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[" 49.Figure ( "15-E10" ) shows an alumi...

[" 49.Figure ( "15-E10" ) shows an aluminium wire of "],[60cm" joined to a steel wire of length "80cm" ."],[" stretched between two fixed supports.The "],[" produced is "40N" .The cross-sectional area of the "],[" wire is "1*0mm^(2)" and that of the aluminium "],[3*0mm^(2)" .What could be the minimum frequeng "],[" tuning fork which can produce standing waves in "],[" system with the joint as a node? The density "],[" aluminium is "2*6gcm^(-3)" and that of steel is "78g(m^(2)" ) "],[qquad (80cm)/(" Steel ")" Aluminium "]

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Figure shows an aluminium wire of length 60 cm joined to a steel wire of length 80 cm and stretched between two fixed supports. The tension produced is 40 N . The cross-sectional area of the steel wire is 1.0 mm^(2) and that of the aluminimum wire is 3.0 mm^(2) The minimum frequency of a tuning fork which can produce standing waves in the system with the joint as a node is 10P (in Hz ) the find P . Given density of aluminimum is 2.6 g//cm^(3) and that of steel is 7.8 g//cm^(3) .

Figure shows an aluminium wire of length 60 cm joined to a steel wire of length 80 cm and stretched between two fixed supports. The tension produced is 40 N . The cross-sectional area of the steel wire is 1.0 mm^(2) and that of the aluminimum wire is 3.0 mm^(2) The minimum frequency of a tuning fork which can produce standing waves in the system with the joint as a node is 10P (in Hz ) the find P . Given density of aluminimum is 2.6 g//cm^(3) and that of steel is 7.8 g//cm^(3) .

Figure shows an aluminium wire of length 60 cm joined to a steel wire of length 80 cm and stretched between two fixed supports. The tension produced is 40 N . The cross-sectional area of the steel wire is 1.0 mm^(2) and that of the aluminimum wire is 3.0 mm^(2) The minimum frequency of a tuning fork which can produce standing waves in the system with the joint as a node is 10P (in Hz ) the find P . Given density of aluminimum is 2.6 g//cm^(3) and that of steel is 7.8 g//cm^(3) .

A steel wire of length 50sqrt(3) cm is connected to an aluminium wire of length 60 cm and stretched between two fixed supports. The tension produced is 104 N , if the cross section area of each wire is 1mm^(2) . If a transverse wave is set up in the wire, find the lowest frequency for which standing waves with node at the joint are produced . (density of aluminimum = 2.6 gm//cm^(3) and density of steel = 7.8 gm//cm^(3) ).

A steel wire of length 50sqrt(3) cm is connected to an aluminium wire of length 60 cm and stretched between two fixed supports. The tension produced is 104 N , if the cross section area of each wire is 1mm^(2) . If a transverse wave is set up in the wire, find the lowest frequency for which standing waves with node at the joint are produced . (density of aluminimum = 2.6 gm//cm^(3) and density of steel = 7.8 gm//cm^(3) ).

A steel wire of length 60 cm and area of cross section 10^(-6)m^(2) is joined with a n aluminium wire of length 45 cm and are of cross section 3xx10^(-6)m^(2) . The composite string is stretched by a tension of 80 N. Density of steel is 7800kgm^(-3) and that of aluminium is 2600kgm^(-3) the minimum frequency of tuning fork. Which can produce standing wave in it with node at joint is

A steel wire of length 60 cm and area of cross section 10^(-6)m^(2) is joined with a n aluminium wire of length 45 cm and are of cross section 3xx10^(-6)m^(2) . The composite string is stretched by a tension of 80 N. Density of steel is 7800kgm^(-3) and that of aluminium is 2600kgm^(-3) the minimum frequency of tuning fork. Which can produce standing wave in it with node at joint is