Calculate the speed of longitudinal sound waves in solids using Young's modulus and density. Compare materials with acoustic impedance data.
The speed of sound in a solid material depends on its elastic properties and density. For longitudinal waves traveling through an isotropic solid, the velocity is calculated as v = √(E/ρ), where E is the material's Young's modulus (elastic modulus) and ρ is the mass density.
Understanding sound speed in solids is essential in many engineering and scientific fields. Non-destructive testing (NDT) uses ultrasonic waves to detect internal flaws in metals, welds, and composite structures. The acoustic impedance — the product of density and sound speed — determines how much energy reflects at material boundaries, which is critical in ultrasound probe design and acoustic matching layers.
This calculator lets you select from a comprehensive material database or enter custom elastic properties. It computes the longitudinal wave velocity, converts to multiple unit systems, estimates travel time over a given distance, and compares the result with the speed of sound in air at your specified temperature. A full material comparison table helps you quickly identify the fastest and slowest materials for wave propagation.
This calculator is invaluable for engineers performing ultrasonic non-destructive testing, materials scientists characterizing elastic properties, and students learning about wave mechanics. By comparing sound speeds across dozens of materials, you can quickly estimate wave behavior for probe selection, transit-time measurements, and acoustic design.
The built-in material database saves you from looking up Young's modulus and density separately, while the custom-material mode lets you analyze any isotropic solid. The acoustic impedance output is directly useful for designing matching layers and calculating reflection coefficients.
Speed of Sound in Solids (longitudinal): v = √(E / ρ) Where: • v = longitudinal wave velocity (m/s) • E = Young's modulus (Pa) • ρ = density (kg/m³) Acoustic Impedance: Z = ρ × v (Pa·s/m or Rayl) Speed of Sound in Air: v_air = 331.3 + 0.606 × T (°C)
Result: 5,048 m/s
For structural steel with E = 200 GPa and ρ = 7,850 kg/m³, v = √(200×10⁹ / 7850) ≈ 5,048 m/s. This is roughly 14.8 times faster than sound in air at 20 °C.
Sound waves in solids propagate as mechanical vibrations through the atomic lattice. Unlike gases, where molecules are far apart and interact weakly, atoms in a solid are tightly bonded. The restoring force from these bonds — characterized by the elastic modulus — determines how quickly a disturbance propagates. Denser materials have more inertia to overcome, which slows the wave, but this effect is usually outweighed by the enormous stiffness of solid materials compared to fluids.
Ultrasonic NDT is one of the most widely used inspection methods in aerospace, manufacturing, and construction. A transducer emits high-frequency sound pulses into a part; the speed of sound determines when echoes return from internal features or defects. Accurate knowledge of the material's sound velocity is essential for converting time-of-flight measurements into depth or thickness readings. Errors in assumed velocity directly translate to measurement errors.
When designing acoustic waveguides, delay lines, or impedance-matching layers, engineers need to compare sound speeds across candidate materials. The comparison table in this calculator provides quick access to the key parameters. Materials with very high impedance (like tungsten) reflect most incident energy, making them good acoustic reflectors. Low-impedance materials (like rubber) are used as absorbers or decouplers.
Solids have much higher elastic moduli than gases. Although solids are denser, the stiffness increase dominates, resulting in higher wave speeds.
Longitudinal (compressional) waves have particle motion parallel to propagation. Transverse (shear) waves move perpendicular. This calculator computes longitudinal velocity; shear velocity uses the shear modulus G instead of E.
Acoustic impedance (Z = ρv) determines how much sound reflects at a boundary between two materials. Large impedance mismatches cause strong reflections, which is the basis of ultrasonic testing and medical ultrasound.
Yes, but much less than in gases. Higher temperature slightly reduces the elastic modulus, typically decreasing speed by a few m/s per 100 °C in metals.
For isotropic composites, yes. Anisotropic composites (like carbon fiber laminates) have direction-dependent stiffness, so wave speed varies with propagation direction.
Diamond has both an extremely high Young's modulus (~1,220 GPa) and relatively low density (3,510 kg/m³), giving v ≈ 18,640 m/s — the highest of any bulk material. Understanding this concept helps you apply the calculator correctly and interpret the results with confidence.