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Understanding the Melting Point of Copper: A Guide to Metal Melting Temperatures

What is the melting point of copper
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Copper is one of the prominent metals used in various industries and it is important to know its melting point, This is crucial for indicating the temperature at which the metal gets plastic, and below that temperature, the metal can regain its original form when stressed or shaped. The melting temperature of copper is approximately 1,981°F (1,083°C). In other words, this is the temperature at which pure copper becomes molten. The property of copper to melt is heavily used in mechanical engineering and when fabricating wiring. When copper parts are buried in the ground, it is the best medium to use because it doesn’t corrode or get oxidized easily. Historically of course in civilizations age-age like the Egyptians to the contemporary world today metal parts have been implemented in all shapes, colors and structures so it raises the question of which forms of copper are preferred to be used. Here the dissimilarities between porous copper and reshaped copper parts will be researched. Filling the pores with copper powder is also used in research and when sown and wrapped copper wire is immersed into epoxy resin and sold in a cured state. Finally, many metallurgical properties about multiple melts and Canadians will be touched so for that matter stay focused and we will spare you further beaten phrases.

What is the melting point of copper?

What is the melting point of copper
What is the melting point of copper?

Copper is known to be a very versatile metal. It has a melting point of 1,083 °C or 1,982 °F which is a very important detail associated with pure copper. This property is very helpful in the metallurgy field by helping settlements that include the grade of complex processes, combining still others, and choosing suitable ways of fabrication. Moving forward, we will be looking at the factors that affect the melting point of copper, its changing point in its alloys as well as the melting point of other metals in increasing order. Grab a seat as I unravel something quite interesting. But do make yourself ready for this technical ride through the melting temperature spectrums of copper.

How do we know the melting point of copper in °C?

An important part of researching the properties of copper is determining its melting point. Due to an extensive amount of research work, it has been established that the melting point of copper equals about 1,083.0 °C (1,981.4 °F). Scientists and researchers employ various methods to measure the melting point accurately. These include:

Differential Scanning Calorimetry (DSC): This device permits the measurement of the heat associated with melting of the metal which in turn indicates the melting point of the metal.

Optical Methods: Optical pyesmomerty is also possible whereby the melting point of copper could be established by the appearance of black body radiation.

Thermocouples: Thermovocouples work by measuring voltage variations caused by heating-induced electrical potential. These devices can be used to verify the temperature during melting as well as the temperature at which copper turns into liquid.

Researchers using these advanced laboratory tools have been able to pinpoint that copper has a melting point thus allowing further explorations on what this Cooper does under different conditions and settings.

Why does pure copper have a specific melting point?

How does the atomic structure of copper determine its melting point? The melting point of pure copper is primarily determined by its atomic structure as well as the forces that act between its atoms. So, when the required thermal energy is provided to the copper atoms at the melting point, it overcomes the interatomic forces, thus causing the solid Copper to melt into liquid Copper. Factors that contribute to the very exact property of melting point for copper are outlined in the belonging points:

The relationship between melting point and atomic structure: The copper has FCC or face-centered cubic structure which plays a crucial role in its thermal melting and its melting point.

Role of Interatomic Forces: The metallic bond together copper atoms is considerably strong owing to the delocalized electrons distributed throughout the entire crystal lattice. This bonding mechanism accounts for the cohesive forces that hold together the copper atoms in a metallic solid.

Energy condition: At the melting point of the Cu atoms, the supplied energy is higher than the cohesive forces so that the interatomic bonding is broken and they turn into the liquid phase.

The exact melting point of pure copper is affected by these factors and is reported to be approximately 1084.62 degrees Celsius (1984.32 degrees Fahrenheit). However, it is critical to emphasize copper melting point characteristics since the presence of various impurities and alloying elements does seem to have an effect on them suggesting a need for higher-purity copper in many applications.

Comparing the melting point of copper to other metals

I am a materials scientist, so I have spent a great deal of effort determining the melting points for most metals, including copper. When assessing the melting point of copper against other metals, the composition and purity of major and minor elements within the metal should be taken into account. My research indicates that copper has a melting point that is lower than metals such as tungsten which is around 3422 degrees Centigrade. In contrast to lead, with a melting point of about 621 degrees Fahrenheit copper has a higher melting point of around 327 degrees Celsius. These comparisons clearly illustrate the range of melting points possessed by different metals and their importance in other industrial processes.

How do factors affect the melting point of copper?

How do factors affect the melting point of copper
How do factors affect the melting point of copper?

Las aleaciones, condiciones de temperatura elevada y el medio ambiente tienen gran influencia respecto al cambio de temperatura en la fusión del cobre. Por ejemplo, el cobre con aleación de otros elementos puede tener un punto de fusión más bajo o más alto dependiendo de la composición específica de la aleación. Las condiciones del medio también impactan en el punto de fusión del cobre, como el aumento de presión o la presencia de impurezas. Por ultimo, el ambiente también influye sobre el temperatura de fusión del cobre, como el caso de estar expuesto al oxígeno o a sustancias corrosivas. La comprensión de estas condiciones es importante para diferentes usos industriales y para obtener las condiciones de fusión del cobre en forma más adecuada.

Impact of Alloying on copper’s melting Temperature

The alloying elements significantly impact the melting temperature of copper. This means that copper alloyed with other metals will have a different melting point than copper itself. Whether that point is higher or lower will depend on the specific alloy. For instance, while zinc lowers the melting point, nickel or aluminum raises it. Alloys of copper may have varying melting points and this feature is important in various industrial applications without it affecting the processes of the production and even the end product. Knowing the effect of alloying on the melting temperature of the copper is vital for determining the necessary parameters that will allow for a successful melting process.

However depending on the metals that are added to copper, the melting point changes. Which in this case means the metals interacted together in the alloy. Since the melting point changes based on the additives used, the phase diagrams of copper alloys are important because they include information such as the alloying temperature that is of interest. By studying these phase diagrams, a copper alloy can be designed with the expected melting point, allowing engineers and metallurgists to make the desired properties and behaviors of alloys in various applications.

The fact that extending copper’s phase diagram with alloys does not solely depend on the constituent of the alloy can be established even at this point. The elevated melting point of copper can be caused by high pressure or the introduction of dissolved gases. Aerospace and marine alloys can corrode and are subjected to melting temperature changes from oxygen or other liquids. These parameters should be accounted for when choosing the conditions for melting a copper alloy.

To conclude, it is quite clear that when electric copper is joined for example with silver or other metals, it may as well change the copper’s melting temperature. Deformation of the geometry of the application, the melting point of the alloy, and even conditions surrounding the item such as temperature, barometric pressure, and humidity are important factors. Having an informed appreciation of any of these parameters is paramount for a variety of industrial activities and processes and also augurs well for the advancement of copper products and further the art of melting and casting them.

Role of high-temperature conditions in copper melting

Melting copper may be fun or quite a tedious process, task, but it still requires the presence of high temperatures surrounding the copper. However, this is not that difficult considering to melt copper the temperature must reach 1083 degrees which is reasonable for a lot of people. Therefore, once the unit of copper reaches this specific temperature, it will shift from its solid state to a liquid state, which can then be used for a lot of industrial tasks.

Melting the copper unit is an easy task but, there’s a catch there are certain specifications that need to be met to get that desired output:

Temperature: Now temperature plays a very crucial role in transforming the state of copper from solid to liquid and therefore the temperature required for such a transformation is above the melting point of the copper.

Heat Source: A heat source such as a furnace or kiln has to be utilized to maintain the heat that is required by copper to melt effectively.

Time: Now time plays a very crucial aspect in the entire process of melting, the time being utilized during the high temperatures determines how complete the melting is.

Crucible Material: The materials graphite and ceramics can survive at high temperatures without creating any devotion or interaction with the molten copper and therefore help the process to be a good one.

The environmental protection aspect includes the melting process of copper. It is apparent however that in some cases, producing a melting atmosphere of an inert gas ( nitrogen or argon for instance ) can be of help.

Having said all this, it is critical to point out that the task of melting copper has certain risks involved which should not be pigheadedly ignored and there is suitable equipment designed for performing such tasks. Hence, looking for the help of professionals is strongly advised before commencing the process of melting copper at home or elsewhere.

Environmental factors influencing copper’s melting temperature

Several environmental factors affect the process of melting copper and hence influence its melting temperature. These include:

Atmospheric Conditions: If copper is exposed to atmospheric oxygen during melting, it gets oxidized. As a countermeasure, it is economical to utilize a protective atmosphere, say an inert gas such as nitrogen or argon.

Heat Source: The heat source type (electric, gas, etc.) as well as its intensity also affects the melting temperature of copper. It is advisable to use a properly selected heat source which would help in achieving the required melting temperature of copper.

Contamination: It has been observed that the melting temperature of copper is impacted by impurities present in the metal. There is a definite melting temperature of pure copper but if there are impurities mixed the temperature will be different. Hence, care should be taken to check the purity of copper to be molten for desired results.

Considering these environmental factors, it would be possible to melt copper at home safely and effectively. However, do ensure that professional aid or research work is done to understand all the required aspects before carrying out copper melting on your own.

How can you melt copper at home?

How can you melt copper at home
How can you melt copper at home?

Copper melting at home can be a daunting task. One has to keep safety measures as their priority. In summary, below are steps on how to combine technical aspects with safety engrained to complete the task without much worrying about safety procedures.

The first step is to acquire the right equipment: Crucibles, tongs, metallurgical gloves, goggles or a welding mask, and a heatproof table will be required so make sure that you have them.

Secondly, when melting copper, one has to prepare the copper thoroughly by cleaning off all forms of surfaces that could interfere with the melting results and its efficiency.

Depending on the amount of the copper one intends to melt, whether a small or a large amount, and the size of the copper, you have to select a heating source. Either a furnace or a propane torch will be suitable.

Thirdly, one melts the copper by adding consistent yet evenly distributed heat to it until it has reached the temperature at which it liquifies. One has to keep closely monitoring the temperatures to ensure that the copper does not overheat.

Then carefully using tongs, pour the molten copper into a container or a mold. Use care to avoid any splashes or spills that would result from overlooking the molten metal which would make the area hazardous.

Leave the container to cool after which remove all solidified copper after it has completely cooled down.

Keep in mind, melting copper at home is somewhat risky and it is good practice to be cautious. For those who are new to copper melting, it is recommended to get professional assistance or do extensive research to ensure safe and successful copper melting.

Essential equipment for metal melting at home

Sourcing the equipment that you would need to safely and efficiently melt metal at home would be crucial. The following are prerequisites that you will need to do metal melting:

Crucible: A heat-resistant container made of materials like graphite or ceramics that is used for holding the liquid metal at the melting stage.

Furnace or Kiln: This is a furnace or a kiln that is built in such a way that it can reach extremely high temperatures necessary to melt metals, and provides a controlled environment for the metal to be heated to its melting point.

Crucible Tongs: These are especially long-handled tongs that are used to handle hot crucibles safely without having actually to touch the hot crucible. This also allows for the transferring and pouring of the molten metal without direct contact.

Safety Gear: There is a greater risk of high-temperature burns and splashes so appropriate safety gear should be worn, such as heat-resistant gloves, safety glasses and protective garments.

Flux: This is primarily a compound that is used in metal smelting to bind with the unwanted materials in the metal thus minimizing impurities in the end product.

Heat Source: A propane torch, gas-powered or electric furnace/s can be used for smaller or larger scale metal melting projects depending on your requirement.

Bear in mind that melting metal may involve heat as well as risky substances. Thus, it is vital to adhere to all the requirements beforehand.

Step-by-step guide to melt copper safely

Melted copper can be used in making certain products such as those manufactured and jewelry among others. However, indulging in metal melting requires one to keep safety measures in check. Here’s how to safely melt copper metals:

Preparation: Look for a place that is either well-ventilated or uses a melting furnace. Ensure you are dressed adequately for the task, for instance, have gloves, wear goggles, and put on clothes that are heat resistant.

Select the copper: Pure copper and its alloys differ in that the latter has different melting points therefore it is important to select the correct type that will aid in the melting process.

Cleaning the copper: It is important to clean the copper by removing any substances that act as impurities before proceeding to melt it. This would mean rubbing the surface with sandpaper or a wire brush.

Safety measures: Metal melting comes with its own set of safety precautions including fire safety, hazardous material handling, and selecting the correct heating component therefore it is crucial to abide by these guidelines.

Heating mechanism: If you are working on a big project then consider using a gas-powered furnace, propane torch, or an electric one. But ensure the heater can generate enough heat for the metal to melt.

Melting Procedure: First, place the copper inside a melting dish or crucible. Slowly, start to heat it with your preferred heat source. Throughout this step, carefully monitor the temperature to ensure the elements/ml are not overheated and remain within the safe range of melting.

Pouring of the molten copper: After melting has commenced, transport the molten metal into the desired and predetermined cast or vessel. During this pouring, great care should be taken so that there is no splattering of molten copper Furthermore, do not disturb this copper until it has cooled down completely into shape.

Lastly, always remember that it is a risky procedure to melt metals at home, It is mandatory to understand the risks involved and how to minimize them to ensure safety during the procedure.

Safety precautions when melting metals at home

From the perspective of a professional who specializes in metal melting, I wish to draw attention to the safety measures that should be taken when handling molten metals in the residence. Here are some safety precautions every metal worker should take note of:

Use of an Appropriate Attire: One must be always armed in appropriate attire which includes heat-resistant gloves, eye protection and an apron to avoid any chances of getting burnt or splattered.

Proper Air Flow: Metal melting should not be practiced in any constrained infected environments. Practice in a fume hood or a wider space with good airflow to prevent any potentially harmful inhalation effects.

Prevention Against Fires: Have clear instructions on how to use a fire extinguisher and have it nearby just in case there is an emergency. It is also vital to consider using fireproof equipment’ or spaces so whilst melting material there is a significant reduction in the chances of unexpected fires.

Careful Movement When Pouring Molten Metals: When pouring metal always use tools or containers that are suited for molten metals and make sure when doing so precise movements are employed to avoid combustion and any chances of harming oneself.

Correct Equipment and Attention: Have all suitable resources that will allow the melting of metals such as a crucible and an iron source. Melting metals should always be supervised for safety as it is dangerous to leave the task unattended.

When it comes to the melting point of copper alloys about copper, it should be noted that it is always advisable to refer to up-to-date and trustworthy sources.

What is the melting point of copper alloy compared to pure copper?

What is the melting point of copper alloy compared to pure copper
What is the melting point of copper alloy compared to pure copper?

Die Schmelzpunkt von Kupferlegierungen hängt vom genauen geprägten Legierung ab. Kupferlegierungen werden aus der Mischung von Kupfer mit anderen Elementen und diese haben sicherlich ein unterschiedliches Schmelzpunkt als Kufer Legierung. Die Verbindung anderer Metalle verändert die atomare Struktur, die die Schmelzpunkte beeinflusst. While there are useful certain databases containing melting temperatures of most common alloys, for a good approximation, it is best to check the specific alloy papers.

Different copper alloys and their melting points

The composition of copper alloys determines their melting point and other parameters. In pure copper, the melting point is higher than that of copper’s alloy, which is created by mixing copper with other metals. This is because there is a modification in atomic structure due to the addition of different metals and since cohesive forces are altered so is the melting point of the metal. Obtaining information regarding the melting points of copper alloys can be done by consulting databases and corresponding documents pertinent to specific types of alloys.

Melting points should be taken into consideration when using different copper alloys since they determine the field of application they can be used. Useful information regarding the average melting points of most commonly selected copper alloys is as follows:

Brass: Depending on the specific composition, brass, a copper and zinc alloy, has a melting temperature that ranges from 900 to 940 degrees Celsius.

Bronze: Bronze, an alloy of copper and tin, as well as other metals, has a melting temperature range of 950 to 1,100 degrees Celsius or 1742 to 2012 degrees Fahrenheit.

Cupronickel: Being a copper-nickel alloy, the melting point of cupronickel varies with the percentage of nickel in the alloy. The melting point can be roughly in the range of 1,200 to 1,300 degrees Kelvin.

Copper-Tungsten: Copper-tungsten alloys are used for their higher electrical and thermal conductivity, and their melting point is approximately 1,470 to 1500 degrees Kelvin.

Now these melting points above must be taken with caution because they can change depending on the specific compositions of the alloy. Always remember, to determine the melting point of copper alloys, different sources or alloy documentation must be used for verification.

Why do copper alloys have different melting points?

What are the Reasons that Melting Points of copper are increased or decreased? Copper alloys have different melting points because of the variation in their elemental composition. For example including alloying ones such as nickel, tungsten or any other metal changes the copper alloy’s crystal arrangement and bonding which in turn raises or lowers the melting point. Each of the different elements in the alloy can alter the atomic arrangements, changes the lattice structure as well as the interatomic forces which can change the melting behavior. The size of the atoms, the reactivity (or electronegativity) of the atoms, and the proportional amount of the alloying elements are what also explains why there is more than one melting point for copper alloy.

Regarding the copper alloys that have been mentioned earlier, the melting point values follow after the specific value, the noted value for every copper alloy differs. For guaranteed and validated information about melting copper alloy quotes, it’s better to check with credible quotes, standard industry, or quote by specific copper alloy.

Now let us consider the features of high melting point copper alloys about their practical applications, compare the metal copper melting point to that of steel, and investigate why among common metals the first has the lowest melting point and the second one the highest.

Applications of high melting point copper alloys

Due to their specific features and strength, high melting point copper alloys are already widely used in many industries. Let’s review the importance and use of these alloys in various industries:

Electrical and Electronic Industries: Among the high melting point copper alloys, CuCrZr and CuNiBe are the popular ones in the broad field of electronics and electrical engineering in which high conductivity, heat resistance, and durability are needed. These would be electrical connectors, switchgear components, circuit break switches, and electrical contact devices.

Aerospace and Defense: High melting point copper alloys possess excellent strength and thermal stability and are resistant to many corrosives and thus are used extensively in the aerospace and defense sectors. Such alloys are used in engine parts, heat exchangers, rocket nozzles and missile parts.

Welding and brazing: Copper alloys having high melting points such as CuZr and CuCr, are used in welding and brazing applications. These alloys offer good heat resistance and can withstand extreme temperatures without losing their mechanical properties, which makes them suitable for joining applications that are subjected to high pressure and high stress.

Mold and Die Casting: CuCo2Be and CuNiSiCr are examples of high melting point copper alloys that are commonly found in die and mold casting applications. These alloys have good thermal conductivity, good wear resistance, and good thermal stability which allows high complexity and quality castings to be manufactured.

High-Temperature Environments: Copper-nickel alloys with important melting points are used in high-temperature applications such as furnace parts and heat exchangers as well as thermocouples. These alloys are resistant to high temperatures without losing their mechanical properties, assisting many applications with extreme heat.

For accurate melting point, thermal conductivity, mechanical and a few other parameters of an alloy, it is necessary to refer to the relevant industry standards and relevant documents. Parameters and data points can differ from one alloy to another due to the precise application requirements.

Which popular metals have different melting points?

Which popular metals have different melting points
Which popular metals have different melting points

El punto de fusión de los metales oscila, lo que entre otros aspectos determina su aplicabilidad. Estos son algunos de los aspectos que resultan relevantes:

El Cobre: Comparativamente, el cobre tiene el punto de fusión más bajo que la mayoría de los metales, situándose en torno a los 1 083 grados centígrados (1 982 grados Fahrenheit). Debido a su gran capacidad de conducción de calor y electricidad, es útil en múltiples industrias, como las cables eléctricos, las tuberías y los intercambios de calor.

El Acero: Por el contrario el acero presenta un punto de fusión más alto que el cobre, en general está en Estas en particular son de 1,370 a 1,540 grados Celsius (2,498 a 2,804 grados Fahrenheit). Dado que el acero funde a temperaturas más altas, resulta útil en la construcción, fabricación de automóviles y maquinarias.

Para el caso de aplicaciones específicas y que son industriales, conocer la temperatura de fusión de los metales es un aspecto esencial ya que permite escoger adecuadamente el material.

Comparing metal melting points: Copper vs. Steel

In the world of metals, on the surface, the depiction of melting points presents a scenario where the heights progressed by Copper and Steel quite vary. A metal extensively used across industries has a low melting point that is around 1,083 degrees Celsius or to put that differently, about 1,982 degrees Fahrenheit. This property together with copper’s remarkable ability to conduct both heat and electricity makes copper extremely valuable in electrical wires, plumbing systems and heat exchangers among other copper-containing products.

When compared to Copper, Steel does appear to be more resilient with melting point. The melting point of steel which lies between a range of 2,498 degrees to 2,804 degrees Fahrenheit (or 1,370 to 1,540 degrees Celsius) is largely determined by its alloy composition. Such a high melting point allows steel to endure higher temperatures therefore steel can be used in construction, cars, machinery and other items needing material that can go through harsh conditions.

Grasping the different melting points of metals is significant in choosing a suitable material for certain industrial uses. In addition, the low melting point of copper allows it to be used in processes needing great thermal and electrical conductivity, while the high melting point of steel enables it to withstand extreme environments where strong durable materials are necessary. While taking these aspects into account industries can make good decisions when choosing appropriate metals for their purposes.

Understanding the lowest melting point among common metals

Being a metallurgy professional, I can explain why among the most common metals; the lowest melting point is quite critical. The melting point of a metal is essential, controlling the behavior of that particular metal under heat and thereby making it important in a variety of industries. When it comes to the more widely used metals, one can observe copper has a rather low melting point approximately at 1,083 degrees Celsius (1,981 degrees Fahrenheit). This quality makes copper ideal for uses where high thermal and electrical conductivity are required. A low melting point also explains why copper is used in making electrical wires, heat exchangers, plumbing and other systems.

Now, to provide you with accurate and reliable information, I searched in detail three top sources on google.com. Among these sources were well-known pages like journals on metallurgical research, industry magazines and some recognized educational institutions. The purpose of using the materials drawn from the above sources is to ensure that you have a proper understanding of the issues at hand as well as verify the data provided within the pages.

The significance of the highest melting point in industrial applications

The melting point of a material has an impact on the areas of its application when it comes to its usefulness in an industry. Metals having high melting points serve better in the case of strength, stability and heat strength properties. This quality is of great importance when dealing with industrial materials because then these materials would be able to perform even in very high temperatures and environment conditions without losing their strength or effectiveness.

For example in aerospace applications, there is a preference for high melting point materials in turbine blades and exhaust because those turbine blades and exhaust would be subjected to a lot of heat. The internal temperatures produced by the combustion would be high; therefore, these materials would not deform and melt.

In metallurgy, high-melting materials find applications in the liners of furnaces, crucibles and molds for metal casting. These materials should have the capacity to bear the heat that is required to melt and cast metals.

The focus should be on the technical information of the materials of high temperature including melting point, thermal power, heat expansion and strength.

These features allow the material to resist thermal stresses, stay geometrically stable, and conduct or oppose heat in varied industrial settings.

The selection of the appropriate material with a high melting point enhances performance, service life and safety during the operation of various industrial applications. It is also necessary to refer to serious technical materials and collect sufficient information about the used materials and systems designed for operation at high temperatures.

References

Melting point

Metal

Temperature

Frequently Asked Questions (FAQ)

Q: What is the pure copper melting point?

A: The pure copper melting point is approximately 1,984°F (1,085°C) at atmospheric pressure.

Q: How does the melting temperature of copper alloy compare to pure copper?

A: The melting temperature of copper alloy varies depending on the alloy composition, but it is generally lower than that of pure copper due to the addition of other metals with a lower melting point.

Q: Why is it important to know the melting point temperatures of metals?

A: Knowledge of the melting point temperatures is crucial for applications in metallurgy and manufacturing, as it helps determine the heat needed to melt copper and other metals for casting or forming processes.

Q: What are the properties of copper related to its melting point?

A: Copper has a high melting point, excellent thermal and electrical conductivity, and good corrosion resistance, making it ideal for electrical wiring and plumbing.

Q: What is the melting point of brass, a common copper alloy?

A: The melting point of brass, which is a copper-zinc alloy, ranges from about 1,650°F to 1,720°F (900°C to 940°C), lower than pure copper due to zinc’s relatively low melting point.

Q: How does atmospheric pressure affect a metal’s melting point?

A: Atmospheric pressure can influence a metal’s melting point slightly, but for most practical purposes, the melting point temperatures of common metals are measured at standard atmospheric pressure.

Q: What is the significance of copper having a relatively high melting point?

A: Copper’s relatively high melting point allows it to withstand high temperatures without melting, making it suitable for applications requiring durability under thermal stress.

Q: How does the melting point of common metals compare to copper?

A: The melting point of common metals varies, with some having a lower melting point than copper, such as lead and aluminum, while others like iron and nickel have higher melting points.

Q: What do you need to know if you want to melt copper into a mold?

A: If you want to melt copper into a mold, you need to heat it to its melting point of 1,984°F (1,085°C) and maintain it at this temperature to ensure complete melting before pouring it into the mold.

Q: Why might someone choose to use copper despite its high melting point?

A: Someone might choose to use copper because, despite its high melting point, it offers superior conductivity, making it ideal for electrical and thermal applications.

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