Tag: melting

Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles

About Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles:

Chemical composition:
Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles插图

Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles Properties

Other NamesTungsten Crucible, Tungsten Melting Pot
CAS No.N/A
Compound FormulaW
Molecular WeightN/A
Appearancecrucible
Melting PointN/A
Solubility in waterN/A
Density>=19.15g/cm3
Purity>=99.95%
Sizecustomized
Boling pointN/A
Specific HeatN/A
Thermal ConductivityN/A
Thermal ExpansionN/A
Young’s ModulusN/A
Exact MassN/A
Monoisotopic MassN/A
  
  

Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles Health & Safety Information

Safety WarningN/A
Hazard StatementsN/A
Flashing pointN/A
Hazard CodesN/A
Risk CodesN/A
Safety StatementsN/A
RTECS NumberN/A
Transport InformationN/A
WGK GermanyN/A
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About Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles:Chemical composition:Metal Alloy Vacuum Coating Tungsten Melting Pot Tungsten Crucibles PropertiesOther NamesTungsten Crucible, Tungsten Melting PotCAS […]

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What is the Melting Point of Potassium Chloride?

When looking for information on the melting point of potassium chloride, it is important to understand the properties of the molecule. Potassium chloride is a type of alkali metal, formed from the bonding of a Potassium atom with a Chlorine atom. It is used in a wide variety of scientific, medical, and industrial applications.

In solid state, potassium chloride has a B1 face-centered cubic structure. This structure is highly refractory at moderate pressures. Therefore, KCl is an excellent candidate for sample containment and calibration at high temperatures.

However, the melting curve of KCl at moderate pressures has not yet been validated. In order to do so, more data at lower pressures are needed. The first step in this process is to obtain an accurate measurement of the melting point at a given pressure.

This is done by obtaining a reference melting curve. Assuming the melting curve is accurate, the current-temperature relation can be used to locate the melting point. For example, if the ionic current of KCl is found to rise steeply with temperature, the point of highest current can be determined.

Several studies have investigated the influence of temperature on the ionic conduction of KCl. These results have yielded an ionic current that ranges from less than 50 mA at a low temperature to 400 mA at a high temperature.

A better design of the ionic conduction experiment is required to improve the accuracy of this measurement. Reproducibility of the measurements is achieved by identifying the steps of the press load and the resolution of the pressure transducer.


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When looking for information on the melting point of potassium chloride, it is important to understand the properties of the molecule. Potassium chloride is a […]

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The Melting Point of TiO2

TiO2 is an inorganic compound, also known as titanium(IV) oxide, that is used in a variety of applications, such as sensors for CO, H2, ozone, and formaldehyde. The melting point of TiO2 is 1840degC.

The structure of TiO2 is dependent on the annealing conditions. For example, it is possible to form a TiO2-x/TiO2-based heterostructure by annealing at 800 degC.

TiO2 is an n-type semiconductor, with a charge mobility of 0.4 cm2/V s. It has a relatively low melting point. However, it is difficult to produce large Ti3O5 crystals due to the polymorphism of titanium oxides.

In addition, TiO2 has been applied as sensing material in room temperature sensors for CO, H2, ozone, formaldehyde, and other gases. Moreover, it has been used as a sensor in the sensing of C7H8.

There are several methods for forming TiO2 structures. One method involves thermochemical treatment. Another is ion irradiation. Ion irradiation results in a change in the crystalline structure of the titanium oxide. These changes can cause the formation of latent ion tracks. Similarly, excessive local heating may also lead to the formation of latent ion tracks.

An XPS analysis showed the presence of ion beam-induced vacancies in the TiO2 lattice. These vacancies are consistent with the lateral dimension of the ion track observed in high resolution TEM images. This indicates that the ion track forms inside the TiO2 material.

The model of thermal spike induced melting predicts that this type of melting is possible. The resulting strain and distortions of the crystalline structure are manifested as shi in the Raman spectra.


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TiO2 is an inorganic compound, also known as titanium(IV) oxide, that is used in a variety of applications, such as sensors for CO, H2, ozone, […]

Continue reading