BookR: School of Health Core Facilities Booking
PubMed Publications| Keyword search (4,163 papers available) |  |
"Ge H" Authored Publications:
| Title | Authors | PubMed ID | |
|---|---|---|---|
| 1 | The Bug-Network (BugNet): A Global Experimental Network Testing the Effects of Invertebrate Herbivores and Fungal Pathogens on Plant Communities and Ecosystem Function in Open Ecosystems | Kempel A; Adamidis GC; Anadón JD; Atkinson J; Auge H; Avtzis D; Bachelot B; Bashirzadeh M; Bota JL; Classen A; Constantinou I; Crawley M; de Bellis T; Dostal P; Ebeling A; Eisenhauer N; Eldridge DJ; Encina G; Estrada C; Everingham S; Fanin N; Feng Y; Gaspar M; Gooriah L; Graff P; Montalván EG; Montalván PG; Hartke TR; Huang L; Jochum M; Kaljund K; Karmiris I; Koorem K; Korell L; Laine AL; le Provost G; Lessard JP; Liu M; Liu X; Liu Y; Llancabure J; Loïez S; Loydi A; Marrero H; Gockel S; Montoya A; Münzbergo | 41080499 ENCS |
| 2 | A review on indoor airborne transmission of COVID-19- modelling and mitigation approaches | Rayegan S; Shu C; Berquist J; Jeon J; Zhou LG; Wang LL; Mbareche H; Tardif P; Ge H; | 40478135 ENCS |
| 3 | Author Correction: Typical and extreme weather datasets for studying the resilience of buildings to climate change and heatwaves | Machard A; Salvati A; P Tootkaboni M; Gaur A; Zou J; Wang LL; Baba F; Ge H; Bre F; Bozonnet E; Corrado V; Luo X; Levinson R; Lee SH; Hong T; Salles Olinger M; Machado RMES; da Guarda ELA; Veiga RK; Lamberts R; Afshari A; Ramon D; Ngoc Dung Ngo H; Sengupta A; Breesch H; Heijmans N; Deltour J; Kuborn X; Sayadi S; Qian B; Zhang C; Rahif R; Attia S; Stern P; Holzer P; | 39814748 PHYSICS |
| 4 | "How do we do that?" An analysis of TikToks by lesbians over age 30 representing sexual identity, lived experience over time, and solidarity | Jamet-Lange H; Duguay S; | 38907626 CONCORDIA |
| 5 | Typical and extreme weather datasets for studying the resilience of buildings to climate change and heatwaves | Machard A; Salvati A; P Tootkaboni M; Gaur A; Zou J; Wang LL; Baba F; Ge H; Bre F; Bozonnet E; Corrado V; Luo X; Levinson R; Lee SH; Hong T; Salles Olinger M; Machado RMES; da Guarda ELA; Veiga RK; Lamberts R; Afshari A; Ramon D; Ngoc Dung Ngo H; Sengupta A; Breesch H; Heijmans N; Deltour J; Kuborn X; Sayadi S; Qian B; Zhang C; Rahif R; Attia S; Stern P; Holzer P; | 38782916 PHYSICS |
| 6 | Family Members' Perceptions of Their Psychological Responses One Year Following Pediatric Intensive Care Unit (PICU) Hospitalization: Qualitative Findings From the Caring Intensively Study | Rennick JE; Knox AM; Treherne SC; Dryden-Palmer K; Stremler R; Chambers CT; McRae L; Ho M; Stack DM; Dougherty G; Fudge H; Campbell-Yeo M; | 34557460 CONCORDIA |
| Title: | A review on indoor airborne transmission of COVID-19- modelling and mitigation approaches | ||||
| Authors: | Rayegan S, Shu C, Berquist J, Jeon J, Zhou LG, Wang LL, Mbareche H, Tardif P, Ge H | ||||
| Link: | https://pubmed.ncbi.nlm.nih.gov/40478135/ | ||||
| DOI: | 10.1016/j.jobe.2022.105599 | ||||
| Publication: | Journal of building engineering | ||||
| Keywords: | Airborne; Building; COVID-19; Mitigation; Modeling; Transmission; | ||||
| PMID: | 40478135 | Category: | Date Added: | 2025-06-06 | |
| Dept Affiliation: |
ENCS
1 Centre for Zero Energy Building Studies, Department of Building, Civil and Environmental Engineering, Concordia University, 1455 de Maisonneuve Blvd. West, Montreal, Quebec, H3G 1M8, Canada. 2 Construction Research Centre, National Research Council Canada, M-24, 1200 Montreal Road, Ottawa, Ontario, K1A 0R6, Canada. |
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Description: |
In the past few years, significant efforts have been made to investigate the transmission of COVID-19. This paper provides a review of the COVID-19 airborne transmission modeling and mitigation strategies. The simulation models here are classified into airborne transmission infectious risk models and numerical approaches for spatiotemporal airborne transmissions. Mathematical descriptions and assumptions on which these models have been based are discussed. Input data used in previous simulation studies to assess the dispersion of COVID-19 are extracted and reported. Moreover, measurements performed to study the COVID-19 airborne transmission within indoor environments are introduced to support validations for anticipated future modeling studies. Transmission mitigation strategies recommended in recent studies have been classified to include modifying occupancy and ventilation operations, using filters and air purifiers, installing ultraviolet (UV) air disinfection systems, and personal protection compliance, such as wearing masks and social distancing. The application of mitigation strategies to various building types, such as educational, office, public, residential, and hospital, is reviewed. Recommendations for future works are also discussed based on the current apparent knowledge gaps covering both modeling and mitigation approaches. Our findings show that different transmission mitigation measures were recommended for various indoor environments; however, there is no conclusive work reporting their combined effects on the level of mitigation that may be achieved. Moreover, further studies should be conducted to understand better the balance between approaches to mitigating the viral transmissions in buildings and building energy consumption. |
