Tonewood


Tonewood refers to specific wood varieties used for woodwind or acoustic stringed instruments. The word implies that certain species exhibit qualities that enhance acoustic properties of the instruments, but other properties of the wood such as aesthetics and availability have always been considered in the selection of wood for musical instruments. According to Mottola's Cyclopedic Dictionary of Lutherie Terms, tonewood is:
Wood that is used to make stringed musical instruments. The term is often used to indicate wood species that are suitable for stringed musical instruments
and, by exclusion, those that are not. But the list of species generally considered to be tonewoods changes constantly and has changed constantly throughout history.

Varieties of tonewood

As a rough generalization it can be said that stiff-but-light softwoods are favored for the soundboards or soundboard-like surface that transmits the vibrations of the strings to the ambient air. Hardwoods are favored for the body or framing element of an instrument. Woods used for woodwind instruments include African blackwood – also known as grenadilla – used in modern clarinets, oboes, and wooden concert flutes. Bassoons are usually made of hard maples, especially Norway maple,'' but sometimes palisander and rosewoods is used in older or French-system bassoons. Wooden flutes, recorders, oboes, and early clarinet-like wind instruments of the Baroque and Classical periods may be made of various hardwoods, such as pear, boxwood, or ebony.

Softwoods

  • Spruce is often used in the soundboards of instruments from the lute, oud, violin, viol, mandolin, guitar, and harpsichord families; as well as the piano. Spruce is particularly suited for this use because of its high stiffness-to-weight ratio. Commonly used varieties are Sitka/Alaskan spruce, Adirondack/Red spruce, Engelmann spruce, and Picea abies.
  • Cedar has since the 1950s been used in the tops of classical guitars and to a lesser but growing degree in steel-string acoustic guitars. Also, genuine Lebanon cedar wood is used today in Crete, Syria, and Anatolia region for several traditional musical instruments, like the lyre.
  • Although a softwood, cypresses such as Mediterranean cypress are used on the back and sides of flamenco guitars, the distinction between flamenco and classical guitars only became apparent when makers started marketing their lower priced, snappy sounding, and thinner topped cypress guitars for the players of flamenco since Antonio de Torres – the progenitor of the modern classical guitar – did not differentiate between them constructionally.
  • Yew was once as common as maple for the bowls of lutes and theorbos.
  • Other softwoods, such as redwoods and Douglas fir have been used to a limited degree. Redwood is not used commonly for guitars with steel strings, but has been used for classical guitars.

    Hardwoods

  • Maple, especially Norway maple and sycamore maple, is traditionally used for the backs and sides of violin family instruments. One variation, the Bosnian maple, is probably the maple used by the Cremonese violin makers such as Antonio Stradivari and Giuseppe Guarneri. Maple is also frequently seen in acoustic guitars and mandolins. Most Fender electric guitars feature maple necks. Variations of maple are very sought after for the back and ribs of violin family instruments and their veneers are used on some of the tops of electric guitars for looks. The pinblock, bridges, and action components of the grand piano is usually made of maple or of beech.
  • Mahogany may be used in the tops of some guitars as well as the back, sides, and necks of instruments of the mandolin and guitar families. Mahogany may also be used for the solid bodies of electric guitars, such as the Gibson Les Paul. Due to lack of availability, other similar woods are used as mahogany replacements, such as Australian red cedar, Indonesian mahogany, African mahogany, meranti, kauri, Nato, sapele, sipo , nyatoh, and okoume. Some of these alternatives are mahogany family timbers.
  • Rosewoods are very often used in the back and sides of guitars and mandolins and fretboards on guitars. The most sought-after variety, Brazilian rosewood, has become scarce and expensive due to high demand, limited availability, and strict trade restrictions such as embargoes and CITES regulations. However, in August 2019, CITES announced an exception for rosewood used in musical instruments. The most widely used rosewood used currently is East Indian rosewood, often paired with a spruce top for steel string guitars and with spruce or cedar for classical guitars. Another rosewood, cocobolo, is used in some high-end clarinets and guitars. Rosewoods are also the wood of choice for marimba bars.
  • Koa is traditionally used for ukuleles. Koa is also used for steel string guitars mostly due to its beauty and compressed dynamic range.
  • Ebony is also often used in many types of instruments for fingerboards, tailpieces, tuning pegs, and so forth due to its attractive jet-black appearance, smoothness to the touch, hardness, and wear resistance. Several varieties of ebony are used. Ebony is often dyed to make it appear more uniformly black than the natural wood, which sometimes shows brown streaks.
  • Paubrasilia, commonly called Pernambuco or Brazilwood, is the most sought-after material for the bows of classical stringed instruments, because of its effects on the tones they produce and the balance of stiffness and flexibility for the need of string players.
  • Walnut is often used for the backs and sides of guitars and mandolin family instruments.
  • Ash, alder, and basswood are commonly used for the bodies of electric guitars, ash for its light-colored, natural wood finishes, and alder and basswood for their uniform density, their ease of machining, and amenability to rapid finishing techniques.

    Mechanical properties of tonewoods

Some of the mechanical properties of common tonewoods, sorted by density.
Wood speciesρ
Density
kg/m3		J
Hardness
N		ELR
Flexural modulus
GPa		?LR
Poisson's strain ratio		F
Flexural strength
MPa		C
Compressive strength
MPa		S
Shrinkage
Volume
%		R
Sound radiation
coefficient		D
Rigidity
3mm plate
N·m
Balsa1503003.710.22919.611.68.533.28.8
Paulownia2801,3304.3837.820.76.414.1
Northern white cedar3501,4205.520.33744.827.37.211.314.0
King Billy pine3505.8069.011.6
Sugi 3601,4207.6536.428.010.512.8
Western red cedar3701,5607.660.37851.731.46.812.320.1
Obeche3801,9106.6960.829.38.711.0
Engelmann spruce3851,7409.440.42262.231.511.012.925.8
Black cottonwood3851,5608.7658.631.012.412.4
Sugar pine4001,6908.210.35656.630.87.911.321.2
Eastern white pine4001,6908.5559.333.18.211.6
Norway spruce4051,6809.7063.035.512.912.0
American basswood 4151,82410.070.36460.032.615.811.926.1
Coast redwood4152,0008.410.36061.739.26.910.821.7
Black willow4151,9206.9753.828.313.99.9
White fir4152,14010.2466.939.69.812.0
Noble fir4151,82011.1774.439.512.412.5
Sitka spruce4252,27011.030.37270.038.211.512.028.8
White spruce4252,1409.0759.632.613.710.9
Okoume4301,7908.4775.036.212.210.3
Red spruce4352,18010.7666.033.611.811.4
Western white pine4351,87010.070.32966.934.811.811.125.4
California red fir4352,22010.2371.537.311.411.1
Butternut4352,1808.1455.935.210.69.9
White poplar4401,8208.900.34465.0NA8.410.222.7
Red alder4502,6209.5267.640.112.610.2
Yellow poplar4552,40010.900.31869.738.212.710.827.3
Catalpa4602,4508.3564.818.97.39.3
Port Orford cedar4652,62011.350.37884.841.910.110.629.8
Primavera4653,1707.8170.540.48.68.8
Western hemlock4652,40011.240.48577.937.312.410.633.1
Spanish cedar4702,6709.1270.840.410.29.4
Australian red cedar4853,1309.2271.536.110.89.0
Swamp ash481–538
European alder4952,8908.9975.942.211.08.6
Alaska yellow cedar4952,5809.7976.643.59.29.0
Sassafras4952,8007.7262.145.510.38.0
Douglas fir5102,76012.170.29286.247.911.69.629.9
Bald cypress5152,2709.930.33873.143.910.58.525.2
Cedar of Lebanon5203,67010.1824210.48.5
Silver maple5303,1107.8661.436.012.07.3
Mediterranean cypress5352,4905.2844.65.9
Kauri5403,23011.8786.642.311.38.7
Black ash5453,78011.0086.941.215.28.2
American sycamore5453,4309.7969.037.114.17.8
Bigleaf maple5453,78010.0073.841.011.67.9
Sweetgum5453,78011.310.32586.243.615.88.428.5
Anigre5504,38010.9583.047.711.88.1
Limba5552,99010.4986.245.410.87.8
Black cherry5604,23010.300.39284.849.011.57.727.4
Cerejeira5603,51010.8872.943.58.37.9
Queensland maple5603,62010.8381.047.015.07.9
American elm5603,6909.2481.438.114.67.3
Western larch5753,69012.900.35589.752.614.08.233.2
Avodiré5755,18011.13106.251.711.37.7
Lacewood5803,740
Honduran mahogany5904,02010.060.31480.846.67.57.025.1
Monkeypod6004,0107.965.739.96.06.1
Cuban mahogany6004,1209.3174.443.38.06.6
Peruvian walnut6004,2507.8177.045.211.46.0
Red elm6003,83010.2889.743.913.86.9
Red maple6104,23011.310.43492.445.112.67.131.4
Black walnut6104,49011.590.495100.752.312.87.134.5
Koa6105,18010.3787.048.712.46.8
Sycamore maple6154,6809.9298.155.012.36.5
California black oak6204,8406.7659.438.910.25.3
Nyatoh6204,76013.3796.054.48.77.5
Oregon myrtle6355,6508.4566.938.911.95.7
English walnut6405,41010.81111.550.213.06.4
Green ash6405,34011.4097.248.812.56.6
Australian blackwood6405,18014.82103.641.011.97.5
African mahogany6404,76010.6091.049.010.06.4
Redheart6405,38010.3298.746.210.66.3
Claro walnut6405,03010.7
Norway maple6454,51010.60115.059.06.3
Teak6554,74012.2897.154.87.26.6
Narra6555,62011.8996.357.06.96.5
Iroko6605,6109.3887.654.08.85.7
Sapele6706,28012.04109.960.412.86.3
White ash6755,87012.000.371103.551.113.36.231.3
Dark red meranti6753,57012.0287.748.812.56.3
European ash6806,58012.31103.651.015.36.3
Makore6855,35010.71112.657.212.45.8
Yellow birch6905,61013.860.426114.556.316.86.538.1
Pear6907,3807.8083.344.113.84.9
Field maple6905,11011.80123.06.0
Red oak7005,43012.140.35099.246.813.75.931.1
Hard maple7056,45012.620.424109.054.014.76.034.6
European beech7106,46014.31110.157.017.36.3
American beech7205,78011.86102.851.117.25.6
Afrormosia7256,98011.83102.966.09.95.6
Pecan7358,10011.9394.554.113.65.5
African padauk7458,76011.72116.056.07.65.3
Keruing7456,17015.81115.261.416.36.2
White oak7555,99012.150.369102.350.816.35.331.6
Black siris7607,26011.896.456.112.35.2
Black locust7707,56014.14133.870.310.25.6
Tzalem7806,23013.1088.39.55.3
Plum7956,90010.1988.44.5
Zebrawood8058,16016.37122.863.517.85.6
Ziricote8058,78010.93113.163.99.84.6
Ovangkol8255,90018.60140.364.212.15.8
Yellowheart8257,95016.64115.969.512.05.4
East Indian rosewood83010,87011.50114.459.78.54.5
Canarywood8306,75014.93131.667.28.45.1
Brazilian rosewood83512,41013.93135.067.28.54.9
Partridgewood8357,96018.17127.564.112.35.6
Pignut hickory8359,52015.59138.663.417.55.2
Indian laurel85510,39012.46101.456.713.24.5
Osage orange85511,64011.64128.664.79.24.3
Bocote8558,95012.19114.459.411.64.4
Pau ferro8658,71010.86122.460.99.94.1
Wenge8708,60017.59151.780.712.95.2
Panga panga8707,31015.73131.275.110.54.9
Leopardwood8859,56019.9150.211.55.4
Bubinga89010,72018.41168.375.813.95.1
Purpleheart90511,19020.26151.783.710.65.2
Gonçalo alves9059,64016.56117.074.211.24.7
Jatoba91011,95018.93155.281.212.15.0
Santos mahogany91510,68016.41148.780.610.04.6
Madagascar rosewood93512,08012.01165.776.610.33.8
Macacauba95012,03019.6148.680.77.24.8
Gaboon ebony95513,70016.89158.176.319.64.4
Boxwood97512,61017.20144.568.615.84.3
Brazilwood98012,54017.55179.413.34.3
Chechen99010,01010.8
Mora1,01510,23019.24155.582.417.74.3
Curapay1,02516,15018.04193.294.412.04.1
Honduran rosewood1,0259,79022.004.5
Pau rosa1,03013,08017.10166.292.810.74.0
Bloodwood1,05012,90020.78174.498.711.74.2
Bulletwood1,08013,92023.06192.289.216.84.3
Cumaru1,08514,80022.33175.195.512.64.2
Cocobolo1,09514,14018.70158.081.37.03.8
Ipê1,10015,62022.07177.093.812.44.1
Macassar ebony1,12014,14017.35157.280.2-3.5
Katalox1,15016,26025.62193.2105.111.24.1
Snakewood1,21016,90023.219511910.73.6
Lignum vitae1,26019,51014.09127.284.114.02.7
African blackwood1,27016,32017.95213.672.97.73.0
CFRP1,6001350.301500120005.7334
Common flat glass2,5307402.1
Aluminium alloy2,700680.3301.9172
Steel alloy8,0002000.3000.6495

CFRP, glass, aluminium, and steel added for comparison, since they are sometimes used in musical instruments.
Density is measured at 12% moisture content of the wood, i.e. air at 70 °F and 65% relative humidity. Most professional luthiers will build at 8% moisture content, and such wood weighs less on average than that reported here, since it contains less water.
Data comes from the Wood Database, except for ?LR, Poisson's ratio, which comes from the Forest Product Laboratory, United States Forest Service, United States Department of Agriculture. The ratio displayed here is for deformation along the radial axis caused by stress along the longitudinal axis.
The shrink volume percent shown here is the amount of shrinkage in all three dimensions as the wood goes from green to oven-dry. This can be used as a relative indicator of how much the dry wood will change as humidity changes, sometimes referred to as the instrument's "stability". However, the stability of tuning is primarily due to the length-wise shrinkage of the neck, which is typically only about 0.1% to 0.2% green to dry. The volume shrinkage is mostly due to the radial and tangential shrinkage. In the case of a neck, the radial shrinkage affects the thickness of the neck, and the tangential shrinkage affects the width of the neck. Given the dimensions involved, this shrinkage should be practically unnoticeable. The shrinkage of the length of the neck, as a percent, is quite a bit less, but given the dimension, it is enough to affect the pitch of the strings.
The sound radiation coefficient is defined as:
where is flexural modulus in Pascals, and ρ is the density in kg/m3, as in the table.
From this, it can be seen that the loudness of the top of a stringed instrument increases with stiffness, and decreases with density. The loudest wood tops, such as Sitka Spruce, are lightweight and stiff, while maintaining the necessary strength. Denser woods, for example Hard Maple, often used for necks, are stronger but not as loud.
When wood is used as the top of an acoustic instrument, it can be described using plate theory and plate vibrations. The flexural rigidity of an isotropic plate is:

where is flexural modulus for the material, is the plate thickness, and is Poisson's ratio for the material. Plate rigidity has units of Pascal·m3, since it refers to the moment per unit length per unit of curvature, and not the total moment. Wood is not isotropic, but orthotropic, so this equation describes the rigidity in one orientation. For example, using ?LR, one gets the rigidity when bending on the longitudinal axis, as would be usual for an instrument's top. This is typically 10 to 20 times the cross-grain rigidity for most species.
The value for shown in the table was calculated using this formula and a thickness of 3 mm.
When wood is used as the neck of an instrument, it can be described using beam theory. Flexural rigidity of a beam varies along the length as a function of x shown in the following equation:
where is the flexural modulus for the material, is the second moment of area, is the transverse displacement of the beam at x, and is the bending moment at x. Beam flexural rigidity has units of Pascal·m4.
The amount of deflection at the end of a cantilevered beam is:

where is the point load at the end, and is the length. So deflection is inversely proportional to. Given two necks of the same shape and dimensions, becomes a constant, and deflection becomes inversely proportional to —in short, the higher this number for a given wood species, the less a neck will deflect under a given force.
Read more about mechanical properties in Wood for Guitars.