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The purpose of this study is to develop nature-inspired 3D surfaces for atmospheric water harvesting.

Initially, cylindrical-shaped protrusions were produced utilizing a 3D printer to obtain a surface with a high surface area. Subsequently, an electrospraying technique was employed to coat the tips of these hydrophobic protrusions with hydrophilic nano-scale particles and fibers, utilizing polyamide 6 (PA6) or PA6/chitosan (CH) blends. In the next stage of the study, the impact of protrusion shape was investigated by fabricating surfaces with cylindrical, conical and tree-shaped protrusions. Following the production of 3D surfaces, PA6 was electrosprayed onto the protrusions to achieve varied wettability patterns on the 3D surface. Finally, the water collection rates and capacities of the surfaces were evaluated.

Water collection tests demonstrated that PA6-coated surfaces exhibited greater water collection capacity compared to untreated surfaces. Furthermore, the addition of CH enhanced the water collecting efficiency of the 3D surface. It was found that the shape of the protrusions significantly influenced water collection capacity. Particularly, cone-shaped protrusions exhibited the highest water collecting capability among the different shapes tested.

In this study, 3D printing and electrospraying techniques were combined to create 3D surfaces characterized by high surface area, along with hydrophilic and hydrophobic regions to produce superior surfaces for atmospheric water harvesting.

The main objective of the present study was to evaluate the feasibility of obtaining energy from cotton processing waste oil and heating demand in the cotton oil processing. For the techno-economical feasibility, Cukobirlik cotton union, located in Adana, Turkey was selected considering capacity per annum. The techno-economical feasibility of cotton processing wastes for fossil fuel substitution running three scenarios was examined. The case study constitutes of the following parts, background information and description of the company activities, the existing facilities and its energy requirements, the second the technical options for the exploitation of biomass and the results of their financial appraisal, environmental considerations, risks and assumptions and finally conclusions and recommendations. The economic and financial assessment of the investment for biomass utilization in Cukobirlik cotton union includes the calculation of the economic viability parameters and cash flow analysis table and investment return indices. An economical solution was determined to be scenario 2 for Cukurova cotton union. The values of discounted payback period, net present value, internal rate of return and benefit to cost ratio were calculated as 3.28 years, 2 832 421 €, 34.07% and 3.31 for scenario 2. Based on the results of the pre-feasibility study, it seems that the installation of a 5 MW biomass boiler to Cukobirlik for substitution of fuel oil (scenario 2) is a very attractive investment and is still favorite in comparison with the installation of a natural gas boiler to meet the same needs when the natural gas price is higher than 0.37 €/Nm³.