Membrane-less reactor design and process for biotransformation of carbon dioxide

We claim: 1. A membrane-less reactor for converting carbon dioxide to alcohols by microbial electrosynthesis, the membrane-less reactor comprising: a) a tubular gas diffusion electrode comprising an active layer, and a gas diffusion layer, wherein the active layer is modified with an electroactive material, wherein the tubular gas diffusion electrode is configured to work as a working electrode, wherein, the active layer faces towards an outside of the working electrode and the gas diffusion layer faces towards an inner core of the working electrode; b) a circular counter electrode, wherein the circular counter electrode is a circular disc shaped mesh having a central cavity; c) a porous bio-electroactive filter, wherein the porous bio-electroactive filter is arranged in association with the active layer of the tubular gas diffusion electrode and is configured to develop an electro-active biofilm, and wherein the electro-active biofilm comprises a biocatalyst for the microbial electrosynthesis; d) an electrolyte; and e) samplings ports; wherein the working electrode and the circular counter electrode are positioned perpendicular to each other such that oxygen generated at counter electrode is washed away without contacting the working electrode, and the working electrode is vertically arranged inside the membrane-less reactor such that it remains completely immersed in the electrolyte, wherein the active layer faces towards the electrolyte and gas diffusion layer faces towards the inner core of the working electrode without contacting the electrolyte, thus forming a gas compartment towards the inner core of the working electrode, and wherein the counter electrode is positioned on top of the electrolyte; wherein the membrane-less reactor is configured to be operated in a batch mode in a sequential batch reactor, or in a continuous or semi-continuous mode in a continuous stirred tank reactor. 2. The membrane-less reactor as claimed in claim 1 , wherein the active layer of the working electrode comprises: a) an activated carbon powder and graphite in 60:40 proportion; and b) the electroactive materials present in a concentration range of 0.4-0.6 mg/cm 2 . 3. The membrane-less reactor as claimed in claim 1 , wherein the working electrode is treated with polymerized redox mediators dissolved in the electrolyte at a concentration of 0.4-0.6 mM; wherein the electrolyte comprises trace metal solution along with carbon dioxide as a carbon source. 4. The membrane-less reactor as claimed in claim 1 , wherein the counter electrode is made up of titanium, nickel, or titanium coated with mixed metal oxide of ruthenium or iridium, and wherein the counter electrode is coated with a coating of highly active materials with a concentration in range of 0.6-0.8 mg/cm2. 5. The membrane-less reactor as claimed in claim 1 , wherein the feedstock for the reactor is CO 2 alone or a flue gas having 14% CO 2 along with other pollutant gases. 6. The membrane-less reactor as claimed in claim 1 , wherein the biocatalyst is a microbe selected from a group consisting of an electro-active bacteria (EAB), a chemoautotrophic bacteria, a heterotrophic bacteria, and a homo acetogenic bacteria, wherein the microbe is grown under 3 V cell potential for 5-7 days prior to inoculation. 7. The membrane-less reactor as claimed in claim 1 , wherein the membrane-less reactor is operated at a pressure in a range of 2-10 bar by maintaining a flow rate of the feedstock and a potential in a range of 1-4 V or applied current in a range of 50-200 A/m2. 8. A system for production of alcohol from carbon dioxide, said system comprising: a carbon dioxide supply reservoir or a flue gas supply reservoir; an electrolyte supply reservoir; a trace metal solution (TMS) for providing essential nutrients to microbial metabolism; a microbial separation column; a product separation column; and a membrane-less reactor for conversion of carbon dioxide to alcohols, wherein, the membrane-less reactor comprises a) a tubular gas diffusion electrode comprising an active layer, and a gas diffusion layer, wherein the active layer is modified with an electroactive material, wherein the tubular gas diffusion electrode is configured to work as a working electrode, wherein, the active layer faces towards an outside of the working electrode and the gas diffusion layer faces towards an inner core of the working electrode, b) a circular counter electrode, wherein the circular counter electrode is a circular disc shaped mesh having a central cavity, c) a porous bio-electroactive filter, wherein the porous bio-electroactive filter is arranged in association with the active layer of the tubular gas diffusion electrode and is configured to develop an electro-active biofilm, and wherein the electro-active biofilm comprises a biocatalyst for the microbial electrosynthesis, d) an electrolyte, e) samplings ports, wherein the working electrode and the circular counter electrode are positioned perpendicular to each other such that oxygen generated at counter electrode is washed away without contacting the working electrode, and the working electrode is vertically arranged inside the membrane-less reactor such that it remains completely immersed in the electrolyte, wherein the active layer faces towards the electrolyte and gas diffusion layer faces towards the inner core of the working electrode without contacting the electrolyte, thus forming a gas compartment towards the inner core of the working electrode, and wherein the counter electrode is positioned on top of the electrolyte, and wherein the membrane-less reactor is configured to be operated in a batch mode in a sequential batch reactor, or in a continuous or semi-continuous mode in a continuous stirred tank reactor, wherein the carbon dioxide supply reservoir and the electrolyte supply reservoir are connected to the membrane-less reactor and supply carbon dioxide and electrolyte respectively and the microbial separation column and the product separation column are sequentially connected to the membrane-less reactor through the electrolyte supply reservoir.