307205 The radius (in \( \mathop {\rm{A}}^{\circ} \)) of third Bohr orbit of a hydrogen atom is

307206 On the basis of Bohr’s model, the radius of the \({{\rm{3}}^{rd}}\) orbit is

307207 Which state of the triply ionized Beryllium \(({\rm{B}}{{\rm{e}}^{3 + }})\) has the same orbit radius as that of the ground state of hydrogen atom?

307208 Statement A :
The radius of the first orbit of hydrogen atom is \({\rm{0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} \)
Statement B :
Radius of each circular orbit \({\rm{(}}{{\rm{r}}_{\rm{n}}}{\rm{)0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} {\rm{(}}{{\rm{n}}^{\rm{2}}}{\rm{/Z),}}\) where \({\rm{n = 1,2,3}}\) and \({\rm{Z = }}\)atomic number

307209 The radius of second Bohr orbit of hydrogen atom is

307205 The radius (in \( \mathop {\rm{A}}^{\circ} \)) of third Bohr orbit of a hydrogen atom is

307206 On the basis of Bohr’s model, the radius of the \({{\rm{3}}^{rd}}\) orbit is

307207 Which state of the triply ionized Beryllium \(({\rm{B}}{{\rm{e}}^{3 + }})\) has the same orbit radius as that of the ground state of hydrogen atom?

307208 Statement A :
The radius of the first orbit of hydrogen atom is \({\rm{0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} \)
Statement B :
Radius of each circular orbit \({\rm{(}}{{\rm{r}}_{\rm{n}}}{\rm{)0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} {\rm{(}}{{\rm{n}}^{\rm{2}}}{\rm{/Z),}}\) where \({\rm{n = 1,2,3}}\) and \({\rm{Z = }}\)atomic number

307209 The radius of second Bohr orbit of hydrogen atom is

307205 The radius (in \( \mathop {\rm{A}}^{\circ} \)) of third Bohr orbit of a hydrogen atom is

307206 On the basis of Bohr’s model, the radius of the \({{\rm{3}}^{rd}}\) orbit is

307207 Which state of the triply ionized Beryllium \(({\rm{B}}{{\rm{e}}^{3 + }})\) has the same orbit radius as that of the ground state of hydrogen atom?

307208 Statement A :
The radius of the first orbit of hydrogen atom is \({\rm{0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} \)
Statement B :
Radius of each circular orbit \({\rm{(}}{{\rm{r}}_{\rm{n}}}{\rm{)0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} {\rm{(}}{{\rm{n}}^{\rm{2}}}{\rm{/Z),}}\) where \({\rm{n = 1,2,3}}\) and \({\rm{Z = }}\)atomic number

307209 The radius of second Bohr orbit of hydrogen atom is

307205 The radius (in \( \mathop {\rm{A}}^{\circ} \)) of third Bohr orbit of a hydrogen atom is

307206 On the basis of Bohr’s model, the radius of the \({{\rm{3}}^{rd}}\) orbit is

307207 Which state of the triply ionized Beryllium \(({\rm{B}}{{\rm{e}}^{3 + }})\) has the same orbit radius as that of the ground state of hydrogen atom?

307208 Statement A :
The radius of the first orbit of hydrogen atom is \({\rm{0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} \)
Statement B :
Radius of each circular orbit \({\rm{(}}{{\rm{r}}_{\rm{n}}}{\rm{)0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} {\rm{(}}{{\rm{n}}^{\rm{2}}}{\rm{/Z),}}\) where \({\rm{n = 1,2,3}}\) and \({\rm{Z = }}\)atomic number

307209 The radius of second Bohr orbit of hydrogen atom is

307205 The radius (in \( \mathop {\rm{A}}^{\circ} \)) of third Bohr orbit of a hydrogen atom is

307206 On the basis of Bohr’s model, the radius of the \({{\rm{3}}^{rd}}\) orbit is

307207 Which state of the triply ionized Beryllium \(({\rm{B}}{{\rm{e}}^{3 + }})\) has the same orbit radius as that of the ground state of hydrogen atom?

307208 Statement A :
The radius of the first orbit of hydrogen atom is \({\rm{0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} \)
Statement B :
Radius of each circular orbit \({\rm{(}}{{\rm{r}}_{\rm{n}}}{\rm{)0}}{\rm{.529}}\mathop {\rm{A}}\limits^{\rm{o}} {\rm{(}}{{\rm{n}}^{\rm{2}}}{\rm{/Z),}}\) where \({\rm{n = 1,2,3}}\) and \({\rm{Z = }}\)atomic number

307209 The radius of second Bohr orbit of hydrogen atom is