Bipolar exfoliation of black phosphorous into phosphorene

What is claimed is: 1. A bipolar exfoliation system for single-step, in situ exfoliations of multi-layer bulk black phosphorous and deposition into single-layer, few-layer, or nano-platelets phosphorene, the system comprising: a first driving electrode; a second driving electrode electrically connected to the first driving electrode through an external power supply; at least one bipolar electrode comprising multi-layer bulk black phosphorous, the at least one bipolar electrode being disposed between the first driving electrode and the second driving electrode in a horizontal direction parallel to a lower surface of the first driving electrode; and a solvent in physical contact with the first driving electrode, the second driving electrode, and the at least one bipolar electrode, the solvent being deionized water without salts. 2. The bipolar exfoliation system according to claim 1 , an electric field between the first and second driving electrodes being configured such that one end of the at least one bipolar electrode is turned into an anodic pole and the other end of the at least one bipolar electrode is turned into a cathodic pole. 3. The bipolar exfoliation system according to claim 2 , the solvent being configured such that molecules of the solvent are oxidized at the anodic pole of the at least one bipolar electrode and the molecules of the solvent are reduced at the cathodic pole of the at least one bipolar electrode. 4. The bipolar exfoliation system according to claim 2 , the at least one bipolar electrode being configured such that two faradaic reactions occur at at the anodic pole and the cathodic pole, respectively, of the at least one bipolar electrode. 5. The bipolar exfoliation system according to claim 2 , the system being configured such that a magnitude of the electric field is configured such that the multi-layer black phosphorous is exfoliated into the single-layer, few-layer, or nano-platelets phosphorene. 6. The bipolar exfoliation system according to claim 2 , the system being configured such that a direction of the electric field relative to the at least one bipolar electrode is configured such that the multi-layer black phosphorous is exfoliated into the single-layer, few-layer, or nano-platelets phosphorene. 7. The bipolar exfoliation system according to claim 1 , the system being configured such that a potential between the first and second driving electrodes is configured such that the multi-layer black phosphorous is exfoliated into the single-layer, few-layer, or nano-platelets phosphorene. 8. The bipolar exfoliation system according to claim 1 , the system being configured such that a distance between the first and second driving electrodes is configured such that the multi-layer black phosphorous is exfoliated into the single-layer, few-layer, or nano-platelets phosphorene. 9. The bipolar exfoliation system according to claim 1 , the at least one bipolar electrode being physically separated from, and not in physical contact with, the external power supply. 10. The bipolar exfoliation system according to claim 1 , the at least one bipolar electrode comprising a plurality of bipolar electrodes, and the system being configured such that the electric field between the first driving electrode and the second driving electrodes is configured to simultaneously control each bipolar electrode of the plurality of bipolar electrodes. 11. The bipolar exfoliation system according to claim 1 , the first driving electrode and the second driving electrode each being a stainless steel electrode. 12. A method of single-step, in situ exfoliation of multi-layer bulk black phosphorous and deposition into single-layer, few-layer, or nano-platelets phosphorene, the system comprising: providing a bipolar exfoliation system, the system comprising: a first driving electrode; a second driving electrode electrically connected to the first driving electrode through an external power supply; at least one bipolar electrode comprising the multi-layer bulk black phosphorous, the at least one bipolar electrode being disposed between the first driving electrode and the second driving electrode in a horizontal direction parallel to a lower surface of the first driving electrode; and a solvent in physical contact with the first driving electrode, the second driving electrode, and the at least one bipolar electrode; and configuring electric conditions between the first driving electrode and the second driving electrode such that one end of the at least one bipolar electrode is turned into an anodic pole and the other end of the at least one bipolar electrode is turned into a cathodic pole such that the multi-layer black phosphorous is exfoliated and deposited into the single-layer, few-layer, or nano-platelets phosphorene, the exfoliating of the multi-layer black phosphorous and the depositing into, the single-layer, few-layer, or nano-platelets phosphorene being performed simultaneously, and the solvent being deionized water without salts. 13. The method according to claim 12 , configuring the electric conditions comprising configuring a magnitude of an electric field between the first driving electrode and the second driving electrode. 14. The method according to claim 12 , configuring the electric conditions comprising configuring a direction of an electric field relative to the at least one bipolar electrode between the first driving electrode and the second driving electrode. 15. The method according to claim 12 , configuring the electric conditions comprising configuring a potential between the first driving electrode and the second driving electrode. 16. The method according to claim 12 , configuring the electric conditions comprising configuring a distance between the first driving electrode and the second driving electrode. 17. The method according to claim 12 , the at least one bipolar electrode being physically separated from, and not in physical contact with, the external power supply. 18. The method according to claim 12 , molecules of the solvent being oxidized at the anodic pole of the at least one bipolar electrode and reduced at the cathodic pole of the at least one bipolar electrode, and two faradaic reactions occurring at the anodic pole and the cathodic pole, respectively, of the at least one bipolar electrode. 19. The method according to claim 12 , the at least one bipolar electrode comprising a plurality of bipolar electrodes, and each bipolar electrode of the plurality of bipolar electrodes being simultaneously controlled by the electric conditions between the first driving electrode and second driving electrode. 20. A method of single-step, in situ exfoliation of multi-layer bulk black phosphorous and deposition into single-layer, few-layer, or nano-platelets phosphorene, the method comprising: providing a bipolar exfoliation system, the system comprising: a first driving electrode; a second driving electrode electrically connected to the first driving electrode through an external power supply; at least one bipolar electrode comprising the multi-layer bulk black phosphorous, the at least one bipolar electrode being disposed between the first driving electrode and the second driving electrode in a horizontal direction parallel to a lower surface of the first driving electrode; and a solvent in physical contact with the first driving electrode, the second driving electrode, and the at least one bipolar electrode; and configuring electric conditions between the first driving electr