Reactors and methods for producing and recovering extracellular metal or metalloid nanoparticles

We claim: 1. A bioelectrochemical reactor system for production of extracellular metal and metalloid nanoparticles, comprising: a bioelectrochemical reactor comprising: an anaerobic anode chamber which comprises a bacteria-coated anode; an anaerobic cathode chamber which comprises a bacteria-coated cathode; a cation exchange membrane in fluid communication with, and separating, the anode chamber and the cathode chamber; a source of an electron donor substance configured for supplying the electron donor substance into the anode chamber; a source of metal or metalloid ion-contaminated medium configured to pump the medium through the cathode chamber; and an external resistor in a circuit with the anode and the cathode, and a separator device which comprises a plate positioned in a flow of the medium exiting the cathode chamber, the plate comprising a plurality of pores to permit the passage of water but not the passage of nanoparticles or bacteria agglomerates, to separate the extracellular metal or metalloid nanoparticles from the medium, wherein the biochemical reactor is configured to reduce the metal or metalloid ions in the metal or metalloid ion-contaminated medium to extracellular metal or metalloid nanoparticles, wherein the metal or metalloid nanoparticles comprise selenium. 2. The bioelectrochemical reactor system of claim 1 , wherein the electron donor substance comprises acetate, propionate, methanol, ethanol, or glucose. 3. The bioelectrochemical reactor system of claim 1 , wherein the medium of the metal or metalloid ion-contaminated medium comprises water. 4. The bioelectrochemical reactor system of claim 1 , wherein the metal ion comprises selenate (SeO 4 2− ) or selenite (SeO 3 2− ). 5. The bioelectrochemical reactor system of claim 1 , further comprising a tangential flow filtration unit for separating the extracellular metal or metalloid nanoparticles and bacteria from the medium. 6. The bioelectrochemical reactor system of claim 1 , wherein: the plate comprises a polymeric surface on which the nanoparticles will adhere, and the plate is angled relative to the flow of the medium such the bacteria will agglomerate and roll off of the plate. 7. The bioelectrochemical reactor system of claim 1 , wherein the plate has an exterior surface which comprises polyethylene. 8. The bioelectrochemical reactor system of claim 1 , wherein: the separator device comprises a vertically elongated vessel in which the plate is disposed, the vessel comprises an inlet about an upper end of the vessel for receiving the medium containing a mixture of bacteria and the nanoparticles, an outlet about an upper end of the vessel opposite the inlet for discharge of the medium from the vessel, and an outlet about the lower end of the vessel for discharge of biomass from the vessel. 9. A method for reducing metal or metalloid ions to extracellular metal or metalloid nanoparticles, the method comprising: providing the bioelectrochemical reactor system of claim 1 ; actuating the circuit to provide a voltage between the anode and the cathode; contacting the cathode and the anode with the metal or metalloid ion-contaminated medium; and feeding the electron donor substance into the anode chamber, wherein the contacting and feed rates are effective to cause extracellular metal or metalloid producing bacteria to reduce the metal or metalloid ions in the metal or metalloid ion-contaminated medium to extracellular metal or metalloid nanoparticles. 10. The method of claim 9 , wherein the metal ion-contaminated medium is fed continuously through the cathode chamber. 11. The method of claim 9 , wherein the electron donor substance is fed continuously through the anode chamber. 12. The method of claim 9 , wherein the electron donor substance comprises an acetate, propionate, methanol, ethanol, or glucose; and wherein the medium of the metal or metalloid ion contaminated medium comprises water. 13. The method of claim 9 , wherein the metalloid ion is selenate (SeO 4 2− ) and the nanoparticles are selenium (Se 0 ). 14. The method of claim 9 , wherein the flow rate of the electron donor is sufficient to maintain an amount equal to or higher than the stoichiometric ratio between electron donor and metal or metalloid ion.