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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

[26] Bojuan HAO, Kaige WANG, Yukun ZHOU 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. ACS Omega, 5, 1109-1119(2020).

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

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

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

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

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

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

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

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

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

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

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

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