The
UV-vis spectrum of gold nanoparticles as a function of time shows that the reaction is completed within 20 min. It has been shown that the formation of gold nanoparticles starts 2 min after the interaction of plant extract with HAuCl4 [110]. The current method [110] of gold nanoparticle synthesis is faster and efficient ATM inhibitor than that reported earlier by Vankar and Bajpai [111] which took approximately 2 h for the completion of reaction. At concentration as low as 0.7 mM, the synthesis was optimum, and above this concentration, the formation of gold nanoparticles ceases to continue (Figure 6). The rate of synthesis of gold nanoparticles from G. glauca flower extract increases with increasing temperature and attains maximum between 40°C and 50°C. A similar pattern was found to follow check details when gold nanoparticle was synthesized from Nyctanthes arbortristis flower extract [112]. In this case, the particles are spherical in size ranging between 5- and 20 nm [113, 114]. Polydispersed gold nanoparticles can be obtained from Rosa hybrida petal extract [115]. When the concentration of HAuCl4 is low, gold nanoparticles of smaller size are produced, although they are often covered with larger particles as aggregates [114]. The FTIR spectra of dried G. glauca flower [110] extract before and after the synthesis of nanoparticles revealed a decrease
in all stretching frequencies of the probable functional groups of the phenols, flavonoids and amines present in the extract. It suggests a decrease in the concentration of the functional groups after the synthesis of gold nanoparticles, which is obvious. During the phytosynthesis of metal nanoparticles, all alcohol, aldehyde and phenol present in the plant extract are oxidized (as shown below), and the metal ions are reduced
to metal nanoparticles: Alcohol → Aldehyde Carnitine palmitoyltransferase II Aldehyde → Carboxylic acid Phenol → Ketone Flavonoids → Flavone Figure 6 Time course of gold nanoparticle formation. As obtained with different concentrations of chloroauric acid using Gnidia glauca flower extract at 40°C [110]. These nanoparticles may be used as chemocatalytic agent in the reduction and degradation of organic compounds. Photocatalytic degradation of methylene blue was done under sunlight by the silver nanoparticles synthesized from Morinda tinctoria leaf extract. The deep blue colour of the dye starts fading after 1 h with the above experimental conditions under sunlight. The maximum absorbance for methylene is at 660 nm. The colour of methylene blue turned light green after 1 h and finally became colourless after 72 h showing its degradation up to a maximum of 95%. This demonstrates the photocatalytic activity of silver nanoparticles for methylene blue which may be SCH772984 manufacturer exploited for the benign treatment of dye stuffs [116]. Ganaie et al.