A study was conducted to physically characterize masks that have been accepted in Indonesian market. This was motivated by the importance of masks as part of public health measures, preventing droplets from the wearer from leaving the mask and from outside (other people) from entering the mask, while maintaining a comfortable breathing environment. The purpose of this study was to physically characterize the three layers (front, middle, and back) of the mask. The results of this study can serve as a reference for small businesses in producing masks that are suitable for use. The research method was carried out in three stages. Stage 1: Calibration of the red and green laser wavelengths used, using diffraction grating (250, 500, and 750 lines/mm). Stage 2: Randomly selected masks from several reputable brands on the market. The lattice constants of the front and back layers of the masks, as well as the water absorption of the middle layer, were measured. This was done (on single brand of mask) in new, used, and used condition with treatment (washing and ironing). Stage 3, checked the lattice constant value (distance between the front and back layer pores) which was seen with microscope (with a micrometer installed in it) at a magnification of 83,3 times. The results obtained were the lattice constant value of the front and back layers and water absorption in the middle layer respectively: (a) new mask: (3.1  0.1)x10^-3 cm; (1.3  0.2)x10^-3 cm, and (3  1)x10^-1 g/minute; (b) used mask: (1.3  0.4)x10^-3 cm, (1.2  0.4)x10^-3 cm, and (3  1)x10^-1 g/minute; (c) used mask with treatment: (1.4  0.4)x10^-3 cm, (1.4  0.3)x10^-3 cm, and (14  1)x10^-1 g/minute. Visual observations using a microscope yielded a lattice constant equivalence to the laser diffraction method. These results indicate that, regardless of comfort, mask suitable for use do not have to be new but this also applies to used masks that have been treated.

disposable mask; physical characterization; three-layer masks; lattice constant; water absorption

Adanur, S., & Jaywal, A. (2022). Filtration mechanism and manufacturing methods of face masks: An overview. Journal of Industrial Textiles, 51(3_suppl), 3683S–3717S.

Asim, N., Badiei, M., & Sopian, K. (2021). Review of the valorization options for the proper disposal of face masks during the COVID-19 pandemic. Environmental Technology & Innovation, 23, 101797.

Badan Standardisasi Nasional. (2021). Yuk mengenal masker dan SNI-nya. Badan Standardisasi Nasional.

Benson, N. U., Bassey, D. E., & Palanisami, T. (2021). COVID pollution: Impact of COVID-19 pandemic on global plastic waste footprint. Heliyon, 7, e06343.

Kementerian Kesehatan Republik Indonesia. (2020). Pedoman pencegahan dan pengendalian coronavirus disease (COVID-19) (Revisi ke-5). Kemenkes RI.

Kementerian Kesehatan Republik Indonesia. (2024). Update laporan harian perkembangan kasus COVID-19 per 30 Januari 2024. Kemenkes RI.

Louten, J. (2016). Virus structure and classification. In Essential human virology (pp. 19–29). Elsevier. https://doi.org/10.1016/B978-0-12-800947-5.00002-8

Meiriza, M., Alvindra, D., Siagian, H., Ummah, N., Situmeang, V., & Hutagalung, M. (2024). Analisis dampak COVID-19 terhadap inflasi harga masker. As-Syirkah: Islamic Economic & Financial Journal, 3(2), 548–554.

Nuraeni, A., Nurfa, N. N., Nisa, P. N., Azzahra, U. H., & Sujarwanto, E. (2019). Penentuan diameter rambut menggunakan laser sebagai fenomena difraksi pada biomaterial. DIFFRACTION: Journal for Physics Education and Applied Physics, 1(2), 29–33.

Presiden Republik Indonesia. (2023). Undang-Undang Republik Indonesia Nomor 17 Tahun 2023 tentang penetapan berakhirnya status pandemi Coronavirus Disease 2019 di Indonesia. Sekretariat Negara.

Salvi, S. S. (2020). In this pandemic and panic of COVID-19, what should doctors know about masks and respirators. Journal of the Association of Physicians of India, 68(3), 20–23.

Seresirikachorn, K., Phoophiboon, V., Chobarporn, T., Tiankanon, K., Aeumjaturapat, S., & Chusakul, S. (2021). Decontamination and reuse of surgical masks and N95 filtering facepiece respirators during the COVID-19 pandemic: A systematic review. Infection Control & Hospital Epidemiology, 42(1), 25–30.

Valh, V., Pušić, J., Curlin, M., & Knežević, A. (2023). Extending the protection ability and life cycle of medical masks through the washing process. Materials, 16(3), 1247.

Wang, Y., Deng, Z., & Shi, D. (2021). How effective is a mask in preventing COVID-19 infection? Medical Devices & Sensors, 4, e10163.

Wang, Q., Gu, J., & An, T. (2022). The emission and dynamics of droplets from human expiratory activities and COVID-19 transmission in public transport systems: A review. Building and Environment, 219, 109224.

Whyte, H. E., Joubert, A., Leclerc, L., Sarry, G., & Verhoeven, P. (2022). Reusability of face masks: Influence of washing and comparison of performance between medical face masks and community face masks. Environmental Technology & Innovation, 20, 102710.

World Health Organization. (2020). Anjuran mengenai penggunaan masker dalam konteks COVID-19: Panduan interim. WHO.

Yang, S., Lee, G. W., Chen, C. M., Wu, C. C., & Yu, K. P. (2007). The size and concentration of droplets generated by coughing in human subjects. Journal of Aerosol Medicine, 20(4), 84–94. https://doi.org/10.1089/jam.2007.0610

Yulendasari, R., Prasetyo, R., Sari, L. Y., & Nelyana, F. (2022). Penyuluhan kesehatan tentang TBC. Journal of Public Health Concerns, 2(3), 125–130.

Zorko, D. J., Gertsman, S., O’Hearn, K., Timmerman, N., Ambu-Ali, N., Dinh, T., Sampson, M., Sikora, L., McNally, J. D., & Choong, K. (2020). Decontamination interventions for the reuse of surgical mask personal protective equipment: A systematic review. PROSPERO: International Prospective Register of Systematic Reviews, CRD42020202530.