Single-step, inexpensive, scalable, and eco-friendly methods and systems for exfoliation and deposition of 2D reduced phosphorene nanosheets are provided, as well as deposited phosphorene nanosheets with high specific capacitance. The exfoliation and deposition can be in situ and can include exfoliation from bulk black phosphorus (BP) into a solvent and deposition onto a negative feeding electrode. The positive feeding electrode can be a noble metal, such as a platinum wire.

Single-step, inexpensive, scalable, and eco-friendly methods and systems for exfoliation and deposition of 2D reduced phosphorene nanosheets are provided, as well as deposited phosphorene nanosheets with high specific capacitance. The exfoliation and deposition can be in situ and can include exfoliation from bulk black phosphorus (BP) into a solvent and deposition onto a negative feeding electrode. The positive feeding electrode can be a noble metal, such as a platinum wire.

A method of producing black phosphorus which includes the steps of: weighing and mixing reaction raw materials which comprises metallic tin, red phosphorus and monocrystalline iodine, wherein a weight ratio of tin: red phosphorus: iodine is 0.6-3.5: 5-45: 0.1-0.8; feeding the mixture to a high-temperature resistant metal reaction tube; removing air by introducing inert gas and sealing the reaction tube tightly; placing the metal reaction tube inside a muffle furnace for carrying out calcination reaction by first increasing a temperature at a preset rate to a maximum temperature and keeping warm and then decreasing a temperature at a preset rate and keeping warm, then to room temperature so that the black phosphorus is produced. The conversion rate is very high and the quality of the produced product is classified as high quality.

A method of producing black phosphorus which includes the steps of: weighing and mixing reaction raw materials which comprises metallic tin, red phosphorus and monocrystalline iodine, wherein a weight ratio of tin: red phosphorus: iodine is 0.6-3.5: 5-45: 0.1-0.8; feeding the mixture to a high-temperature resistant metal reaction tube; removing air by introducing inert gas and sealing the reaction tube tightly; placing the metal reaction tube inside a muffle furnace for carrying out calcination reaction by first increasing a temperature at a preset rate to a maximum temperature and keeping warm and then decreasing a temperature at a preset rate and keeping warm, then to room temperature so that the black phosphorus is produced. The conversion rate is very high and the quality of the produced product is classified as high quality.

A device for producing black phosphorus which includes a reactor having one end connected to a feeding pipe and another end connected to a discharge pipe; a propeller blade unit including a rotating shaft mounted between the two ends of the reactor and a blade element mounted on the rotating shaft; a motor connected to the rotating shaft for controlling a rotation speed of the blade element; a heating device enclosing the reactor at an outer side and defines the reactor into a plurality of heating zones; and an inert gas input connected to the discharge pipe. The device is simple and safe in operation, can optimize the production process at low cost, and has high level of automation, thus facilitating a continuous production of black phosphorus under normal pressure.

A device for producing black phosphorus which includes a reactor having one end connected to a feeding pipe and another end connected to a discharge pipe; a propeller blade unit including a rotating shaft mounted between the two ends of the reactor and a blade element mounted on the rotating shaft; a motor connected to the rotating shaft for controlling a rotation speed of the blade element; a heating device enclosing the reactor at an outer side and defines the reactor into a plurality of heating zones; and an inert gas input connected to the discharge pipe. The device is simple and safe in operation, can optimize the production process at low cost, and has high level of automation, thus facilitating a continuous production of black phosphorus under normal pressure.

A low pressure process for producing thin film crystalline black phosphorus on a substrate and a black phosphorus thin film made by the process. The process includes flowing a phosphorus-containing gas into a deposition chamber and depositing phosphorus from the phosphorus-containing gas onto the substrate in the chamber. The substrate is selected from (i) a gold substrate, a gold-tin alloy substrate, a silver substrate and a copper substrate and (ii) a substrate comprising a thin film of metal selected from gold, tin, silver, copper and alloys of the foregoing metals. The substrate and phosphorus are heated to a temperature ranging from about 350 to less than about 500 C. to form a phosphorus intermediate composition. The substrate and intermediate composition are heated to a temperature of greater than 500 C. to less than about 1000 C. convert the metal phosphorus intermediate composition to the black phosphorus thin film.

A low pressure process for producing thin film crystalline black phosphorus on a substrate and a black phosphorus thin film made by the process. The process includes flowing a phosphorus-containing gas into a deposition chamber and depositing phosphorus from the phosphorus-containing gas onto the substrate in the chamber. The substrate is selected from (i) a gold substrate, a gold-tin alloy substrate, a silver substrate and a copper substrate and (ii) a substrate comprising a thin film of metal selected from gold, tin, silver, copper and alloys of the foregoing metals. The substrate and phosphorus are heated to a temperature ranging from about 350 to less than about 500 C. to form a phosphorus intermediate composition. The substrate and intermediate composition are heated to a temperature of greater than 500 C. to less than about 1000 C. convert the metal phosphorus intermediate composition to the black phosphorus thin film.

A composition includes a few-layer phosphorene nanomaterial comprising at least one of mono-, bi-, and n-layer phosphorene nanosheets, where n is an integer selected from 3 to 6; deoxygenated water; and at least one amphiphilic surface active component.

A composition includes a few-layer phosphorene nanomaterial comprising at least one of mono-, bi-, and n-layer phosphorene nanosheets, where n is an integer selected from 3 to 6; deoxygenated water; and at least one amphiphilic surface active component.