Calculate the Rydberg constant ` R_H` if `He^+` ions are known to have the wavelength difference between the from ( of the longest wavength ) lines fo Balmer and Lyman series equal to ` 133.7 nm`.

Calculate the Rydberg constant R if He^(+) ions are known to have the wavelength difference between the first (of the longest wavelength) lines of the Balmer and Lyman series equal to Delta lambda = 133.7nm .

What hydrohen-like ion has the wave-length difference between the first lines of the Balmer and Lyman series equal to 593 Å .

What hydrogen-like ion has the wavelength difference between the first lines of the Balmer Lyman series equal to 59.3nm ?

What hydrogen-like ion has the wavelength difference between the first lines of the Balmer Lyman series equal to 59.3nm ?

What hydrogen like ion has wavelength difference between the first lines of Balmer and Lyman series equal to 59.3 nm?( R_H=109678 cm^-1 )

What hydrogen-like ion has the wavelength difference the first lines of Balmer and Lyman series equal to 59.3 nm ? R_(H) = 109.678 cm^(-1)

If He^(+) ions are known to have the wavelength difference of the first lines of Balmer series and first line of Lyman series equal to Delta lambda=132nm then the value of Rydberg constant (R) is

The shortest wavelength of H-atom in Lyman series is x, then longest wavelength in Balmer series of He^(+) is

The shortest wavelength of H-atom in Lyman series is x, then longest wavelength in Balmer series of He^(+) is