W Anaf, L Bencs, R Van Grieken, K Janssens, K DeWael (2015). Indoor particulate matter in four Belgian heritage sites: Case studies on the deposition of dark-colored and hygroscopic particles. Science of the Total Environment, 506: 361–368.
ASTM (2008). ASTM D 6245-07. Standard Guide for Using Indoor Carbon Dioxide Concentrations to Evaluate Indoor Air Quality and Ventilation. West Conshohocken, PA, USA: American Society for Testing and Materials.
LM Bellan, LG Salmon, GR Cass (2000). A study on the human ability to detect soot deposition onto works of art. Environmental Science and Technology, 34: 1946–1952.
C Bläuer-Böhm, K Zehnder, H Domeisen, A Arnold (2001). Climate Control for the Passive Conservation of the Romanesque Painted Wooden Ceiling in the Church of Zillis (Switzerland). Studies in Conservation, 46: 251–268.
C Bonacina, P Baggio, F Cappelletti, P Romagnoni, AG Stevan (2015). The Scrovegni Chapel: The results of over 20 years of indoor climate monitoring. Energy and Buildings, 95: 144–152.
A Bonazza, C Sabbioni, N Ghedini (2005). Quantitative data on carbon fractions in interpretation of black crusts and soiling in European built heritage. Atmospheric Environment, 39: 2607–2618.
M Braniš, J Safránek, A Hytychová (2011). Indoor and outdoor sources of size-resolved mass concentration of particulate matter in a school gym—Implications for exposure of exercising children. Environmental Science and Pollution Research, 18: 598–609.
D Camuffo (2013). Microclimate for Cultural Heritage, Chapter 8: Dry deposition of airborne particulate matter: Mechanisms and effects. Amsterdam: Elsevier. pp. 295–366.
D Camuffo, P Brimblecombe, R van Grieken, HJ Busse, G Sturaro, A Valentino, A Bernardi, N Blades, D Shooter, L De Bock, K Gysels, M Wieser, O Kim (1999). Indoor air quality at the Correr Museum, Venice, Italy. Science of the Total Environment, 236: 135–152.
C Chen, B Zhao (2011). Review of relationship between indoor and outdoor particles: I/O ratio, infiltration factor and penetration factor. Atmospheric Environment, 45: 275–288.
DEFRA (2012). Fine Particulate Matter (PM2.5) in the United Kingdom. Air Quality Expert Group, Department for Environment, Food and Rural Affairs.
S El Hamdani, K Limam, MO Abadie, A Bendou (2008). Deposition of fine particles on building internal surfaces. Atmospheric Environment, 42: 8893–8901.
EPA (2012). Report to Congress on Black Carbon. EPA-450/R-12/001. U.S. Environmental Protection Agency.
WJ Fisk, WR Chan (2016). Health benefits and costs of filtration interventions that reduce indoor exposure to PM2.5 during wildfires. Indoor Air, doi:.
H Fromme, D Twardella, S Dietrich, D Heitmann, R Schierl, B Liebl, H Rüden (2007). Particulate matter in the indoor air of classrooms—Exploratory results from Munich and surrounding area. Atmospheric Environment, 41: 854–866.
M Grabon, J Anderson, P Bushnell, A Calvo, W Chadwick (2015). The Sistine chapel: New HVAC system for cultural preservation. ASHRAE Journal, 57(6): 20–34.
J Grau-Bové, M Strlič (2013). Fine particulate matter in indoor cultural heritage: A literature review. Heritage Science, 1: 1–17.
G Loupa, E Karageorgos, S Rapsomanikis (2010). Potential effects of particulate matter from combustion during services on human health and on works of art in medieval churches in Cyprus. Environmental Pollution, 158: 2946–2953.
L Maškova, J Smolik, T Travnickova, J Havlica, L Ondráčková, J Ondráček (2016). Contribution of visitors to the National Library in Prague, Czech Republic. Aerosol and Air Quality Research, 16: 1713–1721.
A Mleczkowska, M Strojecki, Ł Bratasz, R Kozłowski (2016). Particle penetration and deposition inside historical churches. Building and Environment, 95: 291–298.
WW Nazaroff, GR Cass (1991). Protecting museum collections from soiling due to the deposition of airborne particles. Atmospheric Environment, 25A: 841–852.
WW Nazaroff, MP Ligocki, LG Salmon, GR Cass, T Fall, MC Jones, HIH Liu, T Ma (1993). Airborne Particles in Museums, Research in Conservation. Los Angeles: The Getty Conservation Institute.
B Polednik (2013). Particle exposure in a Baroque church during Sunday masses. Environmental Research, 126: 215–220.
B Pretzel (2008). Now you see it, now you don’t: Lighting decisions for the Ardabil carpet based on the probability of visual perception and rates of fading. In: Preprints of the ICOM Committee for Conservation, 15th Triennial Conference, New Delhi, pp. 759–765.
L Samek, A De Maeyer-Worobiec, Z Spolnik, L Bencs, V Kontozova, Ł Bratasz, R Kozłowski, R Van Grieken (2007). The impact of electric overhead radiant heating on the indoor environment of historic churches. Journal of Cultural Heritage, 8: 361–369.
HL Schellen (2002). Heating Monumental Churches: Indoor Climate and Preservation of Cultural Heritage. PhD Thesis, Eindhoven Technical University, Netherlands.
JA Siegel (2016). Primary and secondary consequences of indoor air cleaners. Indoor Air, 26: 88–96.
TL Thatcher, ACK Lai, R Moreno-Jackson, RG Sextro, WW Nazaroff (2002). Effects of room furnishings and air speed on particle deposition rates indoors. Atmospheric Environment, 36: 1811–1819.
TL Thatcher, ML Melissa, LR Kenneth, GS Richard, JB Nancy (2003). A concentration rebound method for measuring particle penetration and deposition in the indoor environment. Aerosol Science and Technology, 37: 847–864.
DT Tran, LY Alleman, P Coddeville, J-C Galloo (2014). Indoor– outdoor behavior and sources of size-resolved air-borne particles in French classrooms. Building and Environment, 81:183–191.
S Weber (2006). Exposure of churchgoers to airborne particles. Environmental Science & Technology, 40: 5251–5256.