Melting Point of Metals
In basic principle, the melting point of metals is the temperature that changes them from solids to liquids. This measurement affects how and where they can be used. It also affects fabrication and workability, meaning how the metal is manufactured.
The melting point of metals is also directly related to thermal conduction and thermal expansion. This and the melting point will ultimately affect how a metal is used. The lower the melting point, the more thermal conduction or expansion it demonstrates.
Metal melting points are also particularly important when it comes to welding services, which is just one of the sheet metal fabrication services we offer here at Salamander Fabrications. Our dedicated team of experts is happy to talk to you about our services any time you like, but for now, continue reading for more information on the melting point of metals.
Why is the melting point of metals so important?
The melting point of any metal affects how the metal is alloyed. This refers to the process of combining a metal with one or more other elements, and it must occur in a liquid state. Metal melting points also dictate how the metal is used. For example, the aerospace or oil and gas industries often require metals that can handle extreme heat.
Melting point of metals chart
Our handy melting point of metals chart shows a number of common and also rare metals, along with their properties, applications, benefits, and melting points.
| Metal | Melting Point (°C) | Properties | Applications | Benefits |
| Aluminium | 660°C | Lightweight, corrosion-resistant, good conductivity | Used in casting, extrusion, and alloys for automotive, aerospace, and packaging | Low density, easily machinable, recyclable |
| Copper | 1,085°C | Excellent electrical and thermal conductivity, ductile | Electrical wiring, plumbing, heat exchangers, coinage | High conductivity, corrosion-resistant |
| Iron | 1,538°C | Strong, tough, magnetic, prone to rusting unless alloyed | Steel production, cast iron components, tools, construction | High strength, widely available, cost-effective |
| Gold | 1,064°C | Highly malleable, ductile, corrosion-resistant, conductive | Jewellery, electronics, currency, coatings | Doesn’t tarnish, excellent conductivity |
| Silver | 961°C | Best electrical conductor, antibacterial, and reflective | Electrical contacts, jewellery, mirrors, medical instruments | High conductivity, antimicrobial, high reflectivity |
| Titanium | 1,668°C | High strength-to-weight ratio, corrosion-resistant | Aerospace, medical implants, sports equipment | Lightweight, strong, biocompatible |
| Zinc | 419°C | Corrosion-resistant, low melting point, brittle | Galvanising steel, die casting, batteries | Protects steel from rust, easy to cast |
| Lead | 327°C | Soft, dense, corrosion-resistant, toxic | Batteries, radiation shielding, ammunition | High density, soundproofing, radiation-shielding |
| Nickel | 1,455°C | High-temperature resistance, corrosion-resistant, strong | Superalloys, stainless steel, batteries | Heat-resistant, enhanced steel properties |
| Platinum | 1,768°C | Highly corrosion-resistant, dense, excellent catalyst | Jewellery, catalytic converters, lab equipment | Doesn’t corrode, high melting point |
| Magnesium | 650°C | Lightweight, strong, flammable in powder form | Aerospace, automotive, fireworks, alloys | Very light, good strength-to-weight ratio |
| Tungsten | 3,422°C | Highest melting point, very dense, hard | Light bulb filaments, electrodes, military applications | Heat-resistant, extremely strong |
| Chromium | 1,907°C | Hard, corrosion-resistant, shiny | Stainless steel production, coatings, plating | Improves steel hardness and corrosion resistance |
| Cobalt | 1,495°C | Magnetic, wear-resistant, retains strength at high temperatures | Superalloys, magnets, batteries | Heat-resistant, strengthens alloys |
| Palladium | 1,555°C | Corrosion-resistant, ductile, catalyst | Catalytic converters, jewellery, fuel cells | Non-reactive, used in emissions control |
| Rhodium | 1,964°C | Extremely corrosion-resistant, highly reflective | Used in catalytic converters, jewellery, mirrors, coatings | Very rare; enhances durability and reflectivity |
| Osmium | 3,033°C | Densest naturally occurring metal, hard, brittle | High-wear alloys, fountain pen nibs, electrical contacts | High hardness, corrosion-resistant |
| Iridium | 2,447°C | Extremely corrosion-resistant, hard, dense | Electrical contacts, spark plugs, aerospace components | Resists extreme temperatures, very strong |
| Rhenium | 3,180°C | Very high melting point, good creep resistance | Jet engine components, thermocouples, electrical contacts | Handles extreme heat, improves superalloys |
| Hafnium | 2,227°C | High melting point, absorbs neutrons | Used in nuclear control rods, aerospace applications | Heat-resistant, good for high-radiation environments |
How to measure the melting point of metals
There are several methods for measuring melting points, each with its own benefits and limitations.
Differential Scanning Calorimetry (DSC)
This is a highly accurate method often used in research and industry. The technique works by measuring the heat flow required to increase the temperature of a sample piece of metal. When the sample reaches its melting point, there is a change in the amount of heat needed, which can be detected precisely. This is highly accurate but involves expensive equipment and a time consuming process.
Pyrometry (optical methods)
Pyrometers are used to measure temperature remotely without direct contact with the sample piece of metal. This is especially useful for metals with high melting points, where conventional thermometers may be ineffective or dangerous to use. The accuracy depends on the material and surface properties of the metal.
Thermocouples
These are widely used in industrial settings to measure temperatures in a variety of processes other than just metal melting. A thermocouple is made of two different metals joined at one end, creating a voltage that changes with temperature. The voltage can then be correlated with the temperature of the metal. This is inexpensive, widely available, and versatile. However, calibration is required, and it offers limited precision at extremely high temperatures.
For more information, you can check out our other blog on metals – ‘The Different Types of Metals; Their Properties, And Their Applications’.
Factors that affect the melting point of metals
Metal melting points depend on several factors that can influence the strength of atomic bonds and structural arrangements.
Atomic bonding
Metals are characterised by metallic bonding. The strength of metallic bonds correlates with how much energy is needed to separate the atoms and cause the metal to melt. Stronger bonds need more heat and vice versa.
Atomic structure
The arrangement of the atoms in a metal also denotes how tightly they are packed together. The tighter they are, the more energy is required for them to change state. Face centred cubic (FCC) structures are less resistant to temperature change, which often results in a lower melting point. Body centred cubic (BCC) and hexagonal close packed (HCP) structures tend to have higher melting points due to tighter atomic interactions.
Impurities
When a metal is impure, the atoms are arranged irregularly, which creates defects in the atomic structure. This can either lower or raise the melting point, depending on the impurity.
Pressure
Higher pressure generally results in a higher melting point because atoms are forced into tighter arrangements, making it harder to separate them. This typically applies to high-altitude or deep earth applications.
Atmospheric conditions
Oxygen levels or the presence of oxidizing agents can affect a metal’s melting point.
Pure metal vs. Alloy melting points
There are some interesting differences when it comes to comparing the melting points of pure metals and their alloys. Pure metals usually have a specific melting point that corresponds to the temperature at which their atomic bonds break down.
On the other hand, as alloys are mixtures of two or more metals, they can often have a wide range of melting points rather than a single point. For example, brass (an alloy of copper and zinc) melts between 900°C and 940°C, while pure copper melts at 1,085°C specifically.
Some alloys are designed to have lower melting points, especially for their use or application. For example, solder (a tin-lead alloy) has a melting point ideal for joining electronic components, as it can melt easily without damaging sensitive parts. Equally, some alloys are designed for high temperature applications. For example, stainless steel (iron-based alloy) has a high melting point due to the addition of chromium, which enhances the alloy’s strength.
The importance of the melting point of metals in terms of welding services
The melting point of metals is crucial in welding because it determines the amount of heat needed to join metals together without causing excessive distortion or damage. Metals with high melting points require more heat and specialised welding techniques. Metals with low melting points risk overheating or warping. Understanding melting points helps in selecting the right welding method, filler material, and heat control to ensure strong, defect-free joints.
Here at Salamander Fabrications we use a number of different types of welding techniques, such as MIG, TIG, and spot welding. Our team consists of qualified, well-trained welders who have meticulously built up their expertise and use cutting-edge tools on every job. Our welding capabilities are also coded in line with numerous standards and specifications.
Our welding specifications
- EN 15614-1: Specification and qualification of welding procedures for metallic materials. Part 1: Arc and gas welding of steels and arc welding of nickel and nickel alloys.
- EN 15614-2: Specification and qualification of welding procedures for metallic materials. Part 2: Arc welding of aluminium and its alloys.
- EN 9606-1: Qualification testing of welders. Fusion welding – steels.
- EN 9606-2: Qualification test of welders. Fusion welding – aluminium and aluminium alloys.
Other metal forming techniques
Below, we’ll explore some other metal forming techniques:
Casting
Casting processes like investment casting and sand casting are used to create complex shapes from molten metals like cast iron. The casting equipment must have a higher melting point than the metal being cast, or it will be unable to fulfil its function.
Cutting and shaping
The melting point of metals isn’t relevant here, but this is still an extremely popular metal fabrication technique. Metals can be cut and shaped using various methods such as shearing, sawing, laser cutting, and plasma cutting.
Heat treatment
Heat treatment can include annealing, quenching, and tempering. These are used to improve hardness, strength, and ductility. The melting point will undoubtedly influence the effectiveness of heat treatment, as more heat may be needed for success.
Sheet metal folding
Sheets of metal can be bent into shape using CNC press brakes or folding machines. Sheet metal folding allows for accurate bends and angles, essential for manufacturing parts with tight tolerances.
Coating and finishing
Coating and finishing processes like painting or powder coating services are used to improve aesthetic appearance and corrosion resistance. This is particularly useful for outdoor applications where durability and appearance are key.
Forming and fabrication
Sheet metal fabrication may involve bending, rolling, or stamping metals into various forms. These methods are used to produce sheet metal parts, structural sections, and other custom components.
Contact Salamander Fabrications for all of your sheet metal fabrication enquiries
Here at Salamander Fabrications, we’re happy to share our knowledge and expertise for any project you have in mind.
We have been the UK’s chosen choice for sheet metal fabrication solutions for over 50 years, with an expert team providing end-to-end machining services. If you would like some more information or advice, please feel free to contact us, give us a call on 01484 843599 or send an email to sales@salamanderfabs.com. Our friendly sales team will be more than happy to help!
