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SCIENTIA SINICA Chimica, Volume 50 , Issue 3 : 324-336(2020) https://doi.org/10.1360/SSC-2019-0157

Research progress in the latent fingerprint development based on electrochemical methods

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  • ReceivedDec 2, 2019
  • AcceptedJan 2, 2020
  • PublishedFeb 28, 2020

Abstract


Funding

国家自然科学基金(21802169,21205139)

公安部科技强警基础工作专项项目(2018GABJC09,2018GABJC07)

辽宁省博士科研启动基金指导计划(20170520204)

痕迹检验鉴定技术公安部重点实验室开放课题(2018121713,2018121704)


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  • Figure 1

    The principle of fingerprint development based on the electrochemical deposition (color online).

  • Figure 2

    Sebaceous fingerprints on different metallic substrates developed by the co-electrodeposition of Cu-Ag alloy. (a) Magnesium sheet, (b) aluminum sheet, (c) zinc sheet and (d) copper sheet [18] (color online).

  • Figure 3

    Enhancement of a sebaceous fingerprint on a stainless steel sheet developed by the electrodeposition of polyaniline: in 1 mol/L H2SO4 solution, the images captured at the applied potential (vs. saturated calomel electrode (SCE)) of −0.2 V (a), 0.3 V (b) and 0.9 V (c), respectively [22] (color online).

  • Figure 4

    (a) The principle of fingerprint development based on the Ru(bpy)32+/TPrA ECL system; developed sebaceous fingerprints on the surface of (b) ITO [35] and (c) the stainless steel [36] (color online).

  • Figure 5

    (a) The principle of fingerprint development based on the Ru(bpy)2(dcbpy)NHS/DBAE ECL system. Developed fingerprints on the ITO after the incubation with Ru(bpy)2(dcbpy)NHS for 1 h: (b) photoluminescence image and (c) ECL image [35] (color online).

  • Figure 6

    The principle of fingerprint development using ECLLIA methods: single-HRP route and multiple-HRP route (color online).

  • Figure 7

    Target analytes for the development of eccrine fingerprints using ECLLIA methods: (a) dermcidin, (b) EGF and (c) lysozyme; Development of eccrine fingerprints using a single-HRP route for the detection of (a′) dermcidin, (b′) EGF and (c′) lysozyme; Development of eccrine fingerprints using a multiple-HRP route for the detection of (a″) dermcidin, (b″) EGF and (c″) lysozyme [39] (color online).

  • Figure 8

    Schematic diagrams of the apparatus (a) and the feedback mode (b) of SECM.

  • Figure 9

    Schematic diagrams illustrating the principles of fingerprint development using SECM: (a) silver stained fingerprints and (b) benzoquinone tagged fingerprints. Insets show enlarged views of developed fingerprints (color online).

  • Figure 10

    The principles of fingerprint enhancement using SCEM: fingerprints developed by (a) MMD methods and (b) VMD methods. Insets show enlarged views of enhanced fingerprints (color online).

  • Figure 11

    Schematic diagrams of SKPM apparatus.

  • Figure 12

    (a) SKPM sample holder arrangement used to scan cartridge cases; (b) latent fingerprints deposited on a post-fired 0.45 inch caliber cartridge case; (b′) the image of a selected region in (b) developed by SKPM; (c) a fired 9 mm short caliber casing bearing a latent fingerprint before firing; (c′) the image of a selected region in (c) developed by SKPM [68,69] (color online).

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