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A long straight wire, of circular cross section (radius =a) carries a current I which is uniformaly distributed across the cross section of the wire. Use Amphere 's circular law to calculate the magnetic field B(r) , due to wire, at a point distant `r lt a` and `rgta` from its axis. Draw a graph showing the dependence of B(r) on r.

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(i)For `rlta`
`ointvecB.vec(dl)=mu_(0)I_("enclosed")`
`I_("enclosed")/(pia^(2))=I/(pir^(2))`
`I_("enclosed")=Ir^(2)/a^(2)`
`vecB.vec(dl)=Bdl=(because cos theta=1)`
`becauseointBdl=mu_(0)lr^(2)/a^(2)`
`B(2pir)=mu_(0)Ir^(2)/a^(2)`
`B=mu_(0)/(2pi)I/a^(2) r`
(ii)For `rgta`
From Ampere's circuital law
`oint vecB.vecdl=mu_(0)I_("enclosed")`
`vecB.vec(dl)=Bdl cos theta`
`theta=0`
`vecB.vec(dl)=Bdl`
`I_("enclosed")=I`
`ointBdl=mu_(0)I`
`Bointdl=mu_(0)I`
`B(2pir)=mu_(0)I`
`B=(mu_(0)I)/(2pir)`

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