METHOD FOR HIGH PRESSURE REGULATION AND CONTROL OF PHOTOELECTRIC DETECTION BASED ON BiOBr

1 . A method for high pressure regulation and control of photoelectric detection based on BiOBr, comprising: inserting an insulation layer into a pressure chamber of a diamond anvil cell and adding BiOBr, disposing two platinum sheets on the BiOBr as an electrode, and placing a pressure-calibrating substance on a culet of the diamond anvil cell; pressurizing the pressure chamber by rotating a press bolt on the diamond anvil cell; and conducting photoelectric detection using the pressurized BiOBr. 2 . The method of claim 1 , wherein the diamond anvil cell has a culet diameter of 400 μm. 3 . The method of claim 1 , wherein the inserting an insulation layer into a pressure chamber of a diamond anvil cell comprises: placing a T301 steel sheet into the pressure chamber and pre-pressing the T301 steel sheet by a thickness of 40 μm via the diamond anvil cell; punching the pre-pressed T301 steel sheet using a laser boring device to obtain a sample chamber having a diameter of 300 μm; and filling an insulation powder in the sample chamber, and pre-pressing the sample chamber filled with the insulation powder such that the insulation powder is attached to the T301 steel sheet. 4 . The method of claim 1 , wherein the pressure-calibrating substance comprises ruby. 5 . The method of claim 4 , wherein a pressure is calibrated by a fluorescence peak of the ruby when the pressure chamber is pressurized by rotating a press bolt on the diamond anvil cell. 6 . The method of claim 1 , wherein the pressure chamber is pressurized by rotating a press bolt on the diamond anvil cell at pressure points of 1.0 GPa, 1.9 GPa, 2.5 GPa, 3.1 GPa, and 3.7 GPa. 7 . The method of claim 6 , after the pressurizing the pressure chamber by rotating a press bolt on the diamond anvil cell, further comprising: conducting an in situ high pressure photoresponse test on the BiOBr, specifically comprising: connecting one end of a copper wire to the platinum electrode, and drawing the other end of the copper wire outside the diamond anvil cell and connecting to a Keithley 2461 source meter; using the Keithley 2461 source meter as equipment for the in situ high pressure photoresponse test on the BiOBr, and using the Keithley 2461 source meter to apply a 10 V bias voltage to the BiOBr; using a pulse laser with a frequency of 1 Hz as a light source to intermittently irradiate the BiOBr, wherein an irradiation time is 0.5 s, the same as an interval time; and recording a current-time curve at each of the pressure points in a process of intermittent irradiation, determining whether a photo-responsivity and a photo-response speed of the BiOBr are enhanced according to the current-time curve, and determining a pressure applied for photoelectric detection of the BiOBr. 8 . The method of claim 7 , wherein the pulse laser irradiates the BiOBr at an optical power density of 0.3 mW/cm 2 . 9 . A system, in which the method described in claim 1 is performed, the system comprising: the diamond anvil cell including: the pressure chamber including the insulation layer, the BiOBr, the two platinum sheets, and the pressure-calibrating substance on the culet of the diamond anvil cell; and the press bolt; wherein the diamond anvil cell has a culet diameter of 400 μm. 10 . The system of claim 9 , wherein the inserting an insulation layer into a pressure chamber of a diamond anvil cell comprises: placing a T301 steel sheet into the pressure chamber and pre-pressing the T301 steel sheet by a thickness of 40 μm via the diamond anvil cell; punching the pre-pressed T301 steel sheet using a laser boring device to obtain a sample chamber having a diameter of 300 μm; and filling an insulation powder in the sample chamber, and pre-pressing the sample chamber filled with the insulation powder such that the insulation powder is attached to the T301 steel sheet. 11 . The system of claim 9 , wherein the pressure-calibrating substance includes ruby. 12 . The system of claim 11 , wherein a pressure is calibrated by a fluorescence peak of the ruby when the pressure chamber is pressurized by rotating a press bolt on the diamond anvil cell. 13 . The system of claim 9 , wherein the pressure chamber is pressurized by rotating a press bolt on the diamond anvil cell at pressure points of 1.0 GPa, 1.9 GPa, 2.5 GPa, 3.1 GPa, and 3.7 GPa. 14 . The system of claim 13 , further comprising a Keithley 2461 source meter and a pulse laser; wherein, after the pressurizing the pressure chamber by rotating a press bolt on the diamond anvil cell, the method further comprises: conducting an in situ high pressure photoresponse test on the BiOBr, comprising: connecting one end of a wire to the electrode, and drawing the other end of the wire outside the diamond anvil cell and connecting to the Keithley 2461 source meter; using the Keithley 2461 source meter as equipment for the in situ high pressure photoresponse test on the BiOBr, and using the Keithley 2461 source meter to apply a 10 V bias voltage to the BiOBr; using the pulse laser with a frequency of 1 Hz as a light source to intermittently irradiate the BiOBr, wherein an irradiation time is 0.5 s, the same as an interval time; and recording a current-time curve at each of the pressure points in a process of intermittent irradiation, determining whether a photo-responsivity and a photo-response speed of the BiOBr are enhanced according to the current-time curve, and determining a pressure applied for photoelectric detection of the BiOBr. 15 . The system of claim 14 , wherein the pulse laser irradiates the BiOBr at an optical power density of 0.3 mW/cm 2 . 16 . A method involving treatment of BiOBr material in a pressure chamber, the method comprising: inserting an insulation layer into a pressure chamber of a diamond anvil cell and adding BiOBr, disposing two platinum sheets on the BiOBr as an electrode, and placing a pressure-calibrating substance on a culet of the diamond anvil cell; pressurizing the pressure chamber by rotating a press bolt on the diamond anvil cell; and treating the BiOBr under pressurization in the pressure chamber. 17 . The method of claim 16 , wherein the diamond anvil cell has a culet diameter of 400 μm. 18 . The method of claim 16 , wherein the inserting an insulation layer into a pressure chamber of a diamond anvil cell comprises: placing a T301 steel sheet into the pressure chamber and pre-pressing the T301 steel sheet by a thickness of 40 μm via the diamond anvil cell; punching the pre-pressed T301 steel sheet using a laser boring device to obtain a sample chamber having a diameter of 300 μm; and filling an insulation powder in the sample chamber, and pre-pressing the sample chamber filled with the insulation powder such that the insulation powder is attached to the T301 steel sheet. 19 . The method of claim 16 , further comprising conducting an in situ high pressure photoresponse test on the BiOBr, including: connecting one end of a wire to the electrode, and drawing the other end of the wire outside the diamond anvil cell and connecting to a Keithley 2461 source meter; using the Keithley 2461 source meter as equipment for the in situ high pressure photoresponse test on the BiOBr, and using the Keithley 2461 source meter to apply a 10 V bias voltage to the BiOBr; using a pulse laser with a frequency of 1 Hz as a light source to intermittently irradiate the BiOBr, wherein an irradiation time is 0.5 s, the same as an interval time; and recording a current-time curve at each of the pressure po