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Publishing Language: Chinese

Experimental study and mechanism analysis on the effect of crystallographic orientation on triboluminescence

Na LIXuefeng XU( )
School of Technology, Beijing Forestry University, Beijing 100083, China
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Abstract

Triboluminescence has been investigated by many researchers due to its many applications in various fields related to industry and life. However, the triboluminescence mechanism is still unclear. The triboluminescence mechanisms are further investigated here by experimentally studying the triboluminescence properties of SiO2 crystals with various crystal orientations. The experimental results show that the crystal orientation significantly affects the triboluminescence. Measurements of the triboluminescence spectra showed that the triboluminescence comes from the gas discharge caused by triboelectrification. The different triboluminescence intensities in different crystal orientations are then shown to be based on the differences in the work functions for different orientations.

Keywords

crystallographic orientationlight intensitytriboluminescencelight spectrum
CLC number: TH117.1 Document code: A Article ID: 1000-0054(2022)03-0470-06

References

[1]

WALTON A J. Triboluminescence[J]. Advances in Physics, 1977, 26(6): 887-948.
Crossref Google Scholar
[2]

MEI Z X, ZHANG X Q, YAO Z G, et al. Study on the triboluminescent property of ZnS: Mn[J]. Spectroscopy and Spectral Analysis, 2001, 21(6): 766-768. (in Chinese)
Crossref Google Scholar
[3]

MONETTE Z, KASAR A K, MENEZES P L. Advances in triboluminescence and mechanoluminescence[J]. Journal of Materials Science: Materials in Electronics, 2019, 30(22): 19675-19690.
Crossref Google Scholar
[4]

ZHANG J C, WANG X S, MARRIOTT G, et al. Trap-controlled mechanoluminescent materials[J]. Progress in Materials Science, 2019, 103: 678-742.
Crossref Google Scholar
[5]

SAGE I C, BOURHIL G. Triboluminescent materials for structural damage monitoring[J]. Journal of Materials Chemistry, 2001, 11(2): 231-245.
Crossref Google Scholar
[6]

OLAWALE D O, DICKENS T, SULLIVAN W G, et al. Progress in triboluminescence-based smart optical sensor system[J]. Journal of Luminescence, 2011, 131(7): 1407-1418.
Crossref Google Scholar
[7]

KNEIP S. A stroke of X-ray[J]. Nature, 2011, 473(7348): 455-456.
Crossref Google Scholar
[8]

HERNÁNDEZ-HERNÁNDEZ M C, ESCOBAR J V. The true spectrum of tribo-generated X-rays from peeling tape[J]. Applied Physics Letters, 2019, 115(20): 201605.
Crossref Google Scholar
[9]

XU B J, HE J J, MU Y X, et al. Very bright mechanoluminescence and remarkable mechanochromism using a tetraphenylethene derivative with aggregation-induced emission[J]. Chemical Science, 2015, 6(5): 3236-3241.
Crossref Google Scholar
[10]

KWAK S Y, YANG S, KIM N R, et al. Thermally stable, dye-bridged nanohybrid-based white light-emitting diodes[J]. Advanced Materials, 2011, 23(48): 5767-5772.
Crossref Google Scholar
[11]

TERASAKI N, ZHANG H W, YAMADA H, et al. Mechanoluminescent light source for a fluorescent probe molecule[J]. Chemical Communications, 2011, 47(28): 8034-8036.
Crossref Google Scholar
[12]

CHANDRA B P, ZINK J I. Triboluminescence and the dynamics of crystal fracture[J]. Physical Review B, 1980, 21(2): 816-826.
Crossref Google Scholar
[13]

CHAKRAVARTY A, PHILLIPSON T E. Triboluminescence and the potential of fracture surfaces[J]. Journal of Physics D: Applied Physics, 2004, 37(15): 2175-2180.
Crossref Google Scholar
[14]

TEKALUR S A. Triboluminescence in sodium chloride[J]. Journal of Luminescence, 2010, 130(11): 2201-2206.
Crossref Google Scholar
[15]

KOBAKHIDZE L, GUIDRY C J, HOLLERMAN W A, et al. Detecting mechanoluminescence from ZnS: Mn powder using a high speed camera[J]. IEEE Sensors Journal, 2013, 13(8): 3053-3059.
Crossref Google Scholar
[16]

SHI Y W, SHI Y D, XIE Q. Flexible 2D graphene-coupled ZnS: Mn2+ mechanodetectors for heart rate monitoring[J]. Journal of Luminescence, 2020, 226: 117441.
Crossref Google Scholar
[17]

BREWER J D, JEFFRIES B T, SUMMERS G P. Low-temperature fluorescence in sapphire[J]. Physical Review B, 1980, 22(10): 4900-4906.
Crossref Google Scholar
[18]

HIRD J R, CHAKRAVARTY A, WALTON A J. Triboluminescence from diamond[J]. Journal of Physics D: Applied Physics, 2007, 40(5): 1464-1472.
Crossref Google Scholar
[19]

WANG K, MA L, XU X, et al. Triboluminescence dominated by crystallographic orientation[J]. Scientific Report, 2016, 6: 26324.
Crossref Google Scholar
[20]

SONG C H, WANG K F, SANG X, et al. Tribo-induced near-infrared light emission between metal and quartz[J]. Langmuir, 2020, 36(5): 1165-1173.
Crossref Google Scholar
[21]

COLAK S B, VAN DER MARK M B, HOOFT G W T, et al. Clinical optical tomography and NIR spectroscopy for breast cancer detection[J]. IEEE Journal of Selected Topics in Quantum Electronics, 1999, 5(4): 1143-1158.
Crossref Google Scholar
[22]

HE F, YANG G X, YANG P P, et al. A new single 808 nm NIR light-induced imaging-guided multifunctional cancer therapy platform[J]. Advanced Functional Materials, 2015, 25(25): 3966-3976.
Crossref Google Scholar
[23]

LI N, MA L R, XU X F, et al. Charge transfer dynamics in contact electrification of dielectrics investigated by triboluminescence[J]. Journal of Luminescence, 2020, 227: 117531.
Crossref Google Scholar
[24]

XU C, ZHANG B B, WANG A C, et al. Effects of metal work function and contact potential difference on electron thermionic emission in contact electrification[J]. Advanced Functional Materials, 2019, 29(29): 1903142.
Crossref Google Scholar
[25]

LIN S Q, XU L, XU C, et al. Electron transfer in nanoscale contact electrification: Effect of temperature in the metal-dielectric case[J]. Advanced Materials, 2019, 31(17): 1808197.
Crossref Google Scholar
[26]

LIN S Q, XU L, ZHU L P, et al. Electron transfer in nanoscale contact electrification: Photon excitation effect[J]. Advanced Materials, 2019, 31(27): 1901418.
Crossref Google Scholar
[27]

NAKAYAMA K, NEVSHUPA R A. Characteristics and pattern of plasma generated at sliding contact[J]. Journal of Tribology, 2003, 125(4): 780-787.
Crossref Google Scholar
[28]

PEARSE R W B, GAYDON A G. The identification of molecular spectra[M]. London: Chapman & Hall, 1965.
[29]

HARPER W R. The volta effect as a cause of static electrification[J]. Proceeding of the Royal Society A: Mathematical, Physical and Engineering Sciences, 1951, 205(1080): 83-103.
Crossref Google Scholar
[30]

HARPER W R. Contact and frictional electrification[M]. London: Oxford University Press, 1967.
[31]

LOWELL J, ROSE-INNES A C. Contact electrification[J]. Advances in Physics, 1980, 29(6): 947-1023.
Crossref Google Scholar
[32]

MATSUSAKA S, MARUYAMA H, MATSUYAMA T, et al. Triboelectric charging of powders: A review[J]. Chemical Engineering Science, 2010, 65(22): 5781-5807.
Crossref Google Scholar
[33]

DUCK C B, FABISH T J. Contact electrification of polymers: A quantitative model[J]. Journal of Applied Physics, 1978, 49(1): 315-321.
Crossref Google Scholar
[34]

SHEN X Z, WANG A E, SANKARAN R M, et al. First-principles calculation of contact electrification and validation by experiment[J]. Journal of Electrostatics, 2016, 82: 11-16.
Crossref Google Scholar
[35]

STERNOVSKY Z, HORÁNYI M, ROBERTSON S. Charging of dust particles on surfaces[J]. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 2001, 19(5): 2533-2541.
Crossref Google Scholar
[36]

MURASHOV V V, DEMCHUK E. Surface sites and unrelaxed surface energies of tetrahedral silica polymorphs and silicate[J]. Surface Science, 2005, 595(1-3): 6-19.
Crossref Google Scholar
[37]

MURASHOV V V. Reconstruction of pristine and hydrolyzed quartz surfaces[J]. Journal of Physical Chemistry B, 2005, 109(9): 4144-4151.
Crossref Google Scholar
[38]

SCHLEGEL M L, NAGY K L, FENTER P, et al. Structures of quartz(100)- and (101)-water interfaces determined by X-ray reflectivity and atomic force microscopy of natural growth surfaces[J]. Geochimica et Cosmochimica Acta, 2002, 66(17): 3037-3054.
Crossref Google Scholar
[39]

ZENG X M, OUYANG C Y, LEI M S. First-principles investigation of the surface energy and work function of noble metal Co、Rh、Ir[J]. Journal of Jiangxi Normal University (Natural Science), 2010, 34(4): 340-345. (in Chinese)
Crossref Google Scholar
[40]

SKRIVER H L, ROSENGAARD N M. Surface energy and work function of elemental metals[J]. Physical Review B, 1992, 46(11): 7157-7168.
Crossref Google Scholar
Journal of Tsinghua University (Science and Technology)
Volume 62 Issue 3,
March 2022
Pages 470-475
DOI: 10.16511/j.cnki.qhdxxb.2021.25.019
Cite this article:
LI N, XU X. Experimental study and mechanism analysis on the effect of crystallographic orientation on triboluminescence. Journal of Tsinghua University (Science and Technology), 2022, 62(3): 470-475. https://doi.org/10.16511/j.cnki.qhdxxb.2021.25.019

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Received: 05 January 2021
Published: 15 March 2022
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