محمد زمان کسایی

In this study, cheap nanoparticles with the highest hybrid similarity were introduced to increase the surface resistance of ancient Pasargadae (Cyrus Tomb) rocks. As result, the kind of mineral of thin section of sample was detected as calcite and grainstone texture. The physical features of the sample indicated a high porosity. In order to achieve a high compatibility of the intended Nano materials, some powder of the sample was used as pre-material through Mechanical Grinder. After preparation of the powder, Nano material was prepared due to sol-gel method. Calcium Titanate blurs with the phase of Perovskite and Titanium dioxide with the phase of Anatase have been detected as XRD. These compounds were confirmed by FT-IR. The size of spherical and oval blurs prepared in the scale of Nano was confirmed by SEM. The existence of common elements such as Calcium, Titanium, Oxygen and Carbon was detected as EDX spectrometer. In this experience, Ethanol was used as solvent. In 4 hours, the gained Colloidal dissolved was added on the surface of the stone by the capillary specific. So as to module the resistance of the sample, the coated surface was examined under the abrasion test. Along with these experiments, all the levels for pre-material lime were done. The results show a relative improvement in the surface resistance of the sample rock. Meanwhile, there wasn’t any remarkable change in the case of the color of the sample.

Chitosan is a glucosamine polysaccharide deacetylated form of chitin species and could be used as biotic elicitor to improve secondary metabolites and as a fertilizer it controls the release of chemical compounds of toxins and stimulates germination and plant growth. Thus, to evaluate the effect of chitosan NPs on barley plants under late season drought stress, a factorial pot experiment was performed based on a randomized complete block design with three replications. The experimental factors were NPs concentrations at 4 levels (0, 30, 60 and 90 ppm), method of usage at 2 levels (foliar and soil application) and irrigation regimes at 2 levels (normal irrigation and with-holding irrigation 15 days after pollination). Experimental procedure consisted of planting seeds, preparing chitosan NPs solution, and using solutions through soil and foliar application at three plant growth stages (tillering, stem elongation and heading). Results indicated that drought stress significantly decreased contents of carotenoid, chlorophyll a, the chlorophyll b, the total chlorophyll, rate of photosynthesis, stomatal conductance, transpiration, grain yield, as well as, biomass. Results also showed that contents of soluble carbohydrate, glucose, sucrose, fructose, intercellular CO2 concentration (Ci) and photosynthetic water use efficiency (WUE) were increased. Also, under both irrigation regimes, application of chitosan NPs significantly increased the chlorophyll a, the chlorophyll b, the soluble chlorophyll and the glucose. Application of 60 and 90 ppm NPs significantly increased grain yield as compared to that of control. Signifficant diffrences for some traits under study between two usage methods of NPs were not observed. In general, application of chitosan NPs reduced negative effects of drought stress for barley plants and improved its growth and seed yield.