[1] Bai Z C, Hao L C, Zhang Z P et al. Enhanced photoluminescence of corrugated Al2O3 film assisted by colloidal CdSe quantum dots[J]. Nanotechnology, 28, 205206(2017).

[2] Fort E, Grésillon S. Surface enhanced fluorescence[J]. Journal of Physics D Applied Physics, 41, 13001(2008).

[3] Li J L, Gu M. Surface plasmonic gold nanorods for enhanced two-photon microscopic imaging and apoptosis induction of cancer cells[J]. Biomaterials, 31, 9492-9498(2010).

[4] Borisov S M, Wolfbeis O S. Optical biosensors[J]. Chemical Reviews, 108, 423-461(2008).

[5] Rizzo R, Alvaro M, Danz N et al. Bloch surface wave enhanced biosensor for the direct detection of Angiopoietin-2 tumor biomarker in human plasma[J]. Biomedical Optics Express, 9, 529(2018).

[6] Zhang W X, Zhang X R, Qin C B et al. Continuous laser induced photoluminescence enhancement of Au nanorods[J]. Laser & Optoelectronics Progress, 56, 202410(2019).

[7] Yang J, Lee J, Lee J Y et al. Photocurrent enhancement of CdSe quantum-dot sensitized solar cells incorporating single-walled carbon nanotubes[J]. Journal of Nanoscience and Nanotechnology, 18, 1347-1350(2018).

[8] Yang J, Park T, Lee J et al. Performance enhancement of 3-mercaptopropionic acid-capped CdSe quantum-dot sensitized solar cells incorporating single-walled carbon nanotubes[J]. Journal of Nanoscience and Nanotechnology, 16, 2710-2714(2016).

[9] Gracie K, Moores M, Smith W E et al. Preferential attachment of specific fluorescent dyes and dyelabeled DNA sequences in a surface enhanced Raman scattering multiplex[J]. Analytical Chemistry, 88, 1147-1153(2016).

[10] Peng M, Bai Z C, Li X J et al. Controlling wide-spectrum fluorescence on Au/ZnSe multi-heterojunction[J]. Applied Physics A, 124, 1-6(2018).

[11] Bai Z C, Hao L C, Huang Z L et al. Enhancement effect of defect fluorescence of ZnSe quantum dots on a heterojuction of ZnSe quantum dots and gold nanoparticles[J]. Methods and Applications in Fluorescence, 5, 045001(2017).

[12] Cheng C, Mao M. Photo-stability and time-resolved photoluminescence study of colloidal CdSe/ZnS quantum dots passivated inAl2O3 using atomic layer deposition[J]. Journal of Applied Physics, 120, 083103(2016).

[13] Zhang Y, Bai Z C, Huang Z L et al. Influence of distance between CdSe quantum dot and gold nanoparticle on system fluorescence[J]. Laser & Optoelectronics Progress, 55, 072601(2018).

[14] [14] Dixit SK, BhatnagarC, KumariA, et al.Development and characterization of PCDTBT: CdSe QDs hybrid solar cell[C]∥AIP Publishing LLC, 2014.

[15] Dayneko S, Tameev A, Tedoradze M et al. Hybrid bulk heterojunction solar cells based on low band gap polymers and CdSe nanocrystals[J]. Proceedings of SPIE, 8981, 898113(2014).

[16] Patel M, Sahu S, Verma A K et al. Solution processed solar cells based onin situ synthesis of CdSe quantum dots[C]∥2017 International Conference on Energy. 1-2 Aug. 2017, Chennai, India., 1683-1687(2017).

[17] Laatar F, Moussa H, Alem H et al. CdSe nanorod/TiO2 nanoparticle heterojunctions with enhanced solar- and visible-light photocatalytic activity[J]. Beilstein Journal of Nanotechnology, 8, 2741-2752(2017).

[18] Chen W W, Yu S, Zhong Y Q et al. Effect of electron transfer on the photocatalytic hydrogen evolution efficiency of faceted TiO2/CdSe QDs under visible light[J]. New Journal of Chemistry, 42, 4811-4817(2018).

[19] Kozlova E A, Kurenkova A Y, Semeykina V S et al. Effect oftitania regular macroporosity on the photocatalytic hydrogen evolution on Cd1-xZnxS/TiO2 catalysts under visible light[J]. ChemCatChem, 7, 4108-4117(2015).

[20] Chatterjee S. Indian Institute of Engineering Science and Technology India, Sarkar J, et al. Effect of anodizing medium on the morphology and photoluminescent property of porous alumina film[J]. GSTF Journal of Engineering Technology, 4, 59-62(2017).

[21] Ismail A K, Ibrahim N H, Shamsuddin K A et al. A practical approach in porous medium combustion for domestic application:a review[J]. IOP Conference Series: Materials Science and Engineering, 370, 012004(2018).

[22] Kim Y M. RheeG H, Ko C H, et al. Catalytic pyrolysis of Korean pine (pinus koraiensis) nut shell over mesoporous Al2O3[J]. Journal of Nanoscience and Nanotechnology, 18, 1351-1355(2018).

[23] Guarnera S. AbateA, Zhang W, et al. Improving the long-term stability of perovskite solar cells with a porous Al2O3 buffer-layer[J]. Journal of Physical Chemistry Letters, 6, 432-437(2015).

[24] Zhang J, Yue D, Xia T F et al. A luminescent metal-organic framework film fabricated on porous Al2O3 substrate for sensitive detecting ammonia[J]. Microporous and Mesoporous Materials, 253, 146-150(2017).

[25] Guo H S, Li W F. Effects of Al2O3 crystal types on morphologies, formation mechanisms of mullite and properties of porous mullite ceramics based on kyanite[J]. Journal of the European Ceramic Society, 38, 679-686(2018).

[26] Rose V. 105(7): 07C902[J]. Franchy R. The band gap of ultrathin amorphous, well-ordered Al₂O₃ films on CoAl, 100, measured by scanning tunneling spectroscopy. Journal of Applied Physics(2009).

[27] Bai Z C, Huang Z L, Hao L C et al. Identifying defects in thin film of high power laser lens by using near field microimaging method[J]. Chinese Journal of Lasers, 44, 0103001(2017).

[28] Bai Z C, Peng M, Zhang Z P et al. Enhanced and broadened fluorescence of ZnSe quantum dots enabled by the fluorescence energy transfer system of ZnSe quantum dots and gold nanoparticles[J]. Applied Optics, 57, 8437-8442(2018).

[29] Murai S, Fujita K, Daido Y et al. Plasmonic arrays of titanium nitride nanoparticles fabricated from epitaxial thin films[J]. Optics Express, 24, 1143-1153(2016).

[30] Naik G V, Schroeder J, Ni XJ et al. Titanium nitride as a plasmonic material for visible and near-infrared wavelengths[J]. Optical Materials Express, 3, 1658-1659(2012).

[31] Zgrabik C M, Hu E L. Optimization of sputtered titanium nitride as a tunable metal for plasmonic applications[J]. Optical Materials Express, 5, 2786-2797(2015).

[32] Jaramillo-Quintero O A, Triana M A, Rincon M E. Optimization of charge transfer and transport processes at the CdSe quantum dots/TiO2 nanorod interface by TiO2 interlayer passivation[J]. Journal of Physics D: Applied Physics, 50, 235305(2017).

[33] Naldoni A, Guler U, Wang Z X et al. Broadband hot-electron collection for solar water splitting with plasmonic titanium nitride[J]. Advanced Optical Materials, 5, 1601031(2017).

[34] Zhao Y, Song Z M, Jin J B et al. Electrochemical corrosion properties of Ti-5%TiN composites formed by selective laser melting in hank's solution[J]. Chinese Journal of Lasers, 46, 0902005(2019).

[35] Avasarala B, Haldar P. Durability and degradation mechanism of titanium nitride based electrocatalysts for PEM (proton exchange membrane) fuel cell applications[J]. Energy, 57, 545-553(2013).

[36] Gao L, Gstöttner J, Emling R et al. Thermal stability of titanium nitride diffusion barrier films for advanced silver interconnects[J]. Microelectronic Engineering, 76, 76-81(2004).

[37] Endres R, Krauss T, Wessely F et al. Damascene metal gate technology for damage-free gate-last high-k process integration[C]∥2009 3rd International Conference on Signals. 6-8 Nov. 2009, Medenine, Tunisia., 1-3(2009).

[38] Hao L, Bai Z, Qin S et al. The effect of differential temperatures on the latent heat in the nucleation of CdSe quantum dots[J]. Journal of Semiconductors, 38, 042004(2017).

[39] Bai Z C, Hao L C, Zhang Z P et al. Measuring photoluminescence spectra of self-assembly array nanowire of colloidal CdSe quantum dots using scanning near-field optics microscopy[J]. Functional Materials Letters, 09, 1650040(2016).

[40] Guo Y, He X, Liu X et al. One-step implementation of plasmon enhancement and solvent annealing effects for air-processed high-efficiency perovskite solar cells[J]. Journal of Materials Chemistry, 6, 24036-24044(2018).