The capturing process of CO2 directly from air has been developed largely considering with commercial scale in pilot plants. This is done so that the capture CO2 from air can be used as a feedstock or raw material for producing carbon free renewable fuels by applying direct air capture (DAC) process. This way of capturing is gone to be possible with using some solid & aqueous sorbents in pilot plant. The success of this capturing process is depended on the appropriate configurations of both major & minor plant operations. Heat & mass balance are required necessarily to contribute on the finding of each pilot plants data. The design of this process is modeled like this so that the captured CO2 can be delivered at 15MPa into the pilot plant & for this, the requirements of energy inputs are about 8.81GJ or 5.25GJ of natural gas & 0 KWHr or 336KWHr of electricity respectively. Then all the results finding from the pilot contactor, reactor, calciner are optimized to reduce the processing cost of the capturing process. It is observed after the ending of the process that the amount of operating cost is ranged between 50$ to 100$ to capture per ton of CO2 from surrounding air where the total levelized cost of the whole process ranges between 94$ to 232$/t-CO2. If it considers the other specific choices such as financial safety, environ mental & ecological arrangements etc. then this DAC process would be the best reliable solution to capture the CO2 from air in upcoming decades.

M. Beller, M. Steinberg. Liquid-Fuel synthesis using nuclear power in a mobile energy depot system. Trans. Am. Nucl. Soc., 8 (1965).

K.S. Lackner, H.-J. Ziock, P. Grimes. Carbon Dioxide Extraction from Air: Is It an Option? Technical Report LA-UR-99-583. (Los Alamos National Laboratory).

K.S. Lackner. The promise of Negative emissions. Science, 354(2016), p. 714.

R. Socolow, M. Desmond, R. Aines,J. Blackstock, O. Bolland, T. Kaarsberg, N. Lewis, M. Mazzotti, A. Pfeffer, K. Sawyer, etal. Direct Air Capture of CO2 with Chemicals: A Technology Assessment for the APS Panel on Public Affairs. American Physical Society(2011).

T, Wang, K.S. Lackner, A/ Wright. Moisture swing sorbent for carbon dioxide capture from ambient air. Environ. Sci. Technol., 45(2011), pp. 6670-6675.

f. S. Zeman, K.S. Lackner. Capturing carbon dioxide directly from the atmosphere. World Resour. Rev., 16(2004), pp. 157-172.

D. Keith, K. Heidel, R. Cherry. Capturing CO2 from the atmosphere: rationale & process design considerations. B. Launder, J.M.T. Thompson(Eds.), Geo-Engineering Climate Change: environmental Necessity or Pandora’s Box?, Cambridge University Press (2010), pp. 107-126.

K.S. Lackner. Capture of carbon dioxide from ambient air. Eur. Phys. J. Spec.Top., 176(2009), pp. 93-106.

G. Holmes, D. Keith. An air-liquid contactor for large-scale capture of CO2 from air. Philos. Trans. A Math. Phys. Eng. Sci., 370(2012), pp. 4380-4403.

J.K. Stolaroff, D.W. Keith, G.V. Lowry. Carbon dioxide capture from atmosphere air using sodium hydroxide spray. Environ. Sci. Technol., 42(2008), pp. 2728-2735.

R.Baciocchi, G. Storti, M. Mazzotti. Process design & energy requirements for the capture of carbon dioxide from air. Chem. Eng. Process. Process Intensif., 45(2006), pp. 1047-1058.

S. D. Faust, O. M. Aly. Chemistry of Water Treatment. (Second Edition), CRC Press(1998).

J. Lassiter, S. Misra. Carbon Engineering. Harvard Business School(2013).

T. proll, K. Rupanovits, P. Kolbitsch, J. Bolhar-Nordenkampf, H. Hofbauer. Cold flow model study on a dual circulating fluidized bed(DCFB) system for chemical looping processes. Chem. Eng. Technol., 32(2009), pp. 418-424.

F. Zeman. Energy & material balance of CO2 capture from ambient air. Environ. Sci. Technol., 41(2007), pp. 7558-7563.

Heidel, K.R. & Rossi, R.A., United States Patent application: 0170327421. High Temperature Hydrator(A1). Filed May10, 2017, & issued A1.

F. S. Zeman, D. W. Keith. Carbon neutral hydrocarbons. Philos. Trans. A Math. Phys. Eng. Sci., 366(2008), pp. 3901-3918.

G. Holmes. A Carbon Dioxide Absorption Performance Evaluation for Capture From Ambient Air. University of Calgary(2010).

D. W. Keith, K. Heidel. A Process for Capturing CO2 from the Atmosphere. 15 August, 2018, pp. 1573-1594.

L. Burhenne, C. Giacomin, t. Follent, J. Ritchie, J.S.J. McCahill, W. Merida. Characterization of reactive CaCO3 crystallization in a fluidized bed reactor as a central process of direct air capture. J. Environ. Chem. Eng., 5(2017), pp. 5968-5977.

C. Gebald, J.A. Wurzbacher, P. Tingaut, A. Steinfeld. Stability of amine- functionalized cellulose during temperature- vacuum- swing cycling for CO2 capture from air. Environ. Sci. Technol., 47(2013), pp. 10063-10070.

KBR. Front end loading process. Available at: http://www.kbr.com/Documents/Onshore%20Refining%20Handouts/FrontEndLoadingProcessAndDeliverables_final.pdf.

E. S. Rubin, C. Short, g. Booras, J. Davison, C. Ekstrom, M. Matuszewski, S. McCoy. A proposed methodology for CO2 capture & storage cost estimates. Int. J. Greenh. Gas Control, 17(2013), pp. 488-503.

M. Mazzotti, r. Baciocchi, M. J. Desmond, R. H. Socolow. Direct air capture of CO2 with chemicals: optimization of a two-loop hydroxide carbonate system using a countercurrent air-liquid contactor. Clim. Change, 118(2013), pp. 119-135.