`{:(,"A.","Spring constant",1.,["M"^(1)"L"^(2)"T"^(-2)]),(,"B.","Pascal",2.,["M"^(0)"L"^(0)"T"^(-1)]),(,"C","Hertz",3.,["M"^(1)"L"^(0)"T"^(-2)]),(,"D.","Joule",4.,["M"^(1)"L"^(-1)"T"^(-2)]):}`

{:("List-I","List-2"),((a)"Pressure ",(e)ML^(2)T^(-2)I^(-1)),((b)"Latent heat", (f) M^(0)L^(0)T^(-1)),((c)"Velocity gradient" ,(g) ML^(-1)T^(-2)),((d) "Magnetic flux" ,(h) M^(0)L^(2)T^(-2)):}

Match the following: {:(," ""Column-I",," ""Column-II"),((a),F = A sin(B t) + (1)/(C ln (Dx)) "For above equation to be dimensionally correct",(p),[A] = [M^(1)L^(1)T^(-1)]","[B] = [M^(0)L^(0)T^(-1)]","[C] = [M^(0)L^(0)T^(-1)]),((b) ,"Pressure" = P + (1)/(2)rhov^(2) + gX ,(q),[A] = [M^(0)L^(1)T^(-1)]"," [B] = [M^(0)L^(0)T^(-1)]","[C] = [M^(0)L^(0)T^(-1)]","),((c),X = At+(v)/(B ln(Cr)),(r),[A] = [M^(1)L^(1)T^(-2)]","[B] = [M^(0)L^(0)T^(-1)]","[C] = [M^(-1)L^(0)T^(1)]),(,,(s),"Dimensionally incorrect""):} (Where F = force, P = pressure, rho = density, t = time, v = velocity, a = acceleration, X = displacement)

[M^(1)L^(1)T^(-2)] are the dimensions of

Match the following {:(,,"Table-1",,"Table-2"),(,(A),L,(P),[M^(0)L^(0)T^(-2)]),(,(B),"Magnetic Flux",(Q),[ML^(2)T^(-2)A^(-1)]),(,(C),LC,(R),[ML^(2)T^(-2)A^(-2)]),(,(D),CR^(2),(S),"None"):}

The expression [M^(1)L^(2)T^(-2)] represents

Dimensions of epsilon_(0) are M^(-1)L^(-3)T^(4)A^(2) M^(0)L^(-3)T^(3)A^(3) M^(-1)L^(-3)T^(3)A M^(-1)L^(-3)TA^(2)