Unit-5

Question Bank

Q-Explain in brief Absorption Spectroscopy.

A-The absorption of light by atoms provides a powerful analytical tool for both quantitative and qualitative analysis. Atomic absorption spectroscopy (AAS) is based upon the principle that free atoms in the ground state can absorb light of a certain wavelength. Absorption for each element is specific; no other elements absorb this wavelength. Absorption Spectroscopy is of following parts:

IR Spectroscopy:

The change in the vibrational motion of molecule is absorbed in the Infrared Region this is why it is also called as the Infrared Spectroscopy. If vibration in the molecule persists then it should change its dipole moment that may be the magnitude form or oriented with its direction. When taking the example of Polar molecule (A-B) as the polar molecule shows the property of the high electronegative atom attracts the electron pair towards it so that it gets partial negative and partial positive charges. So in the polar molecule the atoms are making rotation therefore one side is positive pole while other is negative but due to the rotation at its own axis then there is no change in the magnitude effects hence it posses the generation of magnetic field which in result there in the electric flux or there is a change in the direction.

Ultraviolet Spectroscopy:

Ultraviolet and Visible Spectroscopy helps ion the determination of the absorbance spectra of the compound in the solution. The absorbance of light energy or the electromagnetic radiations are observed. This is responsible for the exciting the electron from the ground state to the first singlet excited state of a compound.

NMR Spectroscopy:

NMR stands for the Nuclear Magnetic Resonance Spectroscopy. NMR Spectroscopy technique is used to observe local magnetic fields around atomic nuclei. An NMR instrument allows the molecular structure of a material to be analyzed by observing and measuring the interaction of nuclear spins when placed in a powerful magnetic field. For the analysis of molecular structure at the atomic level, electron microscopes and X-ray diffraction instruments can also be used, but the advantages of NMR are that sample measurements are non-destructive and there is less sample preparation required.

Q- What are the applications of spectroscopy?

A-Applications of Spectroscopy:

• Cure monitoring of composites using optical fibers.
• Estimate weathered wood exposure times using near infrared spectroscopy.
• Measurement of toxic compounds in blood samples
• Non-destructive elemental analysis by X-ray fluorescence.
• Electronic structure research with various spectroscopes.

Q- What are the selection rules of electronic spectroscopy?

A-  The first rule says that; allowed transitions must involve the promotion of electrons without a change in their spin.
The second rule says that if the molecule has a centre of symmetry, transitions within a given set of p or d orbitals (i.e. those which only involve a redistribution of electrons within a given subshell) are forbidden.
 

Q- What do you understood by Raman Spectroscopy?

A- Raman Spectroscopy deals with the analysis of the chemical in a non-destructive form. This help in extracting a detailed information about the chemical structure, phase and polymorphy, crystallinity and  molecular interactions. This is purely based on the interaction of light with a chemical bonds in the material.

Raman is used to be work as a scattering technique where by the it help in scattering the light of the source at different wavelength while some of the scattered lights are of same wavelength as of source and hence that light are not useful for gathering the further information this is called as the Rayleigh Scatter while the remaining light that is scattered at different wavelength are called as the Raman Scatter.

Raman Spectroscopy provide the chemical structure of material, the polymorphism information is extracted from the Raman Spectroscopy, contamination and impurity. This is used for qualitative as well as the quantitative purpose. This provide the unique fingerprint of chemicals further which can be used in material identification.

Q- Write the application of electronic spectroscopy.

A-

• Cure monitoring of composites using optical fibers.
• Estimate weathered wood exposure times using near infrared spectroscopy.
• Measurement of toxic compounds in blood samples
• Non-destructive elemental analysis by X-ray fluorescence.
• Electronic structure research with various spectroscopes.

Q- What is Rotational Spectroscopy?

A-Rotational Spectroscopy is also called as the microwave spectroscopy. It is the measurement of energy of transition between quantized rotational states of molecules in the gas phase. The rotational spectra of non-polar molecules cannot be observed by this method while it can be measured by Raman spectroscopy. Rotational spectroscopy is sometimes referred to as pure rotational spectroscopy to distinguish it from rotational-vibrational spectroscopy where changes in rotational energy occur together with changes in vibrational energy and also from ro-vibronic spectroscopy where rotational, vibrational and electronic energy changes occur simultaneously. The molecules of the Rotational spectroscopy are classified according to their symmetry.

Q- What do you understand by Infrared Spectroscopy?

A-The change in the vibrational motion of molecule is absorbed in the Infrared Region this is why it is also called as the Infrared Spectroscopy. If vibration in the molecule persists then it should change its dipole moment that may be the magnitude form or oriented with its direction.

Q- Explain NMR Spectroscopy.

A-NMR stands for the Nuclear Magnetic Resonance Spectroscopy. NMR Spectroscopy technique is used to observe local magnetic fields around atomic nuclei. An NMR instrument allows the molecular structure of a material to be analyzed by observing and measuring the interaction of nuclear spins when placed in a powerful magnetic field. For the analysis of molecular structure at the atomic level, electron microscopes and X-ray diffraction instruments can also be used, but the advantages of NMR are that sample measurements are non-destructive and there is less sample preparation required.

Q- Explain about MRI.

A-This is the medical imaging technique which is used in radiology to form pictures of anatomy and physiological process of body. This technique uses very strong magnetic fields and high radio waves to generate organs image. MRI is a medical application of NMR that can also be used for imaging in other NMR applications such as NMR spectroscopy.

Q- Write the mechanism of MRI.

A-Magnetic resonance imaging (MRI) uses the body's natural magnetic properties to produce detailed images from any part of the body. For imaging purposes the hydrogen nucleus (a single proton) is used because of its abundance in water and fat. The hydrogen proton can be likened to the planet earth, spinning on its axis, with a north-south pole. In this respect it behaves like a small bar magnet. Under normal circumstances, these hydrogen proton “bar magnets” spin in the body with their axes randomly aligned.

When the body is placed in a strong magnetic field, such as an MRI scanner, the protons' axes all line up. This uniform alignment creates a magnetic vector oriented along the axis of the MRI scanner. MRI scanners come in different field strengths, usually between 0.5 and 1.5 tesla.

When additional energy is added to the magnetic field, the magnetic vector is deflected. The radio wave frequency (RF) that causes the hydrogen nuclei to resonate is dependent on the element sought and the strength of the magnetic field.

The strength of the magnetic field can be altered electronically from head to toe using a series of gradient electric coils, and, by altering the local magnetic field by these small increments, different slices of the body will resonate as different frequencies are applied. When the radiofrequency source is switched off the magnetic vector returns to its resting state, and this causes a signal (also a radio wave) to be emitted. It is this signal which is used to create the MR images. Receiver coils are used around the body part in question to act as aerials to improve the detection of the emitted signal. The intensity of the received signal is then plotted on a grey scale and cross sectional images are built up.Multiple transmitted radiofrequency pulses can be used in sequence to emphasise particular tissues or abnormalities. A different emphasis occurs because different tissues relax at different rates when the transmitted radiofrequency pulse is switched off. The time taken for the protons to fully relax is measured in two ways. The first is the time taken for the magnetic vector to return to its resting state and the second is the time needed for the axial spin to return to its resting state. The first is called T1 relaxation, the second is called T2 relaxation.

An MR examination is thus made up of a series of pulse sequences. Different tissues have different relaxation times and can be identified separately. By using a “fat suppression” pulse sequence, for example, the signal from fat will be removed, leaving only the signal from any abnormalities lying within it.

Most diseases manifest themselves by an increase in water content, so MRI is a sensitive test for the detection of disease. The exact nature of the pathology can be more difficult to ascertain: for example, infection and tumour can in some cases look similar. A careful analysis of the images by a radiologist will often yield the correct answer.

There are no known biological hazards of MRI because, unlike x ray and computed tomography, MRI uses radiation in the radiofrequency range which is found all around us and does not damage tissue as it passes through.