Calculator finds out sound reflection coefficient between two mediums e.g. air-concrete or steel-steel

Beta version#

BETA TEST VERSION OF THIS ITEM
This online calculator is currently under heavy development. It may or it may NOT work correctly.
You CAN try to use it. You CAN even get the proper results.
However, please VERIFY all results on your own, as the level of completion of this item is NOT CONFIRMED.
Feel free to send any ideas and comments !

Calculations data: ośrodek źródłowy i docelowy#

Source medium
Substance name
Density of substance
Sound velocity in the medium
Destination medium
Substance name
Density of substance
Sound velocity in the medium

Results: what is happening at the medium boundary#

Source medium
Density of substance	-kg/m³
Sound velocity in the medium	-m/s
Acoustic impedance	0kg / (m² s)
Destination medium
Density of substance	2500kg/m³
Sound velocity in the medium	3800m/s
Acoustic impedance	9500000kg / (m² s)
Medium boundary
Reflection coefficient by intensity (β)	1
Transmission coefficient by intensity (α)	0
Transmission loss in logarithmic scale (10 log α)	-infdB

Other target materials#

Values calculated if the target material was the one in the table
Substance name	Reflection coefficient $\beta = \frac{I_1}{I_2}$	Transmission coefficient $\alpha = 1 - \beta$	Transmission coefficient in logarithmic scale [dB] $10~log~\alpha$
aluminum (pure)	1	0	-inf
brass	1	0	-inf
cadmium	1	0	-inf
copper (pure)	1	0	-inf
gold	1	0	-inf
iron	1	0	-inf
iron, cast	1	0	-inf
lead	1	0	-inf
magnesium	1	0	-inf
molybdenum	1	0	-inf
monel	1	0	-inf
nickel	1	0	-inf
platinum	1	0	-inf
silver	1	0	-inf
steel, carbon	1	0	-inf
steel, stainless 304	1	0	-inf
tin	1	0	-inf
titanium	1	0	-inf
tungsten	1	0	-inf
uranium	1	0	-inf
zinc	1	0	-inf
glycerin	1	0	-inf
ethanol	1	0	-inf
liquid helium	1	0	-inf
oil, petroleum	1	0	-inf
mercury	1	0	-inf
water 25°C	1	0	-inf
water, sea	1	0	-inf
ethanol	1	0	-inf
ice (frozen water, 0°C)	1	0	-inf
organic glass (plexiglass)	1	0	-inf
quartz glass	1	0	-inf
hydrogen	1	0	-inf
carbon dioxide	1	0	-inf
dry air (standard conditions, 25°C and 100 kPa)	1	0	-inf
oxygen	1	0	-inf
carbon dioxide	1	0	-inf
aluminium oxide	1	0	-inf
nylon	1	0	-inf
polyethylene	1	0	-inf
rubber, hard	1	0	-inf
neoprene (polychloroprene)	1	0	-inf
teflon (polytetrafluoroethylene, PTFE)	1	0	-inf
fir wood	1	0	-inf
pine wood	1	0	-inf
neoprene (polychloroprene)	1	0	-inf
teflon (polytetrafluoroethylene, PTFE)	1	0	-inf
marble	1	0	-inf
concrete	1	0	-inf

Some facts#

When acoustic wave encounters the medium boundary it may be transmitted to the second medium or it may be reflected (remain in the first medium).
How much energy will be transferred between mediums depends on the physical properties of the mediums.
For plane wave, which falls perpendicular to the boundary surface, the part of energy that remains in the first medium is determined by reflection coefficient:

$\beta = \left(\frac{Z_1 - Z_2}{Z_1 + Z_2}\right)^2$
where:
- $\beta$ - intensity reflection coefficient,
- $Z_1$ - acoustic impedance of the first medium,
- $Z_2$ - acoustic impedance of the second medium.
The range of reflection coefficient is from zero to one. Reflection coefficient equal to one (β = 1) means that the wave is reflected completely. The reflection coefficient equal to zero (β = 0) means that the whole energy of the wave is being passed to the second medium (has been absorbed).
From the expression for reflection coefficient we can see:
- the reflection coefficient is directly proportional to the square difference of acoustic impedance of the mediums:
  
  $\beta \propto (\Delta Z)^2 \propto (Z_1 - Z_2)^2$
- the sound barrier (large reflection coefficient) is acoustic impedance difference,
- because the acoustic impedance depends on the density (to the greatest extent), the greatest insulation is obtained on the gas-solid boundary (e.g. sound from the air is reflected off a wall made of concrete almost completely),
- the worst insulation can be obtained between mediums of similar impedance e.g. between two metal pipes,
- acoustic insulation between two solids is more difficult to achieve than between a solid and a gas. The reason is smaller range of available acoustic impedances among solids than between materials with different states of aggregation,
- in the extreme case when both mediums have identical acoustic impedance (Z₁ = Z₂) the acoustic wave moves like within one medium.
Starting from the law of conservation of energy we can determine the remaining energy that has passed to the second medium. This calculated quantity is usually called transmission coefficient of the medium:

$\alpha = 1 - \beta = \frac{4~Z_1~Z_2}{(Z_1 + Z_2)^2}$
where:
- $\alpha$ - intensity transmission coefficient,
- $\beta$ - intensity reflection coefficient,
- $Z_1$ - acoustic impedance of the first medium,
- $Z_2$ - acoustic impedance of the second medium.
From the expression for the transmission coefficient we can see that sound cannot penetrate into the vacuum (Z₂ = 0).