Saturday, April 2, 2016

RAMAN EFFECT - THEN AND NOW - Palahalli Vishwanath - Deccan Herald

This appeared on FEb 23rd 2016 in SPECTRUM DECCAN HERALD


RAMAN EFFECT - THEN AND NOW

Palahalli R Vishwanath

(The latest use of this phenomenon is in space exploration )

" Chandrasekhara Venkata Raman, Nobel-laureate (Physics-1930), assisted by K S Krishnan at IACS, Calcutta, India, discovered on 28 February 1928, that when a beam of coloured light entered a liquid, a fraction of the light scattered was of a different colour, dependent on material property. This radiation effect of molecular scattering of light bears his name as ‘Raman Effect’. This is the plaque which greets visitors to the Indian Association for Cultivation of Science at Jadavpur, Kolkatta. Thus 28th February 1928 is a golden day for Indian science.
Raman Effect can be easily understood if the incident light is treated as consisting of particles called photons. Most of the encounters of the particles with the target are what is called elastic scattering where there is no change in energy. However, in few encounters, the energy of the photon is changed by either giving energy or taking energy from the molecule Thus the scattered light will have a frequency (and colour) different than that of the incident light. Since the phenomenon can be understood with only the photonic aspect of light , this effect was also seen as one of the proofs for the quantum theory. Two year later along with S. Bhagavantham Professor Raman was able to show that "the light quantum possesses an intrinsic spin equal to one Bohr unit of angular momentum" which further confirmed the quantum nature of light
Professor Raman , who was born in 1888, started working in Kolkata in 1907 as a civil servant. Because of his passion in physics, he started doing experimental work in the Indian Association for Cultivation of Science. He took up a professorship in Calcutta University in 1917 where he worked for 15 years. Later he served as the director of the Indian Institute of Science in Bangalore from 1934 to 1948 and of the Raman Research Institute from 1949 until his death in 1970, at the age of 82.
His early work was in acoustics of musical instruments. In 1924 he was elected a Fellow of the Royal Society ' for his considerable additions to our knowledge of sound and light'. He was
only the fourth Indian so honored. He received the Nobel Prize in physics in 1930. In his later years he became interested in the structure of crystals, especially diamonds.. Educated entirely in India, Raman did outstanding work at a time when there was practically no research in the country . He was famous for his lectures " holding the audience spellbound with his booming voice, lively demonstrations, superb diction and rich humor". S. Ramasehan's statement ' I have never seen anyone who enjoyed science so much' sums up this great man. Raman was the paternal uncle of Subrahmanyan Chandrasekhar who later won the Nobel Prize in Physics (1983) for his research in astrophysics
Prof. Raman stated in his Nobel address" .. enables us to obtain an insight into the ultimate structure of the scattering substance" which made possible the numerous applications of Raman effect. The unique spectrum of Raman scattered light for any particular substance serves as a "fingerprint" that could be used for qualitative analysis of solids,liquids gases and even a mixture of materials. Further, the intensity of the spectral lines is related to the amount of the substance. It is a ubiquitous technique, giving information on what and how much is present in a variety of samples. While generally only one part in a thousand of the total intensity of incident light is Rayleigh scattered, this value drops to one part in a million for Raman scattering . Because of this Prof Raman was also aware of the need for more intense light sources to amplify the effect and observation of the scattered light. The laser provided this very much needed intense source of light. Thus the phenomenon t has become more prominent in the years since powerful monochromatic laser sources could provide the scattering power. Since lasers are highly monochromatic it is very helpful in observing even very small shifts. Further the use of selective filters allows only the components of inelastic scattering.
i

From 1980s with improved instrumentation many new applications for Raman effect have been found. Its ability to detect even very small amounts of chemical and biological molecules has been helpful in treatment of cancer, malaria, HIV and other illnesses. It now has varied uses like (a) analyze nuclear waste material from a safe distance (b) detect trace amounts of molecules in fraudulent paintings, chemical weapons etc.(c) to identify dangerous substances such as improvised explosive devices at airports (d) other defense applications to identify potential threats and hazards (e) food technology etc
RAMAN EFFECT - THEN AND NOW

Palahalli R Vishwanath

(The latest use of this phenomenon is in space exploration )

" Chandrasekhara Venkata Raman, Nobel-laureate (Physics-1930), assisted by K S Krishnan at IACS, Calcutta, India, discovered on 28 February 1928, that when a beam of coloured light entered a liquid, a fraction of the light scattered was of a different colour, dependent on material property. This radiation effect of molecular scattering of light bears his name as ‘Raman Effect’. This is the plaque which greets visitors to the Indian Association for Cultivation of Science at Jadavpur, Kolkatta. Thus 28th February 1928 is a golden day for Indian science.
Raman Effect can be easily understood if the incident light is treated as consisting of particles called photons. Most of the encounters of the particles with the target are what is called elastic scattering where there is no change in energy. However, in few encounters, the energy of the photon is changed by either giving energy or taking energy from the molecule Thus the scattered light will have a frequency (and colour) different than that of the incident light. Since the phenomenon can be understood with only the photonic aspect of light , this effect was also seen as one of the proofs for the quantum theory. Two year later along with S. Bhagavantham Professor Raman was able to show that "the light quantum possesses an intrinsic spin equal to one Bohr unit of angular momentum" which further confirmed the quantum nature of light
Professor Raman , who was born in 1888, started working in Kolkata in 1907 as a civil servant. Because of his passion in physics, he started doing experimental work in the Indian Association for Cultivation of Science. He took up a professorship in Calcutta University in 1917 where he worked for 15 years. Later he served as the director of the Indian Institute of Science in Bangalore from 1934 to 1948 and of the Raman Research Institute from 1949 until his death in 1970, at the age of 82.
His early work was in acoustics of musical instruments. In 1924 he was elected a Fellow of the Royal Society ' for his considerable additions to our knowledge of sound and light'. He was
only the fourth Indian so honored. He received the Nobel Prize in physics in 1930. In his later years he became interested in the structure of crystals, especially diamonds.. Educated entirely in India, Raman did outstanding work at a time when there was practically no research in the country . He was famous for his lectures " holding the audience spellbound with his booming voice, lively demonstrations, superb diction and rich humor". S. Ramasehan's statement ' I have never seen anyone who enjoyed science so much' sums up this great man. Raman was the paternal uncle of Subrahmanyan Chandrasekhar who later won the Nobel Prize in Physics (1983) for his research in astrophysics
Prof. Raman stated in his Nobel address" .. enables us to obtain an insight into the ultimate structure of the scattering substance" which made possible the numerous applications of Raman effect. The unique spectrum of Raman scattered light for any particular substance serves as a "fingerprint" that could be used for qualitative analysis of solids,liquids gases and even a mixture of materials. Further, the intensity of the spectral lines is related to the amount of the substance. It is a ubiquitous technique, giving information on what and how much is present in a variety of samples. While generally only one part in a thousand of the total intensity of incident light is Rayleigh scattered, this value drops to one part in a million for Raman scattering . Because of this Prof Raman was also aware of the need for more intense light sources to amplify the effect and observation of the scattered light. The laser provided this very much needed intense source of light. Thus the phenomenon t has become more prominent in the years since powerful monochromatic laser sources could provide the scattering power. Since lasers are highly monochromatic it is very helpful in observing even very small shifts. Further the use of selective filters allows only the components of inelastic scattering.
i

From 1980s with improved instrumentation many new applications for Raman effect have been found. Its ability to detect even very small amounts of chemical and biological molecules has been helpful in treatment of cancer, malaria, HIV and other illnesses. It now has varied uses like (a) analyze nuclear waste material from a safe distance (b) detect trace amounts of molecules in fraudulent paintings, chemical weapons etc.(c) to identify dangerous substances such as improvised explosive devices at airports (d) other defense applications to identify potential threats and hazards (e) food technology etc

Raman effect is also playing an important role in astronomy . The feasibility of using the Raman spectrum to investigate the physical structure of outer planet atmospheres has been examined . Raman scattering makes contribution to spectra because of very large amounts of hydrogen molecules in their atmosphere. . The spectra of Uranus and Neptune in the UV and visual range have been detected and these observations give information on the amount of hydrocarbons in the atmosphere Similar methods can hopefully be used for exoplanets also

In 2004, a journal devoted to spectroscopy devoted its special issue to Raman spectroscopy breaking terrestrial barriers . Raman spectroscopy can provide highly specific chemical fingerprints of inorganic and organic materials and is therefore expected to play a significant role in interplanetary missions, especially for the search for life elsewhere in our solar system. In Raman spectra, the peaks of minerals and molecular bonds are very sharp and well separated from each other, which enable direct mineral identification from raw Raman spectra. The simplicity in Raman spectra and the non-ambiguity for phase identification are the keys for its application in planetary explorations. Future planetary missions of NASA and ESA to Europa and Mars are all expected to carry Raman spectrometers.. A Raman spectrometer is now being miniaturized for the Exo Mars Rover and is expected to identify organic compounds that could be related to signatures of life like cyanobacteria, chlorophyll, or amino acids, It is also expected to provide a general mineralogical overview, especially those minerals produced by water‐related processes. NASA's mission to Europa, an important satellite of Jupiter, will try to analyze the surface environment and Raman spectra will be an important contribution to the measurements of the key habitability parameters, such as temperature, pH etc. Remote Raman measurements conducted at the University of Hawaii were able to identify minerals under high temperatures such as those that exist on the surface of Venus demonstrating the ability of the remote Raman system to identify atmospheric constituents without landing on the harsh Venusian surface.
------------------------------------------------------------------------------------------------------------------------

1. The original apparatus used by Raman

2. The schematic of the Raman effect : Incident light with a frequency Fo gets changed to Fo +/- Fm

3. A Raman spectrometer to be used on Mars is undergoing checks

Raman effect is also playing an important role in astronomy . The feasibility of using the Raman spectrum to investigate the physical structure of outer planet atmospheres has been examined . Raman scattering makes contribution to spectra because of very large amounts of hydrogen molecules in their atmosphere. . The spectra of Uranus and Neptune in the UV and visual range have been detected and these observations give information on the amount of hydrocarbons in the atmosphere Similar methods can hopefully be used for exoplanets also

In 2004, a journal devoted to spectroscopy devoted its special issue to Raman spectroscopy breaking terrestrial barriers . Raman spectroscopy can provide highly specific chemical fingerprints of inorganic and organic materials and is therefore expected to play a significant role in interplanetary missions, especially for the search for life elsewhere in our solar system. In Raman spectra, the peaks of minerals and molecular bonds are very sharp and well separated from each other, which enable direct mineral identification from raw Raman spectra. The simplicity in Raman
RAMAN EFFECT - THEN AND NOW

Palahalli R Vishwanath

(The latest use of this phenomenon is in space exploration )

" Chandrasekhara Venkata Raman, Nobel-laureate (Physics-1930), assisted by K S Krishnan at IACS, Calcutta, India, discovered on 28 February 1928, that when a beam of coloured light entered a liquid, a fraction of the light scattered was of a different colour, dependent on material property. This radiation effect of molecular scattering of light bears his name as ‘Raman Effect’. This is the plaque which greets visitors to the Indian Association for Cultivation of Science at Jadavpur, Kolkatta. Thus 28th February 1928 is a golden day for Indian science.
Raman Effect can be easily understood if the incident light is treated as consisting of particles called photons. Most of the encounters of the particles with the target are what is called elastic scattering where there is no change in energy. However, in few encounters, the energy of the photon is changed by either giving energy or taking energy from the molecule Thus the scattered light will have a frequency (and colour) different than that of the incident light. Since the phenomenon can be understood with only the photonic aspect of light , this effect was also seen as one of the proofs for the quantum theory. Two year later along with S. Bhagavantham Professor Raman was able to show that "the light quantum possesses an intrinsic spin equal to one Bohr unit of angular momentum" which further confirmed the quantum nature of light
Professor Raman , who was born in 1888, started working in Kolkata in 1907 as a civil servant. Because of his passion in physics, he started doing experimental work in the Indian Association for Cultivation of Science. He took up a professorship in Calcutta University in 1917 where he worked for 15 years. Later he served as the director of the Indian Institute of Science in Bangalore from 1934 to 1948 and of the Raman Research Institute from 1949 until his death in 1970, at the age of 82.
His early work was in acoustics of musical instruments. In 1924 he was elected a Fellow of the Royal Society ' for his considerable additions to our knowledge of sound and light'. He was
only the fourth Indian so honored. He received the Nobel Prize in physics in 1930. In his later years he became interested in the structure of crystals, especially diamonds.. Educated entirely in India, Raman did outstanding work at a time when there was practically no research in the country . He was famous for his lectures " holding the audience spellbound with his booming voice, lively demonstrations, superb diction and rich humor". S. Ramasehan's statement ' I have never seen anyone who enjoyed science so much' sums up this great man. Raman was the paternal uncle of Subrahmanyan Chandrasekhar who later won the Nobel Prize in Physics (1983) for his research in astrophysics
Prof. Raman stated in his Nobel address" .. enables us to obtain an insight into the ultimate structure of the scattering substance" which made possible the numerous applications of Raman effect. The unique spectrum of Raman scattered light for any particular substance serves as a "fingerprint" that could be used for qualitative analysis of solids,liquids gases and even a mixture of materials. Further, the intensity of the spectral lines is related to the amount of the substance. It is a ubiquitous technique, giving information on what and how much is present in a variety of samples. While generally only one part in a thousand of the total intensity of incident light is Rayleigh scattered, this value drops to one part in a million for Raman scattering . Because of this Prof Raman was also aware of the need for more intense light sources to amplify the effect and observation of the scattered light. The laser provided this very much needed intense source of light. Thus the phenomenon t has become more prominent in the years since powerful monochromatic laser sources could provide the scattering power. Since lasers are highly monochromatic it is very helpful in observing even very small shifts. Further the use of selective filters allows only the components of inelastic scattering.
i

From 1980s with improved instrumentation many new applications for Raman effect have been found. Its ability to detect even very small amounts of chemical and biological molecules has been helpful in treatment of cancer, malaria, HIV and other illnesses. It now has varied uses like (a) analyze nuclear waste material from a safe distance (b) detect trace amounts of molecules in fraudulent paintings, chemical weapons etc.(c) to identify dangerous substances such as improvised explosive devices at airports (d) other defense applications to identify potential threats and hazards (e) food technology etc

Raman effect is also playing an important role in astronomy . The feasibility of using the Raman spectrum to investigate the physical structure of outer planet atmospheres has been examined . Raman scattering makes contribution to spectra because of very large amounts of hydrogen molecules in their atmosphere. . The spectra of Uranus and Neptune in the UV and visual range have been detected and these observations give information on the amount of hydrocarbons in the atmosphere Similar methods can hopefully be used for exoplanets also

In 2004, a journal devoted to spectroscopy devoted its special issue to Raman spectroscopy breaking terrestrial barriers . Raman spectroscopy can provide highly specific chemical fingerprints of inorganic and organic materials and is therefore expected to play a significant role in interplanetary missions, especially for the search for life elsewhere in our solar system. In Raman spectra, the peaks of minerals and molecular bonds are very sharp and well separated from each other, which enable direct mineral identification from raw Raman spectra. The simplicity in Raman spectra and the non-ambiguity for phase identification are the keys for its application in planetary explorations. Future planetary missions of NASA and ESA to Europa and Mars are all expected to carry Raman spectrometers.. A Raman spectrometer is now being miniaturized for the Exo Mars Rover and is expected to identify organic compounds that could be related to signatures of life like cyanobacteria, chlorophyll, or amino acids, It is also expected to provide a general mineralogical overview, especially those minerals produced by water‐related processes. NASA's mission to Europa, an important satellite of Jupiter, will try to analyze the surface environment and Raman spectra will be an important contribution to the measurements of the key habitability parameters, such as temperature, pH etc. Remote Raman measurements conducted at the University of Hawaii were able to identify minerals under high temperatures such as those that exist on the surface of Venus demonstrating the ability of the remote Raman system to identify atmospheric constituents without landing on the harsh Venusian surface.
------------------------------------------------------------------------------------------------------------------------

1. The original apparatus used by Raman

2. The schematic of the Raman effect : Incident light with a frequency Fo gets changed to Fo +/- Fm

3. A Raman spectrometer to be used on Mars is undergoing checks

spectra and the non-ambiguity for phase identification are the keys for its application in planetary explorations. Future planetary missions of NASA and ESA to Europa and Mars are all expected to carry Raman spectrometers.. A Raman spectrometer is now being miniaturized for the Exo Mars Rover and is expected to identify organic compounds that could be related to signatures of life like cyanobacteria, chlorophyll, or amino acids, It is also expected to provide a general mineralogical overview, especially those minerals produced by water‐related processes. NASA's mission to Europa, an important satellite of Jupiter, will try to analyze the surface environment and Raman spectra will be an important contribution to the measurements of the key habitability parameters, such as temperature, pH etc. Remote Raman measurements conducted at the University of Hawaii were able to identify minerals under high temperatures such as those that exist on the surface of Venus demonstrating the ability of the remote Raman system to identify atmospheric constituents without landing on the harsh Venusian surface.
------------------------------------------------------------------------------------------------------------------------

1. The original apparatus used by Raman

2. The schematic of the Raman effect : Incident light with a frequency Fo gets changed to Fo +/- Fm

3. A Raman spectrometer to be used on Mars is undergoing checks


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