Constantan Manganin Wire Sampling Resistor Wire, Diameter 0.4mm, 0.6mm, 0.8mm, 1.0mm, 1.5mm, Resistance 3mΩ

Constantan is a copper-nickel alloy composed of 55% copper and 45% nickel (Cu55Ni45). Its characteristics include minimal change in properties with temperature variations and high resistivity. It has a low resistivity temperature coefficient and moderate resistivity (0.48 μΩ·m).
Constantan is suitable for use in AC circuits, serving as precision resistors, sliding resistors, and resistance strain gauges, among others. It can also be used as material for thermocouples and thermocouple compensation wires.
An alloy is a substance with metallic properties formed by mixing two or more chemical substances (at least one of which is a metal). It is generally produced by melting the components into a uniform liquid and then cooling it to solidify.
Alloys can exhibit at least one of the following three characteristics: a single-phase solid solution formed by elements, a mixture of multiple metallic phases, or intermetallic compounds formed by metals. The microstructure of solid solution alloys consists of a single phase, while partially soluble alloys may have two or more phases, which can be either homogeneous or heterogeneous depending on the temperature changes during the cooling process. Intermetallic compounds typically involve one alloy or pure metal enveloped within another pure metal.
Since some properties of alloys are superior to those of pure metallic elements, they are used in specific applications. Examples of alloys include steel, solder, brass, pewter, phosphor bronze, and amalgam.
The composition of alloys is generally calculated based on mass ratios. Depending on the atomic arrangement, alloys can be classified as substitutional alloys or interstitial alloys, and further categorized as homogeneous (single-phase), heterogeneous (multiple phases), or intermetallic compounds (with no distinct boundary between phases). [2]
Overview
The formation of alloys often alters the properties of the constituent elements. For example, steel has greater strength than its primary component, iron. The physical properties of alloys, such as density, reactivity, Young's modulus, electrical conductivity, and thermal conductivity, may resemble those of their constituent elements. However, the tensile strength and shear strength of alloys are often significantly different from the properties of the constituent elements. This is due to the substantial differences in atomic arrangement between alloys and pure metals. For instance, the lower melting point of alloys compared to their constituent metals is attributed to variations in atomic radii, making it more difficult to form a stable crystal lattice.
A small amount of a particular element can greatly influence the properties of an alloy. For example, impurities in ferromagnetic alloys can alter their properties.
Unlike pure metals, most alloys do not have a fixed melting point. Within the melting temperature range, the mixture exists in a solid-liquid coexisting state. Therefore, it can be said that the melting point of an alloy is lower than that of its constituent metals. See eutectic mixture.
Among common alloys, brass is an alloy of copper and zinc; bronze is an alloy of tin and copper, often used for statues, decorations, and church bells. The currency of some countries utilizes alloys (such as nickel alloys).
An alloy is a type of solution. For example, in steel, iron is the solvent, and carbon is the solute.