Ultrafast response hydrogen sensor

What is claimed is: 1. A method of using an ultrafast response hydrogen sensor, wherein the ultrafast response hydrogen sensor comprises: a gas path chamber; a gas mover fixed to a gas inlet of the gas path chamber; and a first hydrogen sensor and a second hydrogen sensor provided inside the gas path chamber; wherein the first hydrogen sensor and the second hydrogen sensor have identical structure and hydrogen-sensitive characteristics; wherein the gas mover is located in a straight line with the first hydrogen sensor and the second hydrogen sensor; the first hydrogen sensor and the second hydrogen sensor each have an electrical connection A and an electrical connection B, and a DC voltage is applied to the electrical connection A of the first hydrogen sensor and the electrical connection B of the second hydrogen sensor, and the electrical connection B of the first hydrogen sensor is connected to the electrical connection A of the second hydrogen sensor to form a shared electrical connection, and the shared electrical connection serves as a voltage output; wherein the method comprises: flowing the hydrogen to the gas path chamber driven via the gas mover, flowing the hydrogen past the first hydrogen sensor and the second hydrogen sensor, converting a resistance differential signal between the first hydrogen sensor and the second hydrogen sensor into a voltage differential signal; detecting the peak value of the voltage differential signal; determining response time and response rate of the ultrafast response hydrogen sensor by detecting the time from the initial state to the peak of the voltage differential signal; characterizing the hydrogen concentration based on the response time and the response rate; after the hydrogen detection is completed, when the air flows the gas path chamber through the gas mover, restoring the ultrafast response hydrogen sensor to the initial state by flowing air through the gas mover and the gas path chamber. 2. The method as recited in claim 1 , wherein a distance between the first hydrogen sensor and the second hydrogen sensor is in a range of 1 mm to 35 cm. 3. The method as recited in claim 1 , wherein a gas flow rate generated by the gas extractor is in a range of 5-500 sccm. 4. The method as recited in claim 1 , wherein a hydrogen-sensitive material of the first hydrogen sensor and the second hydrogen sensor is a palladium metal material, or a composite material consisting of a palladium metal material and at least one metal material, wherein the metal material is nickel, gold, ruthenium, cobalt or titanium. 5. The method as recited in claim 4 , wherein the composite material is a layered material or an alloy material. 6. The method as recited in claim 1 , wherein a distance between the first hydrogen sensor and the second hydrogen sensor, and a gas flow rate generated by the gas mover are adjusted to control the response time and the response rate of the ultrafast response hydrogen sensor.