Table 1.
Bioaerosol removal and inactivation technologies.
| Technology | References | Note | |
|---|---|---|---|
| Elimination of bioaerosol | HEPA Filter | Ruth 1935 [24] | Decrease in air supply due to continuous use |
| Olmsted 2008 [25] | |||
| Ryan 2010 [20] | Energy loss due to filter blockage | ||
| Loderer 2012 [26] | Decrease in air supply due to continuous use | ||
| Hubbard 2012 [27] | Decrease in air supply due to continuous use | ||
| Lee 2015 [28] | Decrease in air supply due to continuous use | ||
| Mousavi 2020 [17] | |||
| Christopherson 2020 [18] | |||
| Nazarenko 2020 [29] | |||
| Zacharias 2021 [19] | |||
| Brouwers 2021 [30] | |||
| Mousavi 2021 [16] | Decrease in air supply due to continuous use | ||
| Myers 2022 [31] | |||
| Acoustic agglomeration | Nelson 2013 [32] | ||
| Adsorption (Electrostatic) | Volckens 2002 [33] | ||
| Hong 2016 [34] | |||
| Jung 2020 [35] | |||
| Feng 2021 [36] | Water vapor reduces electrostatic adsorption | ||
| Adsorption (Adsorbent) | Li 2011 [37] | ||
| Pham 2015 [38] | |||
| Inactivation of bioaerosol | UVC |
Kim 2018 [39] |
UVC-LED |
| Welch 2018 [40] | Laser | ||
| Lo 2021 [22] | Hg Lamp | ||
| Bono 2021 [23] | |||
| Muramoto 2021 [41] | UVC-LED | ||
| Herman 2021 [42] | Sunlight | ||
| Lai 2021 [43] | UVC-LED | ||
| O3 | Masuda 1993 [44] | ||
| Grinshpun 2007 [45] | MS-2 | ||
| Kim 2018 [46] | MS-2 | ||
| Tizaoui 2020 [47] | |||
| Vyskocil 2020 [48] | Phage PhiX174 (HER-036) | ||
| Park 2020 [49] | Escherichia coli and Micrococcus luteus | ||
| Photocatalyst | Ishiguro2011 [50] |
Qβ and T4 bacteriophages |
|
| Daikoku 2015 [51] | Influenza virus | ||
| Poormohammadi 2021 [52] | |||
| Khaiboullina 2021 [53] | SARS-CoV-2 | ||
| Matsuura 2021, 2022 [54,55] | SARS-CoV-2 | ||
| Álvarez 2022 [56] | SARS-CoV-2 | ||
| Moon 2020 [57] | SARS-CoV-2 | ||
| Nakano 2022 [58] | SARS-CoV-2 | ||