Junzhou He
- A new tool for energy conservation in operating room: The role of machine learning models in enhancing airflow control. In: Energy and Buildings, v. 309 (April 2024). (2024):
- A fast and multifactor evacuation method considering cumulative fatality rate based on deep reinforcement learning for urban toxic gas leakage. In: Sustainable Cities and Society, v. 103 (April 2024). (2024):
- Controlling airborne pathogen within Fangcang shelter hospitals: Aerodynamic analysis of bioaerosols released from various locations through experiment and simulation. In: Building and Environment, v. 252 (March 2024). (2024):
- A novel approach for predicting the concentration of exhaled aerosols exposure among healthcare workers in the operating room. In: Building and Environment, v. 245 (November 2023). (2023):
- Assessment of the air disinfection effect of low-concentration ozone in a closed environment. In: Building and Environment, v. 244 (October 2023). (2023):
- Experimental study on the generation of aerosol particles and microorganisms from surgical staff in an operating room. In: Building and Environment, v. 236 (May 2023). (2023):
- Bioaerosol distribution characteristics and potential SARS-CoV-2 infection risk in a multi-compartment dental clinic. In: Building and Environment, v. 225 (November 2022). (2022):
- Impact of the visitor walking speed and glass barriers on airflow and Bioaerosol particles distribution in the typical open tomb. In: Building and Environment, v. 225 (November 2022). (2022):
- Bacteria-carrying particles diffusion in the operating room due to the interaction between human thermal plume and ventilation systems: An experimental-numerical simulation study. In: Energy and Buildings, v. 270 (September 2022). (2022):
- A study on human perception in aircraft cabins and its association with volatile organic compounds. In: Building and Environment, v. 219 (July 2022). (2022):
- Droplet aerosols transportation and deposition for three respiratory behaviors in a typical negative pressure isolation ward. In: Building and Environment, v. 219 (July 2022). (2022):
- An experimental method for measuring VOC emissions from individual human whole-body skin under controlled conditions. In: Building and Environment, v. 181 (August 2020). (2020):
- Source apportionment of volatile organic compounds (VOCs) in vehicle cabins diffusing from interior materials (Part I). Measurements of VOCs in new cars in China. In: Building and Environment, v. 175 (May 2020). (2020):
- A one-dimensional VOC emission model of moisture-dominated cure adhesives. In: Building and Environment, v. 156 (June 2019). (2019):
- Measuring whole-body volatile organic compound emission by humans: A pilot study using an air-tight environmental chamber. In: Building and Environment, v. 153 (April 2019). (2019):
- Human breath as a source of VOCs in the built environment, Part I: A method for sampling and detection species. In: Building and Environment, v. 125 (November 2017). (2017):
- Human breath as a source of VOCs in the built environment, Part II: Concentration levels, emission rates and factor analysis. In: Building and Environment, v. 123 (October 2017). (2017):