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Hochmannova L and Vytrasova J, Photocatalytic and antimicrobial effects of indoor
paints,
Progress in Organic Coatings
, 2010, 67, 1-5.
Huang CH, Wang IK, Lin YM, Tseng YH and Lu CM, Visible light degradation of
nitric oxides on PtO
x
-modifi ed TiO
2
via sol-gel and impregnation method,
Journal
of Molecular Catalysis A
, 2010, 316, 163-170.
Huang H and Li W, Destruction of toluene by ozone-enhanced photocatalysis:
performance and mechanism,
Applied Catalysis B
, 2011, 102, 449-453.
Ihara T, Miyoshi M, Iriyama Y, Matsumoto O and Sugihara S, Visible light active
titanium dioxide photocatalyst realized by an oxygen-defi cient structure and by
nitrogen doping,
Applied Catalysis B
, 2003, 42, 403-409.
Irokawa Y, Morikawa T, Aoki K, Kosaka S, Ohwaki T and Taga Y, Photodegradation
of toluene over TiO
2
-xN
x
under visible light irradiation,
Phys Chem Chem Phys
,
2006, 8, 1116-1121.
Ismail AA and Bahnemann DW, Metal-free porphyrin-sensitized mesoporous
titania fi lms for visible light indoor air oxidation,
Chemical and Sustainability
Energy and Materials
, 2010, 3, 1057-1062.
Jianhua L, Rong Y and Songmei L, Preparation and characterization of the TiO
2
/
V
2
O
5
photocatalyst with visible light activity,
Rare Metals
, 2006, 25, 636-642.
Jo WK and Kim JT, Application of visible light photocatalysis with nitrogen-doped
or unmodifi ed titanium dioxide for control of indoor-level volatile organic com-
pounds,
Journal of Hazardous Materials
, 2009, 164, 360-366.
Kafi zas A, Kellici S, Darr JA and Parkin LP, Titanium dioxide and composite metal/
metal oxide titania fi lms on glass: a comparative study of photocatalytic activity,
Journal of Photochemistry and Photobiology A
, 2009, 204, 183-190.
Kaneko M and Okura I,
Photocatalysis: Science and Technology
, Springer, New
York, 2002.
Kaur S and Singh V, Visible light induced sonophotocatalytic degradation of reactive
red dye 198 using dye sensitized TiO
2
,
Ultrasonics Sonochemistry
, 2007, 14,
531-537.
Kormann C, Bahnemann DW and Hoffmann MR, Environmental photochemistry:
is iron oxide (hematite) an active photocatalyst? A comparative study:
-Fe
2
O
3
,
ZnO, TiO
2
,
Journal of Photochemistry and Photobiology A
, 1989, 34, 161-169.
Laufs S, Burgeth G, Duttlinger W, Kurtenbach R, Maban M, Thomas C, Wiesen P
and Kleffmann J, Conversion of nitrogen oxides on commercial photocatalytic
dispersion paints,
Atmospheric Environment
, 2010, 44, 2341-2349.
Leech JA, Nelson WC, Burnett RT, Aaron S and Raizenne ME, It's about time: a
comparison of Canadian and American time-activity patterns,
Journal of Expo-
sure Analysis and Environmental Epidemiology
, 2002, 12, 427-432.
Maggos T, Bartzis JG, Leva P and Kotzias DK, Application of photocatalytic tech-
nology for NO
x
removal,
Applied Physics A
, 2007, 89, 81-84.
Marolt T, Sever A, Bernard J, Zivec P and Gaberscek M, Photocatalytic activity of
anatase-containing façade coatings,
Surface & Coatings Technology
, 2011, 206,
1355-1361.
Mazellier P and Bolte M, Heterogeneous light induced transformation of 2,6-
dimethylphenol in acqueous suspensions containing goethite,
Journal of Photo-
chemistry and Photobiology A
, 2000, 132, 129-135.
Mele G, del Sole R, Vasapollo G, Lopez EG, Palmisano L and Schiavello M,
Photocatalytic degradation of 4-nitrophenol in aqueous suspension using
α
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