The wavelength of first line of balmer series in hydrogen spectrum is 6563 A. A. H-alpha light is the brightest hydrogen line in the visible spectral range. The first line of the Balmer series occurs at a wavelength of 656.3 nm. Also find the wavelength of the first member of Lyman series in the same spectrum. AOC fires back at critics of her Vanity Fair photo shoot We get Balmer series of the … The first line of Balmer series has wavelength 6563 Å. Calculate the value of Rydberg constant if the wavelength of the first member of Balmer series in the hydrogen spectrum is 6563 amstrong. What will be the wavelength of the first member of Lyman series (a) 1215.4 Å (b) 2500 Å (c) 7500 Å (d) 600 Å The wavelength of the first member of Balmer series in the hydrogen spectrum is 6563A o.Calculate the wavelength of the first member of lyman series in the same spectrum. View All Answers (1) S safeer. Solution Show Solution The Rydberg formula for the spectrum of the hydrogen atom is given below: Then the wavelength (in Å) of the first member of Lyman series in the - 11005293 The wavelength of the first member of the Balmer series in hydrogen spectrum is x Å. Using Rydberg formula, calculate the wavelengths of the spectral lines of the first member of the Lyman series and of the Balmer series. For first member of Balmer series wave length is … The first line of Balmer series has wavelength 6563 Å. Find the wavelength of first line of lyman series in the same spectrum. H-alpha (Hα) is a specific deep-red visible spectral line in the Balmer series with a wavelength of 656.28 nm in air; it occurs when a hydrogen electron falls from its third to second lowest energy level. What will be the wavelength of the first member of Lyman series. If the wavelength of first member of Balmer series of hydrogen spectrum is 6564 A°, the wavelength of second member of Balmer series will be: (A) 121 What is the energy difference between the two energy levels involved in the emission that results in this spectral line? m⁻¹ A/C to question, here it is given that first member of balmer series of hydrogen atom has wavelength of 656.3 … Then the wavelength of the second member is. the shortest line of Lyman series p = 1 and n = ∞ Balmer Series: If the transition of electron takes place from any higher orbit (principal quantum number = 3, 4, 5, …) to the second orbit (principal quantum number = 2).