Let` A_(0)` be the area enclosed by the orbit in a hydrogen atom .The graph of `ln (A_(0) //A_(1))` against `ln(n)`

Let theta=(a_(1),a_(2),a_(3),...,a_(n)) be a given arrangement of n distinct objects a_(1),a_(2),a_(3),…,a_(n) . A derangement of theta is an arrangment of these n objects in which none of the objects occupies its original position. Let D_(n) be the number of derangements of the permutations theta . The relation between D_(n) and D_(n-1) is given by

In terms of Bohr radius a_(0) , the radius of the third Bohr orbit of a hydrogen atom is given by

Let A_(1), A_(2), A_(3), A_(4) be the areas of the triangular faces of a tetrahedron, and h_(1), h_(2), h_(3), h_(4) be the corresponding altitudes of the tetrahedron. If the volume of tetrahedron is 1/6 cubic units, then find the minimum value of (A_(1) +A_(2) + A_(3) + A_(4))(h_(1)+ h_(2)+h_(3)+h_(4)) (in cubic units).

Let A_(r) be the area of the region bounded between the curves y^(2)=(e^(-kr))x("where "k gt0,r in N)" and the line "y=mx ("where "m ne 0) , k and m are some constants A_(1),A_(2),A_(3),… are in G.P. with common ratio

If A_(n) is the area bounded by y=x and y=x^(n), n in N, then A_(2).A_(3)…A_(n)=

Let a_(1), a_(2) ...be positive real numbers in geometric progression. For n, if A_(n), G_(n), H_(n) are respectively the arithmetic mean, geometric mean and harmonic mean of a_(1), a_(2),..., a_(n) . Then, find an expression for the geometric mean of G_(1), G_(2),...,G_(n) in terms of A_(1), A_(2),...,A_(n), H_(1), H_(2),..., H_(n)

Prove, Using the Rolle's theorem that between any two distinct real zeros of the polynomial a_(n) x^(n) + a_(n-1) x^(n-1) + …..a_(1)x + a_(0) there is a zero of the polynomial . na_(n) x^(n-1) + (n-1) a_(n-1) x^(n-2) + ….+ a_(1)

If a_(1) = 4 and a_(n + 1) = a_(n) + 4n for n gt= 1 , then the value of a_(100) is