KR20210019547A - Metal powder, its manufacturing method, and sintering temperature prediction method - Google Patents

Abstract

One of the problems is to provide a metal powder containing metal particles in which the concentration and distribution of sulfur are controlled, and a method for producing the same. A method of making a metal powder is provided. This method includes producing metal chloride gas by chlorination of metal with chlorine and reducing metal chloride as a gas in the presence of a gas containing sulfur to produce metal particles. The reduction is such that the bulk concentration of sulfur, which is a metal particle, is 0.01% by weight or more and 1.0% by weight or less, and the local concentration of sulfur at a position 4 nm from the surface of the metal particle is 2 atomic% or more. The bulk concentration and the local concentration are respectively estimated by an inductively coupled plasma emission spectroscopic analyzer and an energy dispersive X-ray spectrometer provided in a scanning transmission electron microscope.

Description

Metal powder, its manufacturing method, and sintering temperature prediction method

One of the embodiments of the present invention relates to a metal powder and a method for producing the same. Alternatively, one of the embodiments of the present invention relates to a method for controlling the quality of a metal powder, a method for estimating properties of the metal powder, or a method for predicting a sintering temperature.

Aggregates containing fine metal particles (hereinafter, metal powders) are used in various fields, and metal powders of metals exhibiting high conductivity, such as copper, nickel, and silver, are, for example, inside a multilayer ceramic capacitor (MLCC). It is widely used as a raw material for electronic components such as electrodes. MLCC has a lamination of a ceramic layer including a dielectric material and an internal electrode including a metal as a basic structure. This lamination is formed by alternately applying a dispersion liquid containing a dielectric material and a dispersion liquid containing a metal powder, followed by heating, and sintering the dielectric material and the metal powder. For example, Patent Document 1 or Patent Document 2 discloses a method for controlling the sintering characteristics of a metal powder during heating.

Patent Document 1: Japanese Patent Laid-Open Publication No. 11-80816 Patent document 2: Japanese Patent Laid-Open No. 2014-189820

One of the embodiments of the present invention is to provide a metal powder containing metal particles in which the concentration and distribution of sulfur are controlled, and a method for producing the same. Another object of the present invention is to provide a metal powder having a high sintering start temperature and a method for producing the same. Another object of the present invention is to provide a metal powder having a small variation in sintering start temperature and a method for producing the same. Another object of the present invention is to provide a method for quality control of metal powder, a method for estimating properties of metal powder, or a method for predicting sintering temperature.

One of the embodiments according to the present invention is a metal powder. This metal powder contains metal particles including metal and sulfur. The bulk concentration of sulfur in the metal particles is 0.01% by weight or more and 1.0% by weight or less, and the local concentration of sulfur at a position 4 nm from the surface of the metal particles is 2 atomic% or more. The bulk concentration and the local concentration are respectively estimated by an inductively coupled plasma emission spectroscopic analyzer and an energy dispersive X-ray spectrometer provided in a scanning transmission electron microscope.

One of the embodiments related to the present invention is a method of manufacturing a metal powder. This method includes producing metal chloride gas by chlorination of metal with chlorine and reducing metal chloride as a gas in the presence of a gas containing sulfur to produce metal particles. The reduction is such that the bulk concentration of sulfur, which is a metal particle, is 0.01% by weight or more and 1.0% by weight or less, and the local concentration of sulfur at a position 4 nm from the surface of the metal particle is 2 atomic% or more. The bulk concentration and the local concentration are respectively estimated by an inductively coupled plasma emission spectroscopic analyzer and an energy dispersive X-ray spectrometer provided in a scanning transmission electron microscope.

One of the embodiments according to the present invention is a method of predicting the sintering temperature of a metal powder. This method involves measuring the local concentration of sulfur at a position 4 nm from the surface of metal particles selected from metal powders. The local concentration of sulfur is measured using a scanning transmission electron microscope equipped with an energy dispersive X-ray spectrometer.

1 is a schematic cross-sectional view of a reduction furnace of a metal powder manufacturing apparatus according to one of the embodiments of the present invention.
2 is a diagram showing a sulfur concentration profile of metal particles included in metal powders of Examples and Comparative Examples.
3 is a diagram showing the relationship between the sintering start temperature of metal powders of Examples and Comparative Examples and the bulk concentration of sulfur.

Hereinafter, each embodiment of the present invention will be described with reference to the drawings and the like. However, the present invention may be implemented in various aspects without departing from the gist thereof, and is not intended to be limited to the description of the embodiments exemplified below.

In the drawings, the width, thickness, shape, etc. of each part may be schematically expressed as compared to the actual mode in order to make the description more clear, but this is only an example and does not limit the interpretation of the present invention. In the present specification and each of the drawings, elements having functions similar to those described with respect to the preceding drawings are denoted by the same reference numerals, and redundant descriptions are omitted.

<First embodiment>

In this embodiment, the structure and characteristics of the metal powder 100 which is one of the embodiments related to the present invention will be described.

1. Structure

The metal powder 100 is an aggregate of a plurality of metal particles 102, and the metal particles 102 include metal and sulfur. The metal is selected from nickel, copper, silver and the like, and is generally nickel. The number average particle diameter of the metal powder 100 may be 50 nm or more and 400 nm or less, 100 nm or more and 300 nm or less, or 100 nm or more and 250 nm or less. In other words, the average value of the particle diameters of the plurality (eg, 600) of the metal particles 102 selected from the metal powder 100 may be included in the above range as the number average particle diameter of the metal powder 100. As the number average particle diameter, for example, by observing the metal particles 102 contained in the metal powder 100 with a scanning electron microscope, measuring the particle diameter of a plurality of particles (e.g., 600 particles), the average value Can be used. The particle diameter is the diameter of the smallest circle inscribed with the particle.

The metal powder 100 contains sulfur. Specifically, the bulk concentration of sulfur in the metal powder 100 is 0.01% by weight or more and 1.0% by weight or less, or more than 0.01% by weight and 0.6% by weight or less, or 0.15% by weight or more and 0.6% by weight or less, or 0.16% by weight or more and 0.6 It is less than or equal to weight. In other words, the average value of the sulfur bulk concentration of the plurality of metal particles 102 selected from the metal powder 100 (for example, the number corresponding to 0.5 g) falls within the above-described range. Here, the bulk concentration of sulfur is a weight ratio of sulfur to the weight of the metal particles 102. The average of the sulfur bulk concentration of one metal particle 102 selected from the metal powder 100 or the sulfur bulk concentration of the plurality of metal particles 102 is calculated as the bulk concentration of the metal powder 100.

The bulk concentration of sulfur can be measured by inductively coupled plasma emission spectroscopy. For example, it may be measured using an inductively coupled plasma emission spectroscopic analyzer (SPS3100) manufactured by SII Nano Technology Co., Ltd. To illustrate a specific measurement method, first, after dissolving the metal powder 100 with an acid, the bulk concentration of sulfur can be obtained by performing ICP emission spectroscopic analysis at a measurement wavelength of 182.036 nm.

The metal particles 102 contain sulfur not only in the vicinity of the surface but also in the interior relatively far away from the surface toward the inside of the particles. Specifically, the concentration of sulfur decreases from the surface of the metal particles 102 to the inside, but the concentration of sulfur at a position of 4 nm from the surface (hereinafter, the concentration of sulfur at a specific position of the metal particles 102 is Local concentration) is 2 atomic percent or more. Further, the concentration of sulfur at a position of 4 nm from the surface may be 4 atomic% or less. The average value of the local concentration of sulfur at the above-described position of a plurality of (eg, ten) metal particles 102 selected from the metal powder 100 is included in the above-described range.

In addition, a position where the local concentration is 1/2 of the local concentration of sulfur on the surface of the metal particles 102 (hereinafter, halved depth) may exist in a range of 2 nm or more and 4 nm or less from the surface. That is, the average value of the halving depth of the plurality of (eg, 10) metal particles 102 selected from the metal powder 100 may be included in the above-described range.

The above-described local concentration of sulfur may be estimated by, for example, an energy dispersive X-ray spectroscope (STEM-EDS) provided in a scanning transmission electron microscope. To illustrate a specific measurement method, first, the metal powder 100 is dispersed in a resin to cure the resin. Thereafter, a cross section is exposed using a cross section polisher (CP), and a thin film sample is prepared by planar sampling using a focused ion beam (FIB). The thickness of the sample is about 100 nm, and the metal particles 102 are formed into a thin film having this thickness. Thereafter, the obtained thin film may be subjected to EDS measurement on a straight line passing through the center of the metal particle 102 to obtain a local concentration. As the EDS measurement conditions, for example, an acceleration voltage of 200 kV, a probe diameter of 1 nm, a pitch width of 3 nm, and a measurement time per point of 15 seconds can be selected.

2. Characteristics

The metal powder 100 including the metal particles 102 has a high bulk concentration of sulfur, and the sintering start temperature due to the wide distribution of sulfur in the surface layer portion of the metal particles 102, for example, 600°C. It shows a high sintering start temperature in the above range. Moreover, the sintering start temperature may be 700°C or less. Based on the above characteristics, when the local concentration of sulfur in the surface layer of the metal particles is measured, and the local concentration satisfies the above-described conditions, it can be determined that the sintering start temperature of the metal powder as an aggregate of the metal particles is high. Thus, the present embodiment provides an effective method for predicting the properties of a metal powder.

As shown in the examples, it is suggested that the wide distribution of sulfur and the high bulk concentration are correlated with the high sintering initiation temperature of the metal powder 100. Further, for example, when the bulk concentration of sulfur is the same, it is advantageous from the viewpoint of improving the sintering start temperature if the sulfur distribution is wide (if sulfur exists from the surface to the depth). When this is used, the sintering start temperature of the metal powder can be estimated or estimated by measuring the distribution and bulk concentration of the sulfur in the surface layer. For example, when metal particles arbitrarily selected from metal powders are analyzed by STEM-EDS, and the condition that the local concentration of sulfur at 4 nm from the surface of the metal particles is 2 atomic% or more is satisfied, the metal It can be estimated that the sintering temperature of the metal powder containing particles is 600°C or higher. In other words, according to the present embodiment, the sintering behavior of the metal powder can be estimated by measuring the sulfur concentration of the surface layer without sintering the metal powder, and an effective method for controlling the quality of the metal powder can be provided. .

As described above, for example, when metal powder is used as a raw material for internal electrodes of MLCC, a dispersion liquid containing a dielectric and a dispersion liquid containing a metal powder are alternately applied, followed by firing. The dispersion liquid containing a dielectric material contains Ba or Ti-based oxide powder or a polymer material that functions as a binder, a solvent, a dispersant, and the like, and the dispersion containing the metal powder contains not only metal powder but also a binder, solvent, and dispersant. During firing, such a binder, solvent, and dispersant are evaporated or decomposed, and at the same time, oxide powder or metal powder is sintered to provide a dielectric film and an internal electrode, respectively. In general, since the sintering start temperature of the dielectric is higher than the sintering start temperature of the metal powder, sintering of the metal powder is first started during firing. As a result, a gap is formed between the dielectric and the internal electrode during firing, and due to this gap, peeling may occur between the internal electrode and the dielectric film, which causes a decrease in the characteristics or yield of the MLCC.

On the other hand, since the metal powder 100 according to the present embodiment exhibits a high sintering start temperature, sintering starts at a temperature closer to the sintering start temperature of the oxide powder or the like. As a result, it is possible to ensure high adhesion between the internal electrode and the dielectric during firing, thereby suppressing peeling. For this reason, the metal powder 100 may be used as a raw material for providing various electronic components having excellent properties.

As described above, since the sintering behavior of the metal powder can be estimated without sintering according to the present embodiment, it is possible to provide a quality control method for producing a highly reliable metal powder as a material for MLCC electrodes.

<2nd embodiment>

In this embodiment, an example of a method of manufacturing the metal powder 100 will be described.

The metal powder 100 is manufactured using a vapor phase method. That is, it is produced by reducing the vapor of a metal chloride obtained by chlorinating a metal (hereinafter, simply referred to as chloride) or a vapor obtained by heating a metal chloride, in the presence of a sulfur-containing gas. However, since chloride vapor of high purity can be obtained and the supply amount of the chloride vapor can be stabilized, it is more preferable to generate the vapor of the chloride with a metal chloride. A well-known device (chlorination furnace) for chlorinating metals may be used, so its description will be omitted.

Fig. 1 shows a schematic cross-sectional view of a reduction device 110, which is an apparatus for reducing chloride. The reduction device 110 functions to reduce the chloride to generate the metal powder 100 and to introduce sulfur into the metal particles 102 at the same time. The reduction device 110 includes a reduction furnace 112 and a heater 114 for heating the reduction furnace 112 in a basic configuration. A first transport pipe 116 is connected to the reduction furnace 112, through which metal chloride gas is introduced into the reduction furnace 112. The reduction furnace 112 is further provided with a first gas introduction pipe 118 for supplying a reducing gas such as hydrogen, hydrazine, ammonia, methane, or the like. A reducing gas supply source (not shown) is connected to the first gas introduction pipe 118. The valve 120 is attached to the first gas introduction pipe 118, thereby controlling the supply amount of the reducing gas.

A second gas introduction pipe 122 for supplying a sulfur-containing gas is provided in the first transport pipe 116. A sulfur-containing gas supply source (not shown) is connected to the second gas introduction pipe 122 through a valve 124, and the supply amount thereof is adjusted by the valve 124. With this configuration, the reducing gas can be brought into contact with the mixed gas of the chloride gas and the sulfur-containing gas. The first gas introduction pipe 118 and the second gas introduction pipe 122 may be connected to an inert gas supply source, whereby an inert gas as a carrier gas is mixed to convert a reducing gas or a sulfur-containing gas into the reduction furnace 112 Can supply to With this configuration, a mixed gas of a chloride gas and a sulfur-containing gas is supplied to the reduction furnace 112. Although not shown, the second gas introduction pipe 122 is connected to the reduction furnace 112 without being connected to the first transport pipe 116, and the chloride gas and the sulfur-containing gas are individually supplied to the reduction furnace 112. You may do it.

In the reduction furnace 112 heated by the heater 114, chloride is reduced by a reducing gas, thereby generating metal particles 102, and at the same time, sulfur derived from the sulfur-containing gas is transferred to the metal particles 102. ). In addition, it is preferable to introduce the chloride gas not isolated, but produced in a chlorination furnace (not shown). By setting it as such a form, chlorination and reduction can be performed continuously, and a metal powder can be produced efficiently.

The reduction furnace 112 is further provided with a third gas introduction pipe 126 for supplying the cooling gas to the reduction furnace 112. The third gas introduction pipe 126 is preferably installed at a position spaced apart from the first transport pipe 116. For example, when the first transport pipe 116 is installed above the reduction furnace 112, the third gas introduction pipe 126 is installed below the reduction furnace 112. An inert gas such as nitrogen or argon may be used as the cooling gas, and such a gas supply source (not shown) is connected to the third gas introduction pipe 126. The flow rate of the cooling gas is controlled by valve 128. By supplying a cooling gas, it is possible to control the growth of the metal particles 102 formed in the reduction furnace 112. The metal powder 100 is transported to a separation device or a recovery device through the second transport pipe 130 by the cooling gas, and is isolated and purified.

When performing reduction, the reduction furnace 112 is heated by the heater 114, and the gas of metal chloride and the sulfur-containing gas are transferred through the first transport pipe 116 and the second gas introduction pipe 122 to the reduction furnace ( At the same time as introducing into 112), the reducing gas is supplied to the reduction furnace 112 through the first gas introduction pipe 118. The heating temperature of the reduction furnace 112 is preferably lower than the melting point of the metal, and is, for example, selected in the range of 800°C to 1,100°C. Thereby, the metal produced in the reduction furnace 112 can be extracted into the metal particles 102 in a solid state. The amount of the reducing gas supplied to the reduction furnace 112 is adjusted using the valve 120 so that it is stoichiometrically equal to or slightly excess with the supplied metal chloride.

As the sulfur-containing gas, a gas containing a component selected from hydrogen sulfide, sulfur dioxide or sulfur halide may be mentioned. Examples of the sulfur halide include S _n Cl ₂ (n is an integer of 2 or more), SF ₆ , SF ₅ Cl, SF ₅ Br, and the like. Among these, sulfur dioxide, which is easy to handle, is preferable. The flow rate of the sulfur-containing gas is adjusted by using the valve 124 to be 0.01% by weight or more and 1.0% by weight or less compared to the metal powder generated from chloride per unit time supplied to the reduction furnace 112.

By adopting the above-described method, it is possible to control the bulk concentration and local concentration of sulfur within the ranges described in the first embodiment, and metal particles containing sulfur at a high concentration not only near the surface but also inside spaced from the surface ( 102), and the metal powder 100 containing the metal particles 102 may be prepared.

Example

1. Example 1

This embodiment shows an example in which the metal powder 100 is manufactured by applying the manufacturing method described in the second embodiment.

Nickel chloride gas is generated by reacting chlorine gas and nickel in a chlorination furnace, and the reduction furnace 112 is heated to 1,100°C, and nickel chloride gas, a sulfur-containing gas, is sulfur dioxide in the first transport pipe 116 connected to the chlorination furnace. A mixed gas of gas and nitrogen gas was introduced into the reduction furnace 112 at a flow rate of 2.8 m/sec (1,100°C conversion). At the same time, hydrogen was introduced into the reduction furnace 112 at a flow rate of 2.2 m/s (in terms of 1,100°C) through the first gas introduction pipe 118. Nitrogen was used as the cooling gas and supplied from the third gas introduction pipe 126. The obtained nickel powder (number average particle diameter: 190 nm) was purified using a generation apparatus or the like (not shown). The bulk concentration of sulfur to the obtained nickel powder was 0.15% by weight.

As Comparative Example 1 to this Example 1, nickel powder obtained by performing sulfur treatment on nickel powder obtained by performing reduction of nickel chloride in the absence of a sulfur-containing gas was used, and the sulfur concentration thereof was measured. . The nickel powder of Comparative Example 1 was produced by preparing a nickel powder without introducing a sulfur-containing gas into the reduction furnace 112 in the above example, and then performing the following post-processing.

That is, to the slurry obtained in the process of purifying nickel powder (number average particle diameter: 190 nm) prepared in the absence of a sulfur-containing gas, a thiourea aqueous solution was added so that the sulfur content of the nickel powder was 0.15% by weight, and stirred for 30 minutes. Thereafter, the slurry was dried with an airflow dryer to obtain nickel powder of Comparative Example 1.

The nickel powders of Example 1 and Comparative Example 1 were measured for the local concentration of sulfur in the depth direction from the surface using STEM-EDS. The measurement was performed using a scanning transmission electron microscope (JEM-2100F manufactured by Japan Electronics Co., Ltd.) equipped with an energy dispersive X-ray spectroscopy analyzer (JED-2300T manufactured by Japan Electronics Corporation). The obtained results are shown in Table 1 and FIG. 2.

Local concentration of sulfur in nickel powder Local concentration of sulfur (atomic%) 2nm 4nm 6nm Example 1 3.9 2.5 0.9 Comparative Example 1 3.1 0.9 0.1

As shown in Table 1 and FIG. 2, in the nickel powder of Comparative Example 1, the local concentration of sulfur on the surface is higher than that of Example 1, but as the depth from the surface increases, that is, as it gets closer to the inside It was found to decrease rapidly. In contrast, in the nickel powder of Example 1, although the local concentration of sulfur on the surface was low, the reduction rate in the depth direction was low, and it was confirmed that sulfur was also distributed inside the nickel powder. In Example 1, the half-reduction depth was 3.2 nm.

From these results, it was found that by using the manufacturing method according to the embodiment of the present invention, a metal powder in which sulfur is distributed to a deeper position can be obtained.

2. Example 2

In Example 2, the influence of the bulk concentration of sulfur on the sintering start temperature was examined. The same method as in Example 1 was applied, and the flow rate of the sulfur-containing gas was changed from 1.7 m/sec to 2.2 m/sec (1,100°C equivalent) to prepare nickel powders having various sulfur bulk concentrations. Similarly, using the same method as in Comparative Example 1 described in Example 1, the concentration or addition amount of the thiourea aqueous solution was changed to produce nickel powder having various sulfur bulk concentrations as Comparative Example 2. Measurement of the bulk concentration of sulfur was performed in the same manner as in Example 1.

The measurement of the sintering start temperature was performed by a scanning electron microscope (SU-5000 manufactured by Hitachi High Technology) equipped with a heating stage (Murano 525 heating stage manufactured by Gatan). To illustrate a specific method, first, metal powder 100 was molded into pellets of φ5 mm×1 mm, adhered to a heating stage, and introduced into a scanning electron microscope. The heating stage was observed with a scanning electron microscope while raising the temperature step by step from room temperature to 800°C. The metal particles 102 start sintering with increasing temperature, but the temperature when at least half of the nickel powder in the field of view is sintered was taken as the sintering start temperature. The results are shown in FIG. 3.

In Comparative Example 2, it can be seen that the sintering start temperature increases as the sulfur bulk concentration increases. However, as also described in Example 1, in the metal powder of Comparative Example 2, since sulfur is not distributed at a high concentration to the inside of the metal particles, there is an upper limit on the bulk concentration of sulfur. Perhaps due to this, the bulk concentration of sulfur is at most about 0.2% by weight, and the sintering initiation temperature remains at around 500°C to 600°C.

On the other hand, it can be seen that the nickel powder of Example 2 has a higher sintering start temperature compared to Comparative Example 2. Further, in Example 2, since sulfur is distributed to the inside of the nickel particles, a high bulk concentration of sulfur can be achieved as compared with the nickel powder of Comparative Example 2. For example, in this Example 2, it is possible to obtain a metal powder in which the bulk concentration of sulfur exceeds 0.2% by weight, or even the bulk concentration of sulfur is 0.3% by weight or more. Due to this, the sintering initiation temperature of the nickel powder of Example 2 can achieve more than 600°C, and reaches about 700°C. Further, it has been found that when the bulk concentration of sulfur is the same, nickel powder having a higher sintering start temperature can be produced by applying the production method of this embodiment.

Here, it should be noted that in Example 2, when the bulk concentration of sulfur is 0.15% by weight or more, the sintering start temperature is 600°C or more, and furthermore, it is possible to achieve more than 600°C with a high probability. For this reason, by setting the bulk concentration of sulfur in the metal powder 100 to 0.15% by weight or more, even if the bulk concentration of sulfur changes significantly, the sintering start temperature is not affected, and fluctuations in the sintering start temperature can be effectively suppressed. I can. In other words, by the manufacturing method of the present embodiment, it is possible to provide a metal powder having a small variation in the sintering start temperature.

Based on the embodiments of the present invention, as long as those skilled in the art appropriately add, remove or change the design of constituent elements, or add, omit, or change conditions of steps, as long as the gist of the present invention is included. Included in the scope.

Even if an operation effect different from the operation effect derived by the aspect of each of the above-described embodiments, what is obvious from the description of the present specification or what a person skilled in the art can easily predict is interpreted as being derived by the present invention.

Reference Numerals 100: metal powder, 102: metal particles, 110: reduction device, 112: reduction furnace, 114: heater, 116: first transport pipe, 118: first gas introduction pipe, 120: valve, 122: second gas introduction pipe , 124: valve, 126: third gas introduction pipe, 128: valve, 130: second transport pipe

Claims (9)

It contains metal and metal particles containing sulfur having a bulk concentration of 0.01% by weight or more and 1.0% by weight or less,
The local concentration of sulfur at a position of 4 nm from the surface of the metal particles is 2 atomic% or more,
The bulk concentration and the local concentration are each estimated by an inductively coupled plasma emission spectroscopic analyzer and an energy dispersive X-ray spectrometer provided in a scanning transmission electron microscope,
Metal powder. The method of claim 1,
A metal powder having a number average particle diameter of 50 nm or more and 400 nm or less. The method of claim 1,
The sintering start temperature of the metal powder is 600°C or higher. The method of claim 1,
The metal is nickel, copper or silver, metal powder. Producing metal chloride gas by chlorination of the metal with chlorine, and
Generating metal particles by reducing the metal chloride as a gas in the presence of a gas comprising sulfur,
The reduction is performed so that the bulk concentration of sulfur in the metal particles is 0.01% by weight or more and 1.0% by weight or less, and the local concentration of sulfur at a position 4 nm from the surface of the metal particles is 2 atomic% or more,
The bulk concentration and the local concentration are each estimated by an inductively coupled plasma emission spectroscopic analyzer and an energy dispersive X-ray spectrometer provided in a scanning transmission electron microscope,
Method for producing metal powder. The method of claim 5,
The method, wherein the reduction is performed without isolating the metal chloride. The method of claim 5,
The method, wherein the sulfur-containing gas is a sulfur dioxide-containing gas. Measuring a local concentration of sulfur at a position of 4 nm from the surface of the metal particles selected from metal powder,
The local concentration of sulfur is measured using a scanning transmission electron microscope equipped with an energy dispersive X-ray spectrometer,
How to predict the sintering temperature of metal powder. The method of claim 8,
Further comprising the step of measuring the bulk concentration of sulfur in the metal powder,
The bulk concentration of the sulfur is measured using the scanning transmission electron microscope equipped with the energy dispersive X-ray spectrometer,
How to predict the sintering temperature of metal powder.

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