KR100655978B1 - Hydrogen sensor using Pd nano-wire - Google Patents

Abstract

The present invention relates to a hydrogen sensor using palladium nanowires, wherein the crystalline nanowires are arranged regularly on a silicon substrate, arranged on a titanium metal film on the silicon substrate, the top of the nanowires and the titanium By producing a hydrogen sensor that can measure the electrical resistance by forming electrodes on the metal film, it is possible to accurately measure the hydrogen concentration of 4% or less, and the structure is simple, not only saves cost, but also response speed It also relates to a hydrogen sensor using very fast palladium nanowires.

Palladium Nano Rod, Hydrogen Sensor, Silicon Substrate, Titanium Metal Film, Electrode

Description

Hydrogen sensor using Palladium nano wires {Hydrogen sensor using Pd nano-wire}             

1 is a schematic view showing a hydrogen sensor using palladium nanowires according to the present invention,

2 is a view showing the operating principle of the hydrogen sensor using the palladium nanowires according to the present invention,

3 is a view showing a hydrogen sensor using a conventional palladium nanowires.

<Explanation of symbols for the main parts of the drawings>

10: hydrogen sensor 11: nanowire

12 silicon substrate 13 titanium metal film

14a, 14b: electrode

The present invention relates to a hydrogen sensor using palladium nanowires, and more specifically, by making palladium into a regularly arranged form of nanowires and using it as a hydrogen sensor, the structure is simple and the cost is reduced, as well as the response The speed also relates to a hydrogen sensor using fast palladium nanowires.

Conventional hydrogen sensors can be classified into catalytic combustion sensors, semiconductor sensors, electrochemical sensors, palladium field effect transistor (FET) sensors, and palladium resistance sensors. have.

The contact combustion sensor is a sensor that measures the difference in temperature generated when hydrogen is burned while passing through a particle carrying a heated catalyst, using a Wheatstone bridge, and is the most widely used sensor. .

This sensor can be used to measure 1 ~ 5% hydrogen concentration, and it can be used as a safety sensor. The response speed is also fast within 10 seconds, but it has a disadvantage of being expensive.

The semiconductor sensor is a sensor that measures the change in resistance to hydrogen adsorption using a metal oxide semiconductor.

The sensor can be used for general purposes, but it is not suitable as a hydrogen sensor for fuel cells.

The electrochemical sensor constitutes an electrochemical cell using hydrogen as a fuel, generates a current while simultaneously supplying oxygen as a reducing agent, and measures the current to obtain a concentration of hydrogen.

The sensor is capable of measuring accurate concentrations, but its price is so high that it is not suitable as a hydrogen sensor for fuel cell vehicles.

The palladium FET sensor is a sensor configured by using a metal palladium that is very sensitive to hydrogen as a gate. The palladium FET sensor converts the palladium absorbed hydrogen into a current and voltage characteristic signal by using a slight resistance change. Measure the concentration of hydrogen.

The sensor can be used as a safety sensor because it can measure very low concentrations, but it has a disadvantage in that the structure is rather complicated.

The palladium resistance sensor is a sensor in which the concentration of hydrogen is directly determined by directly measuring a change in the resistance of palladium according to the absorption of hydrogen, and the structure thereof is simple, but a short response time is a disadvantage.

Among these conventional hydrogen sensors, the contact combustion sensor is known to be the closest to practical use, and the contact combustion sensor has high stability because it is superior to other types of sensors in terms of response speed and selectivity. Can be.

In addition, although the response speed is faster than other types of sensors due to the operation principle of the contact combustion sensor, it can be said to exhibit particularly excellent performance because it can respond to gases capable of oxidation other than hydrogen in terms of selectivity. The biggest problem of the contact combustion sensor is that the price is high, the power consumption is high, and the driving circuit is complicated.

Meanwhile, since a hydrogen sensor using palladium nanowires was introduced in 2001 to the journal Science (F. Favier, et al., Science 293, 2227 (2001)), many studies have been conducted. The sensor has attracted much attention because of its fast response time to hydrogen within 1 second, little power consumption, and the ability to operate at room temperature.

In addition, the sensor exhibits improved performance because of its differentiation from the conventional palladium sensor.

The palladium nanowires used in this sensor are composed of a large number of palladium nanoparticles that form a single wire. When hydrogen is injected, each of the palladium nanoparticles expands in volume, and the broken nanoparticles expand in volume. As it is connected while being used to reduce the resistance of the nanowires, as shown in Figure 3, several strands of palladium nanowires are connected between both electrodes, flowing a small current continuously, hydrogen atmosphere The palladium particles occlude hydrogen and expand in volume, thereby reducing the total electrical resistance and detecting the amount of hydrogen.

This is a phenomenon in which a conventional palladium resistance sensor is completely different from the increase in resistance when hydrogen is injected. The response speed is also increased by using this method, and the reaction of gas such as carbon monoxide affects the detection of hydrogen. The impact can also be reduced.

However, it is always difficult to make a uniform form of palladium nanowires, hydrogen concentration is less than 4% can not be measured, the higher the concentration of hydrogen, there is a problem that the response speed is slow.

Therefore, the present invention is invented to solve the above problems, the crystalline nanowires are arranged regularly on a silicon substrate, but arranged on a titanium metal film on the silicon substrate, the top of the nanowires And by forming an electrode on each of the titanium metal film to produce a hydrogen sensor that can measure the electrical resistance, it is possible to accurately measure the hydrogen concentration of less than 4%, and the structure is simple, not only can save costs It is an object of the present invention to provide a hydrogen sensor using palladium nanowires having a very fast response speed.

Hereinafter, the features of the present invention for achieving the above object are as follows.

Hydrogen sensor using the palladium nanowires according to the present invention, the crystalline nanowires 11 are arranged regularly on the silicon substrate 12, on the titanium metal film 13 on the silicon substrate 12 And the electrodes 14a and 14b are formed on the top of the nanowire 11 and the titanium metal film 13, respectively, so that the electrical resistance can be measured.

Particularly, when the nanowire 11 absorbs hydrogen and expands in volume, the distance between the nanowires 11 becomes close to reduce electrical resistance between the electrodes 14a and 14b. It is characterized by.

Hereinafter, the configuration of the present invention with reference to the accompanying drawings in detail.

1 is a schematic view showing a hydrogen sensor using a palladium nanowire according to the present invention, Figure 2 is a view showing the operating principle of the hydrogen sensor using a palladium nanowire according to the present invention.

Hydrogen sensor using the palladium nanowires according to the present invention, using the palladium nanowires 11 similar to those described in the prior invention, but the nanowires 11 used in the present invention is a nanowire 11 consisting of broken nanoparticles It is not a crystalline nanowire 11, that is, in the form of a nano-sized rod, a large number of nanowires 11 are configured in a regular arrangement.

At this time, the size of the nanowire 11 is a cylindrical shape having a diameter of about 80 nanometers (nm), the interval between each nanowire 11 is about several nanometers (nm) to 100 nanometers (nm) )

In the hydrogen sensor 10 using such palladium nanowires, the crystalline nanowires 11 are regularly arranged on the silicon substrate 12, more specifically, on the silicon substrate 12. It is arranged on the titanium metal film 13, the electrode 14a is formed on the top.

In addition, another electrode 14b is formed on the titanium metal film 13 to form an operating structure capable of measuring an electrical resistance together with the electrode 14b.

In the presence of hydrogen, the nanowires absorb hydrogen and become palladium hydride, which expands to about 3.5% in volume.
At this time, the resistance of the palladium nanowires themselves will increase, but due to the expanded volume, the adjacent nanowires will stick to each other, and eventually the resistance of the entire arrangement will decrease.
For example, the distance between nanowires is a few nanometers, so when the nanowires expand in volume, the nanowires stick together. Eventually, the resistance is proportional to the length and inversely proportional to the area. Since this increases several times, the resistance decreases.
This decrease in resistance occurs because the resistance is larger than the increase in resistance caused by the absorption of hydrogen by palladium.

At this time, the titanium metal film 13 is a film for growing the palladium nanowires 11 from the silicon substrate 12, and is connected to the electrode 14a formed on the upper end of the palladium nanowires 11 and above. It serves to connect the electrodes 14b to each other.

On the other hand, when the hydrogen disappears, the hydrogen is released again from the palladium nanowires 11, and returns to the original resistance.

At this time, since the surface area of the palladium nanowires 11 is very large, hydrogen can be introduced and exited very quickly, and thus the response speed is also very fast.

In addition, the spacing between the arranged nanowires 11 is not constant, so that the relatively close intervals and distant intervals, which allow to measure the concentration of hydrogen from a low concentration to a high concentration.

As described above, according to the hydrogen sensor using the palladium nanowires according to the present invention, in addition to the advantage that the response speed is faster than the conventional hydrogen sensor, the structure is simple and low price, due to the simplicity of the structure to increase the durability In particular, there is an effect that can minimize the effects of other gases in detecting the concentration of hydrogen.

Claims (2)

Arrange the crystalline nanowires 11 on the silicon substrate 12 regularly, on the titanium metal film 13 on the silicon substrate 12, the top of the nanowires 11 and the A hydrogen sensor using palladium nanowires, characterized in that the electrodes 14a and 14b are formed on the titanium metal film 13 to measure electrical resistance. The method according to claim 1, When the nanowire 11 absorbs hydrogen and expands in volume, the distance between the nanowires 11 becomes close, so that the electrical resistance between both electrodes 14a and 14b is reduced. Hydrogen sensor using palladium nanowire.

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