From Biofiltration to Promising Options in Gaseous Fluxes Biotreatment

<p>Part 1. Biological Treatment of Gaseous Streams: Attached and Suspended Biomass Units <br>Part 1.1. Benchmark aspects on biological removal of contaminants from gaseous streams <br>1. Current challenges and perspectives in gas fluxes biotreatment<br>2. Biofilters versus bioscrubbers and biotrickling filters: state of the art of biological air treatment<br>3. Determination of biofilters performances<br>4. Porous media models for packed-bed characterization<br>5. Life cycle assessment of biofiltration</p> <p>Part 1.2. Alternatives for gas treatment<br>6. High-performance biofilters for air treatment applications<br>7. Biofiltration of VOCs and PAHs<br>8. Biogas treatment for H2S, CO2 and other contaminants removal<br>9. Industrial biofilter case studies</p> <p>Part 2. Biological Treatment of Gaseous Streams: Phytoremediation and Microalgae Approaches<br>Part 2.1. Phytosystems for air quality enhancement<br>10. Particularities of indoor air biotreatment<br>11. Plant physiological mechanisms of air treatment<br>12. Plant-microbe interaction within phytosystems used for air treatment<br>13. Technological aspects of the removal of air pollutants by phytosystems<br>14. Phytosystems implementation: examples of application in practice</p> <p>Part 2.2. Microalgae-based approaches<br>15. Microalgae with potential in air treatment<br>16. Microalgae photobioreactors for gaseous contaminants removal<br>17. Microalgae-based biomass production for control of air pollutants<br>18. CO2 capture from CO2 - rich gases by microalgae <br>19. A model microalgae for addressing air treatment in spacecrafts<br>20. Microalgae for combined air revitalization and biomass production for space applications</p>