Agriculture Reference
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Fig. 5.6 TEM pictures of wheat gluten-based materials containing ethofumesate filled with
unmodified MMT (WG-HPS-E) and organically modified MMMT (WG-C30B-E and
WG-D72T-E) ( top ). Ethofumesate release kinetics obtained for the unfilled wheat gluten-based
material ( white circle ); wheat gluten-based materials filled with HPS ( delta ), C30B ( diamond ), and
D72T ( white square ); and commercial formation ( asterisk )at8 C(a), 25 C(b), and 40 C.
Symbols are experimental data points. Error bars represent standard deviation. Dot lines are fitting
to the model. RMSE values were 0.04, 0.05, 0.10, and 0.51 at 8 C; 0.05, 0.03, 0.04, and 0.39 at
25 C; 0.04, 0.03, 0.05, and 0.15 at 40 C for WG, WG-HPS, WG-C30B, WG-D72T, respectively
( bottom ) (Chevillard et al. 2012 ). Reproduced by permission of Elsevier
Fig. 5.7 Scanning electron micrographs of (a) uncoated and coated Ni-Cr wire, (b) Ppy, and (c)
Ppy/nanoclay fibers (adapted from Jafari et al. 2014 ). Reproduced by permission of Elsevier
by detection of diazinon and fenthion pesticides through gas chromatography
corona discharge ion mobility spectrometer (GC-CD-IMS) analysis. In these exper-
iments, 5 real samples were analyzed, 2 of which were water (tap and river), 1 of
which was fruit (apple), and 2 of which were vegetables (cucumber and lettuce), as
shown in Table 5.3 .
Dehaghi et al. ( 2014 ) studied chitosan-zinc oxide (CS-ZnO) nanoparticles as an
absorbent vehicle for the removal of the pesticide permethrin from water. ZnO
nanoparticles possessed an almost spherical morphology with a size of 58 nm. The
authors investigated the influence of the amount of absorbent, agitation time,
pesticide initial concentration, and pH on the sorption of the pesticide by CS-
ZnO absorbents. The authors concluded that these novel absorbent materials may
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