[1] ANGELOPOULOU M, PETROU P, KAKABAKOS S. Advances in interferometric sensors for the detection of food contaminants[J]. Trends in Analytical Chemistry, 175, 117714(2024).

[2] KURIHARA Y, SAWAZUMI T, TAKEUCHI T. Exploration of interactions between membrane proteins embedded in supported lipid bilayers and their antibodies by reflectometric interference spectroscopy-based sensing[J]. Analyst, 139, 6016-6021(2014).

[3] SU Qianqian, SUN Yu, TANG Yanhua et al. Measurement of enzyme activity of insoluble substrates based on ordered porous layer interferometry and the application in evaluation of thrombolytic drugs[J]. Analyst, 149, 1537-1547(2024).

[4] HUANG Weihua, TU Zhengqian, DI Zixiang et al. Large-area thickness measurement of transparent films based on a multichannel spectral interference sensor[J]. Applied Sciences, 14, 2816(2024).

[5] CHU B Y, CHUI H C, HSU C R et al. Characteristic resonance reflection spectra of nanoporous alumina films and its application to precise thickness measurement[J]. ECS Journal of Solid State Science and Technology, 6, N92-N96(2017).

[6] KUMERIA T, LOSIC D. Reflective interferometric gas sensing using nanoporous Anodic Aluminium Oxide (AAO)[J]. Physica Status Solidi, 5, 406-408(2011).

[7] ALVAREZ S D, LI C P, CHIANG C E et al. A label-free porous alumina interferometric immunosensor[J]. Acs Nano, 3, 3301-3307(2009).

[8] VELASCO G M N. Optical biosensors for probing at the cellular level: a review of recent progress and future prospects[J]. Seminars in Cell & Developmental Biology, 20, 27-33(2009).

[9] FENG Silu, JI Weiwei. Advanced nanoporous anodic alumina-based optical sensors for biomedical applications[J]. Frontiers in Nanotechnology, 3, 678275(2021).

[10] BRECHT A, GAUGLITZ G, POLSTER J. Interferometric immunoassay in a FIA-system: a sensitive and rapid approach in label-free immunosensing[J]. Biosensors and Bioelectronics, 8, 387-392(1993).

[11] LI Wenhao, JIA Pinggang, WANG Jun et al. High sensitivity micro fiber fabry perot pressure sensor based on silicon MEMS technology[J]. Acta Photonica Sinica, 53, 0553110(2024).

[12] SANTOS A, KUMERIA T, LOSIC D. Nanoporous anodic aluminum oxide for chemical sensing and biosensors[J]. Trends in Analytical Chemistry, 44, 25-38(2013).

[13] GU Chenglu, WANG Zhiqiang, PAN Yawen et al. Tungsten-based nanomaterials in the biomedical field: a bibliometric analysis of research progress and prospects[J]. Advanced Materials, 35, 2204397(2023).

[14] RETHINASABAPATHY M, GHOREISHIAN S M, HWANG S K et al. Recent progress in functional nanomaterials towards the storage, separation, and removal of tritium[J]. Advanced Materials, 35, 2301589(2023).

[15] LETANT S E, SAILOR M J. Molecular identification by time-resolved interferometry in a porous silicon film[J]. Advanced Materials, 13, 335-338(2001).

[16] COLLINS B E, DANCIL K P S, ABBI G et al. Determining protein size using an electrochemically machined pore gradient in silicon[J]. Advanced Functional Materials, 12, 187-191(2002).

[17] PACHOLSKI C, SARTOR M, SAILOR M J et al. Biosensing using porous silicon double-layer interferometers: reflective interferometric Fourier transform spectroscopy[J]. Journal of the American Chemical Society, 127, 11636-11645(2005).

[18] WU Feng, SU Qianqian, ZHOU Lele et al. Monitoring of binding affinity between drugs and human serum albumin using reflectometric interference spectroscopy with silica colloidal crystal films[J]. Nano, 16, 2150052(2021).

[19] WU Qingqing, WANG Kaige, SUN Dan et al. Pairing mismatched ssDNA to dsDNA studied with reflectometric interference spectroscopy sensor[J]. Chinese Physics Letters, 33, 088701(2016).

[20] MACIAS G, HERNANDEZ E L P, FERRE B J et al. Gold-coated ordered nanoporous anodic alumina bilayers for future label-free interferometric biosensors[J]. ACS Applied Materials & Interfaces, 5, 8093-8098(2013).

[21] LIM S Y, LAW C S, TRAN K N et al. Engineering nanoporous anodic alumina bilayered interferometers for liquid and gas sensing[J]. ACS Applied Nano Materials, 6, 20954-20969(2023).

[22] TABRIZI M A, FERRE B J, MARSAL L F. Remote sensing of Salmonella-specific DNA fragment by using nanoporous alumina modified with the single-strand DNA probe[J]. Sensors and Actuators B: Chemical, 304, 127302(2020).

[23] LAW C S, SANTOS A, KUMERIA T et al. Engineered therapeutic-releasing nanoporous anodic alumina-aluminum wires with extended release of therapeutics[J]. ACS Applied Materials & Interfaces, 7, 3846-3853(2015).

[24] SANTOS A, KUMERIA T, LOSIC D. Nanoporous anodic alumina: a versatile platform for optical biosensors[J]. Materials, 7, 4297-4320(2014).

[25] TANG Y, ZHEN L, LIU J et al. Rapid antibiotic susceptibility testing in a microfluidic pH sensor[J]. Analytical Chemistry, 85, 2787-2794(2013).

[26] HAO Bojuan, WANG Kaige, ZHOU Yukun et al. Label-free detecting of the compaction and decompaction of ctDNA molecules induced by surfactants with SERS based on a nanoPAA-ZnCl2-AuLs solid substrate[J]. ACS Omega, 5, 1109-1119(2020).

[27] SUI Chaofan, WANG Kaige, WANG Shuang et al. SERS activity with tenfold detection limit optimization on a type of nanoporous AAO-based complex multilayer substrate[J]. Nanoscale, 8, 5920-5927(2016).

[28] ZHOU Y K, DANG Y, WANG K G et al. A stable nanoPAA-ZnO/ZnCl2 composite with variable 3D structured morphology and sustained superhydrophilicity[J]. Langmuir, 37, 5457-5463(2021).

[29] LU Yao, SUN Dan, WANG Kaige et al. Label-free detecting oligonucleotide hybridization melting temperature in real-time with a reflectometric interference spectroscopy–based nanosensor system[J]. Optik, 192, 162903(2019).

[30] JEONG C, JUNG J, SHEPPARD K et al. Control of the nanopore architecture of anodic alumina via stepwise anodization with voltage modulation and pore widening[J]. Nanomaterials, 13, 342(2023).

[31] NOREK M. Self-ordered porous anodic alumina with large pore intervals: review on experimental and theoretical research[J]. Journal of The Electrochemical Society, 169, 123503(2022).

[32] LEE W, PARK S J. Porous anodic aluminum oxide: anodization and templated synthesis of functional nanostructures[J]. Chemical Reviews, 114, 7487-7556(2014).

[33] MANZANO C V, RAMOS D, PETHO L et al. Controlling the color and effective refractive index of metal-anodic aluminum oxide (AAO)-Al nanostructures: morphology of AAO[J]. The Journal of Physical Chemistry C, 122, 957-963(2018).

[34] SANTOS A, BALDERRAMA V S, ALBA M et al. Nanoporous anodic alumina barcodes: toward smart optical biosensors[J]. Advanced Materials, 24, 1050-1054(2012).

[35] KUMERIA T, LOSIC D. Controlling interferometric properties of nanoporous anodic aluminium oxide[J]. Nanoscale Research Letters, 7, 1-10(2012).

[36] DRONOV R, JANE A, SHAPTER J G et al. Nanoporous alumina-based interferometric transducers ennobled[J]. Nanoscale, 3, 3109-3114(2011).

[37] ASTROVA E V, TOLMACHEV V A. Effective refractive index and composition of oxidized porous silicon films[J]. Materials Science and Engineering: B, 69, 142-148(2000).

[38] ZHAO Yuqing, GAO Zhishan, YUAN Qun et al. Simulation and analysis of low-coherence micro-interference signal with high aspect ratio trench structure based on FDTD[J]. Acta Photonica Sinica, 52, 0112001(2023).