-52］

指印分泌物质	成份	化学结构
外分泌汗腺（汗液）	有机物：蛋白质、多肽（200mg/L）葡萄糖（3.5mg/L）乳酸（3.15mg/L）；氨基酸（1.45mg/L）尿素（2mg/L）丙酮酸（2mg/L）
外分泌汗腺（汗液）	无机物：水（98%~99%）氯离子（3.5g/L）钠离子（3.3g/L钾离子（0.2g/L）镁离子（0.04g/L）铁离子（3.5mg/L）钙离子（2mg/L）碳酸氢盐（107mg/L）硫酸盐（10mg/L）磷酸盐（1.4mg/L）
皮脂腺（脂质）	游离脂肪酸（37.6％）甘油三脂、胆固醇脂（25％）蜡脂（21％）角鲨烯（14.6％）胆固醇（3.8％）
顶分泌汗腺	有机物：蛋白质、胆固醇、类固醇无机物：铁	—

图6 不同物理吸附性能的粉末显现指印的效果及其扫描电镜图像[55-56]

Fig.6 Fingerprint development effect and SEM images of powders with different physical adsorption properties[55-56]

图7 基于静电吸附作用AIE试剂显现过程及机理验证[57-58]

Fig.7 Development process and mechanism verification of electrostatic adsorption-induced AIE reagent[57-58]

图8 HPS、MCSTPS化学结构及成像效果对比图[59]

Fig.8 Comparison diagram of chemical structures and imaging performance between HPS and MCSTPS[59]

图9 探针Zn(tpy-NMe2)在水溶液中与不同物质作用的荧光照片(a)（λex = 365 nm）；探针Zn(tpy-NMe2)和油酸的混合物中分离得到化合物的高分辨质谱(b)；探针Zn(tpy-NMe2)对潜指纹显色的可能机理示意图(c)[61]

Fig.9 Fluorescence images of probe Zn(tpy-NMe2) interacting with different substances in aqueous solution (a) (λex = 365 nm); High-resolution mass spectrum of the compound isolated from the mixture of probe Zn(tpy-NMe2) and oleic acid (b); Proposed mechanism diagram for latent fingerprint visualization by probe Zn(tpy-NMe2) (c) [61]

图10 基于普通发光模式的指印显现

Fig.10 Latent fingerprint development based on conventional luminescence mode

图11 不同电子取代基的AIE化学结构及不同发射波长（荧光颜色）的指印图像 [61,64]

Fig.11 AIE chemical structures with different electron-donating substituents and fingerprint images at varying emission wavelengths [61,64]

图12 基于“时间分辨”发光模式的指印显现

Fig.12 Latent fingerprint development based on “Time resolved” luminous mode

图13 不同卤素取代基的DMAc化学结构(a)、荧光寿命(b)、发光机理(c)及DMAc Br显出的荧光图像（d）[68]

Fig.13 DMAc chemical structure(a), fluorescence lifetime(b), luminescence mechanism of different halogen substituents(c) and fluorescence images of DMAc Br(d)[68]

图14 不同时间分辨特性AIE材料显现指印的荧光图像[69-70]

Fig.14 Fluorescence images of fingerprints developed by AIE materials with different time-resolved characteristics[69-70]

图15 TPE-DPA的化学结构、显现过程、机理及效果示意图[71]

Fig.15 Chemical structure, developing process, mechanism and effect of TPE-DPA[71]

图16 LHS的组装及化学结构(a)、显现机理(b)及效果示意图(c)[73]

Fig.16 Schematic diagram of the assembly and chemical structure of LHS(a), as well as the development mechanism(b) and effects(c)[73]

图17 部分溶液法AIE显出指印试剂的结构图及成像效果图[75-77,79-82,85,88-91,93-94]

Fig.17 Structure diagram and imaging effect diagram of partial AIE solution reagent[75-77,79-82,85,88-91,93-94]

图18 TPE吡啶盐显现指印机理、操作方法（喷洒、浸泡）(a)及显现效果(b)示意图[79]

Fig.18 Schematic diagram of fingerprint development mechanism, operational procedure(spraying, immersion) (a) and visualization effects(b) of TPE pyridinium salts[79]

图19 LFP-Yellow和LFP-Red显现指印机理、操作方法（雾化）(a)及显现效果(b)示意图[92]

Fig.19 Schematic diagram of fingerprint development mechanism, operational procedure(atomization) (a) and visualization effects(b) of LFP-Yellow, LFP-Red[92]

图20 BTPE-Sin化合物的合成(a)、显现指印操作方法（滴涂）(b)及效果示意图(c)[94]

Fig.20 Schematic diagram of synthesis of BTPE-Sin compound(a), fingerprint development procedure(drop-coating)(b) and visualization(c)[94]

图21 NIFA试剂结构(a)、发光机理(b)、显现流程(c)及成像效果(d)示意图[95]

Fig.21 Schematic diagram of NIFA reagent structure(a), luminescence mechanism(b), development procedure(c) and imaging results(d)[95]

表2 AIE显现指印研究

Table 2 Overview of fingerprint development of AIE

λ_Ex/nm	操作方法	显现效果	性能验证	指印质量评价	文献
365	刷显	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	灰度分析法	[71]
365	刷显	三级特征，无背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[73]
365	浸泡、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	灰度分析法、特征标划法、系统特征匹配法	[75-77]
365	浸泡/喷涂	三级特征，有背景荧光干扰	指印样本未裁切，常见客体适用、稳定性、安全性、对比度、灵敏度、选择性研究	灰度分析法特征标划法	[79]
365	浸泡、冲洗	二级特征，有背景荧光干	指印样本未裁切，仅非渗透性客体适用研究，老化指纹显现研究	特征标划法	[80]
365	浸泡、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[81]
365	滴涂	三级特征，有背景荧光干扰	指印样本未裁切，常见客体适用性研究	特征标划法人工特征匹配法	[82]
365	浸泡、冲洗	三级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[85]
365	喷洒	三级特征，无背景荧光干扰	指印样本未裁切，常见客体适用研究，老化指纹显现研究	灰度分析法特征标划法	[88]
365	滴涂	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征观察法	[89]
365	浸泡	三级特征，有背景荧光干扰	指印样本未裁切，非渗透性客体适用研究，老化指纹显现研究，灵敏度研究	灰度分析法、特征标划法、人工特征匹配法	[90]
365	喷洒	三级特征，有背景荧光干扰	指印样本未裁切，非渗透性客体适用、客体表面磨损干扰研究	特征标划法	[91]
445	雾化	三级特征，有背景荧光干扰	指印样本未裁切，非渗透性客体适用、快速性、接触DNA 影响研究	特征标划法	[92]
365	浸泡/雾化	三级特征，有背景荧光干扰	指印样本未裁切，常见客体适用，水中指纹、老化指纹显现研究	灰度分析法、特征标划法、人工特征匹配法	[93]
365	滴涂、冲洗	二级特征，部分三级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[94]
365	浸泡、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	灰度分析法、特征标划法、系统特征匹配法	[75]
365	熏显、滴涂、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[95]

表2 AIE显现指印研究

Table 2 Overview of fingerprint development of AIE

λ_Ex/nm	操作方法	显现效果	性能验证	指印质量评价	文献
365	刷显	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	灰度分析法	[71]
365	刷显	三级特征，无背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[73]
365	浸泡、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	灰度分析法、特征标划法、系统特征匹配法	[75-77]
365	浸泡/喷涂	三级特征，有背景荧光干扰	指印样本未裁切，常见客体适用、稳定性、安全性、对比度、灵敏度、选择性研究	灰度分析法特征标划法	[79]
365	浸泡、冲洗	二级特征，有背景荧光干	指印样本未裁切，仅非渗透性客体适用研究，老化指纹显现研究	特征标划法	[80]
365	浸泡、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[81]
365	滴涂	三级特征，有背景荧光干扰	指印样本未裁切，常见客体适用性研究	特征标划法人工特征匹配法	[82]
365	浸泡、冲洗	三级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[85]
365	喷洒	三级特征，无背景荧光干扰	指印样本未裁切，常见客体适用研究，老化指纹显现研究	灰度分析法特征标划法	[88]
365	滴涂	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征观察法	[89]
365	浸泡	三级特征，有背景荧光干扰	指印样本未裁切，非渗透性客体适用研究，老化指纹显现研究，灵敏度研究	灰度分析法、特征标划法、人工特征匹配法	[90]
365	喷洒	三级特征，有背景荧光干扰	指印样本未裁切，非渗透性客体适用、客体表面磨损干扰研究	特征标划法	[91]
445	雾化	三级特征，有背景荧光干扰	指印样本未裁切，非渗透性客体适用、快速性、接触DNA 影响研究	特征标划法	[92]
365	浸泡/雾化	三级特征，有背景荧光干扰	指印样本未裁切，常见客体适用，水中指纹、老化指纹显现研究	灰度分析法、特征标划法、人工特征匹配法	[93]
365	滴涂、冲洗	二级特征，部分三级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[94]
365	浸泡、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	灰度分析法、特征标划法、系统特征匹配法	[75]
365	熏显、滴涂、冲洗	二级特征，有背景荧光干扰	指印样本未裁切，仅非渗透性客体适用研究	特征标划法	[95]

图22 AIE试剂结合微网雾化技术方法（AIE-AT）[96]

Fig.22 AIE reagent combined with micro-mesh nebulization technology (AIE-AT)[96]

图23 AIE-AT方法显现指印性能研究 [96]

Fig.23 Performance study of AIE-AT method for fingerprint development[96]

图24 AIE-AT对A4纸上连续捺印指印的显现成像效果（A）油墨捺印指印（指纹左上角数字表示捺印次数）[97]

Fig.24 Development results of sequentially stamped fingerprints on A4 paper using AIE-AT(A) Ink-stamped fingerprints (numbers in upper left corner indicate stamping sequence)[97]

图25 AIE-AT方法显现指印性能研究 [96]

Fig.25 Performance study of AIE-AT method for fingerprint development [96]

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基于聚集诱导发光材料的潜指印光学显现技术研究进展

Research progress of latent fingerprint optical visualization technology based on aggregation induced emission materials

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