ATOMS The first model of atom was proposed by J. J. Thomson in 1898.

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ATOMS The first model of atom was proposed by J. J. Thomson in 1898. According to this model, the positive charge of the atom is uniformly distributed throughout the volume of the atom and the negatively charged electrons are embedded in it like seeds in a watermelon. This model was picturesquely called plum pudding model of the atom. However subsequent studies on atoms, as described in this chapter, showed that the distribution of the electrons and positive charges are very different from that proposed in this model.

Ernst Rutherford (1871–1937), a former research student of J. J. Thomson, was engaged in experiments on α-particles emitted by some radioactive elements. In 1906, he proposed a classic experiment of scattering of these α-particles by atoms to investigate the atomic structure. This experiment was later performed around 1911 by Hans Geiger (1882–1945) and Ernst Marsden (1889–1970, who was 20 year-old student and had not yet earned his bachelor’s degree). The details are discussed in Section 12.2. The explanation of the results led to the birth of Rutherford’s planetary model of atom (also called the nuclear model of the atom). According to this the entire positive charge and most of the mass of the atom is concentrated in a small volume called the nucleus with electrons revolving around the nucleus just as planets revolve around the sun.

ALPHA-PARTICLE SCATTERING EXPERIMENT Alpha-particles emitted by a 83Bi214 radioactive source were collimated into a narrow beam by their passage through lead bricks. The beam was allowed to fall on a thin foil of gold of thickness 2.1 × 10–7 m. The scattered alpha-particles were observed through a rotatable detector consisting of zinc sulphide screen and a microscope.

Graph of the total number of α-particles scattered at different angles, in a given interval of time. Many of the α-particles pass through the foil. It means that they do not suffer any collisions. Only about 0.14% of the incident α-particles scatter by more than 1º; and about 1 in 8000 deflect by more than 90º.

Rutherford argued that, to deflect the α-particle backwards, it must experience a large repulsive force. This force could be provided if the greater part of the mass of the atom and its positive charge were concentrated tightly at its centre. Then the incoming α-particle could get very close to the positive charge without penetrating it, and such a close encounter would result in a large deflection. This agreement supported the hypothesis of the nuclear atom. This is why Rutherford is credited with the discovery of the nucleus. In Rutherford’s nuclear model of the atom, the entire positive charge and most of the mass of the atom are concentrated in the nucleus with the electrons some distance away. The electrons would be moving in orbits about the nucleus just as the planets do around the sun.

Alpha-particle trajectory The trajectory traced by an α-particle depends on the impact parameter, b of collision. The impact parameter is the perpendicular distance of the initial velocity vector of the α-particle from the centre of the nucleus It is seen that an α-particle close to the nucleus (small impact parameter) suffers large scattering. In case of head-on collision, the impact parameter is minimum and the α-particle rebounds back ( θ≈π). For a large impact parameter, the α-particle goes nearly undeviated and has a small deflection ( θ≈0).

Total energy of revolving electron of hydrogen atom The electrostatic force of attraction ( Fe ) between the revolving electrons and the nucleus provides the requisite centripetal force (Fc) keep them in their orbits. Thus the relation between the orbit radius and the electron velocity is The kinetic energy (K) of the revolving electron

The electrostatic potential energy (U) of the electron Thus the total energy E of the electron in a hydrogen atom is The total energy of the electron is negative. This implies the fact that the electron is bound to the nucleus.

ATOMIC SPECTRA ultraviolet I n f r a r e d r e g i o n In the early nineteenth century it was also established that each element is associated with a characteristic spectrum of radiation. for example, hydrogen always emit radiations of certain wavelengths only. ultraviolet Visible light I n f r a r e d r e g i o n In 1885, the first such series was observed by a Swedish school teacher Johann Jakob Balmer (1825–1898) in the visible region of the hydrogen spectrum. This series is called Balmer series

For n = 4, one obtains the wavelength 486.1 nm. Taking n = 3 in Balmer formula we obtains the wavelength For n = 4, one obtains the wavelength 486.1 nm. For n = ∞., one obtains the limit of the series, at λ = 364.6 nm. This is the shortest wavelength in the Balmer series.

Other series of spectra for hydrogen were subsequently discovered. These are known, after their discoverers, as Lyman, Paschen, Brackett, and Pfund series. These are represented by the formulae: The Lyman series is in the ultraviolet, and the Paschen and Brackett series are in the infrared region. The Balmer formula may be written in terms of frequency

Shortcomings in the Rutherford’s planetary model of atom According to the Rutherford’s planetary model of atom negatively charged electrons revolves around the positively charged centre nucleus. As we know the revolving motion of the electrons around the nucleus is an accelerated motion. According to classical electromagnetic theory, an accelerating charged particle emits radiation in the form of electromagnetic waves. The energy of an accelerating electron should therefore, continuously decrease. The electron would spiral inward and eventually fall into the nucleus. Thus, such an atom can not be stable. 2. Further, according to the classical electromagnetic theory, the frequency of the electromagnetic waves emitted by the revolving electrons is equal to the frequency of revolution. As the electrons spiral inwards, their angular velocities and hence their frequencies would change continuously, and so will the frequency of the light emitted. Thus, they would emit a continuous spectrum, in contradiction to the line spectrum actually observed.