Ashok Chandran

Blogs are an interactive conversation platform allowing active participation by all users not only to read, but also write and comment. Blogging allows you to share your knowledge and expertise. Blogs work on the principle that Knowledge shared is knowledge gained or knowledge multiplied.

Blogging is extremely easy and cost effective way to build your Personal Brand allowing you access to newer contacts and newer opportunities. You can position yourself as an expert or authority on the subject of your expertise. You can connect with like minded people and build your own community.

Blogs are a phenomenon that you cannot ignore, postpone, or delegate. Blogs are not a business elective, They are a prerequisite.

First, a few numbers. There are atleast 9 million blogs out there, with 40,000 new ones popping up each day. Some discuss poetry, others constitutional law. And, yes, many are plain silly. Blogs could be talking about your business, engaging your employees, or leaking confidential information that you thought nobody knew.

This is just the beginning. Many of the same folks who developed blogs are busy adding features so that bloggers can start up music and video channels and team up on editorial projects. The divide between the publishers and the public is collapsing. This turns mass media upside down. It creates media of the masses.

Business or corporate blogging is picking up very fast. In the yesteryears we used to say that anyone who is somebody in the industry should have a Web site; Today companies look at Blogs as a must have strategic tool, and budgets the same in their marketing plans.

The blog can indeed be fabulous for relationships, but it also exposes companies that fail to deliver its promises; Poor service or product delivery will be visible to all in a matter of days if not in minutes. Companies over the past few centuries have gotten used to shaping their message. Now they’re losing control of it.

Professional PR agencies have emerged worldwide to provide services to businesses to manage criticism and to create a positive impact on their target audiences.

Blogs evolve with every posting, each one tied to a moment. So if a company can track millions of blogs simultaneously, it gets a heat map of what a growing part of the world is thinking about, minute by minute. E-mail has carried on billions of conversations over the past decade. But those exchanges were private. Most blogs are open to the world. As the bloggers read each other, comment, and link from one page to the next, they create a global conversation.

Why does this matter? Think of the implications for businesses of getting an up-to-the-minute read on what the world is thinking. Already, studios are using blogs to see which movies are generating buzz. Advertisers are tracking responses to their campaigns. “I’m amazed people don’t get it yet,” says Jeff Weiner, Yahoo’s senior vice-president who heads up search. “Never in the history of market research has there been a tool like this.”

The innovation that sends blogs zinging into the mainstream is RSS, or Really Simple Syndication. It offers an easy-to-use system to turn blogs, or even specific postings, into Web feeds. With this system, a user could subscribe to certain blogs, or to key words, and then have all the relevant items land at a single destination. These personalized Web pages bring together the music and video the user signs up for, in addition to news. They’re called “aggregators.” For now, only about 5% of Internet users have set them up. But that number’s sure to rise as Yahoo and Microsoft plug them.

In time, aggregators could turn the Web on its head. Why? They discourage surfing as users increasingly just wait for interesting items to drop onto their page or e-mailbox. Internet advertising, which traditionally counts on page views and clicks, could be thrown for a loop. Already Yahoo is packaging ads on the feeds. Google is testing the waters.

There are product or Subject Specific Blogging like ITVidya.com which is targeted at IT professionals and IT Entrepreneurs. Academic Blogs are created by universities or students belonging to a batch or class. There are also blogs for researchers and students that can allow different colleges or universities to collaborate through Blogs on a global platform. You can setup your own personal blog like www.ashokchandran.com or have your Blog on a community site like ashokchandran.itvidya.com

The popular sites that offer free blogging platform includes Rediffblogs.com, Blogger.com (Google site), itvidya.com, O3.indiatimes.com, 360.yahoo.com and spaces.msn.com

There are Blog-specific search engines like Blogsearch.google.com, Technorati or Feedster. For those who want to go deeper, firms like Intelliseek and BuzzMetrics use sophisticated software to analyze the blog universe for corporate clients. Blogstreet.com goes a step forward by not only providing profiling and search services but also an RSS Ecosystem.

Among the popular tools for serious blogging Movable Type and Word Press are the two interesting ones. These tools allow you to setup your own Blog like www.ashokchandran.com and host it on the Internet. Most of the good Internet hosting companies offer the Blogging option in their hosting plans, this is easy to use as you do not have to worry of setting up the tool yourself.

Like any creative art like Photography it is finally not the equipment but what you put into it that will make your Blog tick.

Benefits of Blogging:

- Flexible and easy content management tool unlike general web-sites.
- Personal self expression and Personal Brand buildiing.
- Marketing medium for corporates.
- Well organized/categorized content with regular updations.
- Possibility of integrated Photo Blogging.
- Simple user interface and easy to use without any technical intervention for content management and updations.
- Information threads and collaborative discussions can be done.
- Impersonal feedback and opinion sharing with anyone unlike direct or email based personal feedbacks.
- Strategic tool for Knowledge Management, Collaborative development efforts, e-Learning, News Publishiing, Idea generation and sharing, Project planning, Product FAQ or help desk.etc. The list is endless and businesses and

individuals can innovatively and effectively use Blogs for their benefit.

Welcome to Blogging. Setup your own Blog, Be a part of Blog communities, Publish your thoughts anytime, anywhere through the net; Unleash your full self expression.

Ashok Chandran can be reached on his blog www.ashokchandran.com or Email ashok@ac.co.in

President A P J Abdul Kalam addressed the plenary session of ‘Nasscom 2006: India Leadership Forum’ in Mumbai. He spoke to a packed house on his vision of India’s future.

“The present projection of Nasscom is $60 billion by 2010 and I am here to discuss how to make it $200 billion,” the President said communicating the purpose of his visit.

He said that India should aspire for a $200 billion revenue IT industry by 2010 and grab a lion’s share of today’s $300 billion global offshoring market. The potential exists, but we need to ignite this potential within to convert it into reality.

‘‘The Nasscom - McKinsey Report 2005 indicates that the addressable market for global offshoring including BPO is around $300 billion presently, whereas we are only tapping 10 per cent of this addressable market,’’ Kalam said at the concluding day of the Nasscom Leadership Summit, 2006.

From Nasscom’s current projections, the country is expected to reach a target of $60 billion by 2010. To achieve the President’s target, India will need to expand the overall IT and offshoring market to $400 billion and do business with roughly 50 per cent of this slice.

He also mentioned that the key is to have an ‘I can do IT’ attitude’ to really achieve the target.
He mentioned that if each member in this forum at Nasscom promises that he will increase the productivity of his organization by 20% that itself can create a miraculous result. If we commit ourself to the goal and work towards the same, all barriers will automatically disappear.
Kalam urged Nasscom to convert the addressable market of IT and ITeS into an actual market.

The small and medium sized businesses contribute a major chunk to the revenues of the IT Industry and it is the the Government and Nasscom’s duty to support these entrepreneurs and businesses especially in areas of Marketing globally.

“Apart from partnering with International players and Large Indian corporates, Nasscom should also invite and support small enterprises, who are facing problem of marketing their products,” he said.

The President also urged the industry to be a part of the World Knowledge Platform with joint partnerships and invest in R&D and knowledge products that will earn more revenue.

The World Knowledge Platform will work for development of biotech and nanotechnology to build a safe and prosperous world.

“There is a need to develop products for the underprivileged and the mass market. I would like to see tablet PCs at a cost of about $100-150 so that a large majority of children even in the rural villages can replace their heavy textbooks with tablet PC’s” said the President.

Business process outsourcing services should be extended to Tier-II cities, he said, suggesting joint ventures with countries like Philippines and Korea in Asia for partnering in an information technology knowledge grid.

Underscoring the need for a level playing field for small and medium enterprises in IT sectors, Kalam asked Nasscom to come forward for the same.
Suggesting setting up of village knowledge centres on the lines of Kisan Call Centres, he asked the industry to address people in rural areas through IT in different domains like travel and tourism, health care, banking and insurance.
The Indian IT and BPO sector account for just 3.5% of the total global market, this has to be raised to 15%, said the President.

Turning the attention on the GramIT project, the President said, the Byrajupura project which has been able to provide connectivity to 116 villages is an excellent example of how villages can be made knowledge centers. He requested the industry to study this successful model and help in replicating the success.

Kalam said that India’s cost competitiveness in software products must aim for quality and just-in-time delivery going forward. ‘‘Since there are a number of countries competing for the $300 billion target, we continuously have to aim high,’’ he said.

Laying out a six-pronged approach for the offshoring and IT business, the President said that Nasscom and the government must assist small enterprises in software by setting up consortiums and undertake major drives to build capacity in graduates working for the ITES and BPO sectors.

He said Indian industry must focus on the Asia Pacific, ASEAN and African countries to become more productive. Besides, he added that Indian IT companies cannot afford to ignore the 1 billion-strong domestic IT market any longer.

‘‘It is the responsibility of the Government, Nasscom and the Indian industries to enable a level-playing-field for the smaller players,’’ Kalam said.

He also said that India’s existing policy objectives for Africa should map on to its IT goals so as to establish a ‘‘Pan-African e-Network that connects 53 countries for providing tele-education, tele-medicine and connecting the Heads of State.’’

Our dream is India leading the technology revolution; the smallest village linked to the world and providing opportunities for every child to reach their potential. He wants India’s BPO industry to promote the ‘tier two’ cities to spread the wealth and lessen the strain on the major ‘traditional BPO’ cities (Bangalore, Delhi, Mumbai, Chennai, Hyderabad primarily), and he wants India to lead the R&D activity into new technological products, and to drive the ‘knowledge networks’ across the rest of Asia and the Far East.

Target $200 bn revenues: Some pointers to achieve $200 billion revenues by 2010.

• Invest in innovation IT.
• Form an ICT market for Asia, Africa and ASEAN nations.
• Focus on India and on products for the Indian and Asian markets.
• Indian’s pan-African e-network has a tremendous potential; take part in the venture with 53 nations in various aspects of technology.
• Be Competitive and aim high.
• Support the SME segment in their Marketing activities.
• Set up village knowledge centres.
• Convert the addressable market into an actual market.
• Expand BPO and IT activities in big towns to tier-two cities with a population of 1 million.
• Engage more partner nations like the Philippines and Singapore.
• Support projects in e-governance, Rural Projects etc.
• Ensure level playing field for SMEs and help them market their products.
• Develop domain services on the lines of Kisan centres that help farmers to use IT.

This was a very powerful presentation, impressively detailed and with an inspiring Vision. It was provocative and more thought provoking than anything else discussed in the 3 day international level conference. It was not only about financial targets but the impact of technology on the entire nation that was touching. Finally Mr. Kalam summarized his message for the benefit of the delegates by saying that “the summary is nothing else but $ 200 Billion.”

Stress is here to stay. No matter what anyone says. So here are a few effective and efficient ways to deal with this ‘reality’. And while reading the tips just try this out: Read according to the alphabet in your name and you will be surprised to see that advise you get is just the one you need !!!

(eg. for VINAY it is =
Verify information from the source before exploding.
Identify stressors and plan to deal with them better next time.
No is a word you need to learn to use without feeling guilty.
Always take time for yourself, at least 30 minutes per day.
Yearly goal setting: Plan what you want to achieve based on your priorities in your career, relationships, etc.)

A to Z of stress management:

Always take time for yourself, at least 30 minutes per day.
Be aware of your own stress meter: Know when to step back and cool down.
Concentrate on controlling your own situation, without controlling everybody else.
Daily exercise will burn off the stress chemicals.
Eat lots of fresh fruit, veggies, bread and water, give your body the best for it to perform at its best.
Forgive others, don’t hold grudges and be tolerant — not everyone is as capable as you.
Gain perspective on things, how important is the issue?
Hugs, kisses and laughter: Have fun and don’t be afraid to share your feelings with others.
Identify stressors and plan to deal with them better next time.
Judge your own performance realistically; don’t set goals out of your own reach.
Keep a positive attitude, your outlook will influence outcomes and the way others treat you.
Limit alcohol, drugs and other stimulants, they affect your perception and behaviour.
Manage money well, seek advice and save at least 10 per cent of what you earn.
No is a word you need to learn to use without feeling guilty.
Outdoor activities by yourself, or with friends and family, can be a great way to relax.
Play your favourite music rather than watching television.
Quit smoking: It is stressing your body daily, not to mention killing you too.
Relationships: Nurture and enjoy them, learn to listen more and talk less.
Sleep well, with a firm mattress and a supportive pillow; don’t overheat yourself and allow plenty of ventilation.
Treat yourself once a week with a massage, dinner out, the movies: Moderation is the key.
Understand things from the other person’s point of view.
Verify information from the source before exploding.
Worry less, it really does not get things completed better or quicker.
Xpress: Make a regular retreat to your favourite space, make holidays part of your yearly plan and budget.
Yearly goal setting: Plan what you want to achieve based on your priorities in your career, relationships, etc.
Zest for life: Each day is a gift, smile and be thankful that you are a part of the bigger picture.

Introduction

The architect of Nuclear Science inModern India. His far sightedness, powers of organization, and the encouragement and guidance young scientists received from him these built up an invaluable asset for scientific work in India.He was a painter and worshipped the beauty of Nature. Science and art both enriched his mind and life. He was the ideal personality India needs today.
Author - K.C.Shivappa

Homi Bhabha

Homi Bhabha is one of the pioneers in the field of science in modern India. His role in the history of science in free India is of great significance. He is the architect of nuclear science in India.

The Boy-Scientist

Homi Jehangir Bhabha was born in Bombay on October 30, 1909. His father Jehangir Bhabha, once a student of Oxford University, was a reputed advocate and served the Tata Enterprises. Meheran, Bhabha’s mother, belonged to the petit family. His grandfather was an officer in the Education Department of Mysore State. (Now it is Karnataka)

In his childhood Bhabha used to sleep very little. The worried parents took him to several qualified doctors. But forsometime the reason for his sleeplessness could not be found out. At last doctors assured the parents that Bhabha was in excellent health. He did not sleep as long as other children of his age, because of his super- active brain and the continuous, rapid flow of thoughts.

His parents took interest in shaping Bhabha’s love of science. He was also provided with a small library. The library contained many science books. Bhabha made full use of his library. Books became his friends. Thus a good foundation was laid for his scientific career. Einstein (1879-1955) is one of the greatest scientists of this century. It is difficult to understand his Theory of Relativity. But, at the age of 15, Bhabha was able to read Einstein’s book on Relativity. He could also digest the contents to some extent.

Even as a boy Bhabha was a lover of Nature. He was deeply interested in painting, music and literature. He took full advantage of his good collection of books and records. But he was not much interested in sports.
Education and Research

Bhabha was educated at the Cathedral and John Cannon High School. He was a merit student. He won many prizes at school.

At the age of 15, Bhabha passed the Senior Cambridge Examination.

Later he entered Elphinstone College and the Royal Institute of Science, Bombay. He continued his studies here for two years.

Bhabha loved Physics. Mathematics was also his favorite subject. But his father wanted him to become an engineer. Bhabha respected the wishes of his father. He left India for Cambridge to study Engineering. Bhabha passed the Mechanical Engineering Tripos in the first class in 1930. He then pursued his studies in Theoretical Physics as a Research Scholar.
Devotion to Fine arts

Bhabha was not a mere bookworm. He had secured many scholarships. He had an inborn taste and a creative urge. During his stay in England and Europe, painting became his hobby. He visited many art galleries, museums, palaces and gardens. He never missed a good musical concert. Many of his paintings now grace the walls of art galleries in England. Devotion to art and the study of science went hand in hand in Bhabha’s life.
Research Pursued

Bhabha was awarded the Rouse Ball Travelling Studentship for two years in 1932. He worked with W. Pouli in Zurich and Enrico Fermi in Rome. During this period he was awarded the Isaac Newton Fellowship in 1934 and the1851-Exhibition Studentship in 1936.

Bhabha was fortunate to come into close contact with famous scientists like Rutherford, Dirac, Niels Bohr and Heitler. This association greatly influenced his research and way of life.

The Study of Cosmic Rays

Bhabha presented, with Heitler, the ‘Cascade Theory of Electron Showers’, in 1937. It is called the ‘Bhabha-Heitler Cascade Theory’. It is a uniquecontribution to the world of Physics. This research brought fame to Bhabha. This theory explains the process of electron showers in cosmic rays.

Cosmic rays are primary rays, which are fast moving and sub-microscopic particles.They comprise protons,electrons and gamma rays. When some of them happen to approach the earth and enter its atmosphere, they collide with atoms in the air. They then breed new nuclear particles. Bhabha’s new theory explains clearly the processes and effects of the mutual reaction. It throws light on one of the most puzzling mysteries of cosmic rays.

Bhabha recognized heavy electron particles in cosmic rays and called them ‘Meson’. Bhabha’s mastery ofmathematics can be seen in the ‘Classical Theory of Spinning Particles’. The importance of his work received wide recognition.

Bhabha’s orginal contributions to Physics lie in the fields of cosmic radiation, theory of elementary particles and quantum theory.

Bhabha returned to India for a holiday in 1939. That was the time of the Second World War. Bhabha did not return to England and this was indeed fortunate for India.

In Bangalore

Bhabha could have got lucrative posts in any developed country. But he did not think of them. The material pleasures of foreign countries did not attract him. Bhabha decided to devote his life to the service of his motherland.

In 1940 Bhabha joined the Indian Institute of Science as Reader in Theoretical Physics. He shouldered the responsibility of building a new department to undertake research on cosmic rays. In 1941 he was elected a member of the Royal Society. When this great distinction was conferred on Bhabha, he was just 31 years old. Not many have been so honored at such a young age by the Royal Society.

Bhabha became a Professor in theInstitute in 1942. The University of Cambridge also awarded the Adams Prize to him.

The young Bhabha dreamt of the ‘great adventure’ of building a modern India. In the salubrious climate of Bangalore he studied the background of the great culture of India. He analyzed the socio- economic problems of the country. He was quite convinced that science was the only means for the progress of India.

Bhabha’s love of classical music, dance and sculpture deepened. This keen interest made him worship art throughout his life. It also influenced the pattern of his life.

Bhabha had just come to Bangalore. He was asked to deliver a lecture. C. V. Raman presided over the program. The subject of the lecture related to modern physics. The audience who heard the lecture was amazed at his scholarship. In his speech as the Chairman, Raman said: “The lecture was a treat for three persons - the lecturer, the Chairman and one other noted mathematician present here.”
Far-sighted

In those days the equipment and facilities needed for research in Atomic Physics were not available in India. Realizing this, Bhabha formulated a plan to meet this need.

Bhabha was invited to join the staff of Oxford University. But he did not accept the invitation. He expressed his desire to build an excellent institution of research in India.

Bhabha wrote a letter to the Dorabji Tata Trust on March 13, 1944. In the course of the letter he said:

‘When nuclear energy has been success- fully applied to power production in, say, a couple of decades from now, India will not have to look abroad for its experts, but will find them ready at hand.’

Bhabha wrote this letter almost a year before the atom bombs fell on Hiroshima and Nagasaki! This letter clearly illustrates his far-sightedness and patriotism. Bhabha’s plan was an embryo from which a school of physics was born.
A New Climate Created

The Tata Trust founded the - ‘Tata Institute of Fundamental Research’ in 1945. The establishment of the Institute was mainly due to the initiative of Bhabha. The Bombay government and the Government of India gave financial support to the Institute. Bhabha was appointed its first Director, and he assumed theresponsibility of shaping the Institute. India thus took the first step on the journey of nuclearscience.

The Institute first commenced its work in the rented premises at Peddar Road. Later it moved to the extension at the Yatch Club.It is now situated in abeautifully proportioned building.

Research work in pure mathematics, th6oretical and applied physics, computer technology and geophysics was under- taken at the Institute. The study of the principles of atomic explosion, the production of isotopes and the purification of uranium formed part of the work of the Institute. Thus Bhabha created an intellectual environment in India. He was successful in practicing what he had learnt at Cambridge and Paris.

The Tata Institute of Fundamental Research is an outcome of the discussion that Bhabha had with the industrialist J. R. D. Tata, and the far-sighted decision of the Tata Trust to support Bhabha’s Project. The hills of Trombay have today blossomed into a fine research complex. The Institute is one of the world’s top research centers in nuclear research. It enjoys a great reputation and can be compared with any research institute in developed countries. Thanks to the guidance and tireless efforts of Homi Bhabha the Institute is indeed a symbol of scientific tradition in India. It is Bhabha’s contribution to the country’s advancement of science and technology.
Towards Deeper Study of Atomic Energy

India got independence on August 15, 1947. Eleven days later, on August 26, 1947, Bhabha addressed the Atomic Energy Research Committee as follows:

“We meet today at the beginning of a new chapter in our history. We have great hopes that this new chapter will be a glorious one. The development and use of atomic energy is a question of national importance. We hope to establish soon an Atomic Research Center comparable with those in the most advanced countries.”

A year later, the Atomic Energy Commission was formed. Bhabha was appointed Chairman of the Commission.

The major responsibilities of the Com- mission were: a survey of Indian soil for the materials required for nuclearresearch, the construction of atomic reactors, the purification of atomic materials, conducting fundamental research and the formulation of training program.

The Commission utilized the services of scientists at the Tata Institute of Fundamental Research. The scope of the work of the Commission was enlarged. The Atomic Energy programme took a concrete shape. The Department of Atomic Energy thus came into existence as a separate department of the Government of India in 1954, under the direct control of Prime Minister Nehru. Bhabha became the Ex-officio Secretary of the Department.

Shortly after the formation of the Department of Atomic Energy, it was decided to create the Atomic Energy Establishment for application of atomic energy to peaceful purposes. Bhabha became its first Director. The Establish- ment was formally inaugurated by Jawaharlal Nehru on January 20,1957.

Thus India began to win new laurels for the study of atomic energy. Bhabha worked ceaselessly and enriched the sphere of science in the country. Through out his directorship, he emphasized indigenous know-how to make the country self-reliant in the nuclear field.

J. R. D. Tata and Jawaharlal Nehru gave support and encouragement to Bhabha in his work. Pandit Nehru very much appreciated the efficiency, farsightedness and patriotism of Bhabha. Bhabha was very close to Nehru and enjoyed his confidence. As a result, Bhabha got considerable freedom to carry on his work with ease and efficiency. Bhabha framed administrative rules to suit the tempo, of scientific activity. He helped to get rid of lethargy and red-tapism which were obstacles to the progress of science. One of Bhabha’s achievements was that he persuaded the Government to take greater interest in technology.
Reactors

It is a meeting of men and circumstances that sometimes stimulates progress. It is therefore providential that Nehru had Bhabha and Bhabha had Nehru. As a close personal friend and devoted follower of the Prime Minister. Bhabha shared the great man’s dreams, ambitions and points of view.

Bhabha was participating in a conference at Geneva in 1955. Canada came forward to build a Reactor in India. On August 29,1955, Bhabha sent a cable from Geneva to Nehru and requested him to approve the, acceptance of this offer. Within three days, Bhabha received the consent of the Prime Minister. The Canada-India Reactor ‘Cirus’ was born.

‘Apsara’, ‘Cirus’ and ‘Zerlina’ are the three reactors built by the Trombay scientists and engineers, with foreign assistance. The credit for establishing these reactors goes to Bhabha.

‘Apsara’, India’s first reactor was taken up in 1955 to fulfil the needs in the fields of neutron physics, radiation, chemistry and biology and also the production of radio isotopes. It became 6critical’ on August 4, 1956. The uranium fuel for the reactor was obtained from the United, Kingdom. The erection of ‘Apsara’ gave self- confidence to the Indian scientists and engineers.

‘Cirus’ was built in 1960 -and ‘Zerlina’ in 1961. The construction of ‘Cirus’ took some four years, and 1200 engineers and skilled artisans worked for the completion of the reactor.

Having acquired these reactors, Bhabha planned to take up the actual construction of atomic power plants. The atomic power plant of Tarapur in Maharashtra is now producing electricity. The other two plants are situated at Rana Pratap Sagar in Rajasthan and Kalpakam in Tamil Nadu. These power plants will appreciably contribute to the production of electricity in India. These achievements are the living symbols of Bhabha’s imagination and dynamism.

It has now been possible to produce plutonium, a valuable nuclear material, and other useful fuel at Tomboy. Work on thorium is also in progress. India has the largest reserves of thorium in the world. Thorium is a promising material for India’s nuclear power program. More than 250 radioisotopes used in agriculture, industry, medicine and biology are now made available in large quantities. Today, over 350 radioisotopes and other radioisotope products are produced to meet a countrywide demand and also for export purposes. Radioisotopes play an important role in the study of the functions of a normal human body.
The Trombay Institute

Bhabha worked very hard for the development of Trombay Institute. His time and energy were entirely
devoted to the Institute. Reactors like Apsara, uranium and zirconium plants, the Van de Graff and
cyclotron equipment - all are the gifts of Dr. Bhabha. Top priority is given to research relating to the
application of radiation to preserve perishable food and protect it from the attacks of parasites. This work has made it possible topreserve fish, fruits, vegetables and other edible products for a long
time. The process of curing seeds for better yields is also being studied. A seismic array station has been set up at Gauribidnur, about 80 kilometers from Bangalore, to detect earthquakes and
underground nuclear explosions.
Atomic Energy the Only Foundation

The consumption of energy in the world is on the increase. Naturally available resources of energy like coal and oil are on the decrease. Added to this, there is shortage of hydel energy in certain places. Realizing this, Bhabha declared that atomic energy is the only foundation for the progress of industries in India. He suggested that producing electricity could effect economy by nuclear methods.

Electronic instrumentation is required in all spheres of atomic energy work. Bhabha prepared blueprints for various projects relating to electronic instruments. Nuclear instruments worth a few millions are fabricated at Trombay every year. At present Trombay turns out over 2,000 electronic instruments annually. They include radiation survey meters, amplifiers and spectrometers.

The Electronic Corporation of India also manufactures many electronic instruments. All this has been possible because of the far-sightedness of Bhabha.
Assistance to Centers

Bhabha gave generous assistance to a number of centers of science. The Saha Atomic Research Center (Calcutta), the Physical Research Laboratory (Ahmedabad) and other laboratories got assistance from the Department of Atomic Energy. The Tumba Rocket Launching Station of Kerala, the High Altitude Research Center of Kashmir, the Uranium Mine of Bihar and the Heavy Water Plant of Nungal are also the under takings of the Atomic Energy Establishment. Bhabha gave necessary attention to the advancement of fundamental science. He had close contact with the universities and research laboratories in India and abroad. He offered facilities, like scholarships, grants and equipment to institutions, which needed them. He thus promoted the cause of research in basic science.
Building Up A Team of Scientists

The early atomic age of India was a period of transition. At that time Bhabha gave a clarion call to all young scientists who were staying abroad; “Return to Trombay; return to the motherland.” Many young scientists listened to his call and came to Trombay.

They are today among the reputed scientists in the country. Bhabha took personal care to provide necessary amenities to them.

Bhabha selected scientists with care. He placed them in positions of responsibility. He thus succeeded in building up a team of excellent workers around him. He created a suitable scientific atmosphere for his colleagues. Necessary materials and equipment were provided. He inspired the staff and gave them the freedom they needed to pursue their work. He gave them every opportunity to grow. Spotting scientific talent was his passion.

Discipline in all walks of life and a challenging attitude to accomplish the targets were his special characteristics. He instilled a sense of confidence in his fellow-workers so that project could be successfully completed.
His Contribution

On May 18, 1974, India conducted its first nuclear explosion for peaceful purposes, at Pokran in, Rajasthan and joined the galaxy of nations with atomic energy. It thus became the world’s sixth nuclear power. The other five countries with the nuclear know-how are America, Russia, Britain, France and China. India’sexplosion of a nuclear device is a great milestone in the path of technological progress. This achievement was based entirely on Indian effort. The success of this achievement is due mainly to Bhabha who put India on the world map of nuclear science.
Honours

Bhabha was a recipient of many honors. He was awarded honorary doctorates by several Indian and foreign universities. Among these universities are London, Cambridge, Padova, Perth, Banaras, Agra, Patna, Lucknow, Allahabad, Andhra and Aligarh. In 1948 he received the Hopkins Prize of the Cambridge Philosophical Society. He was elected the President of the Indian Science Congress in 1951. In 1954 the President of India gave him the Padma Bhushan award for his outstanding contribution to nuclear science. In 1963 he was elected as the President of the National Institute of Sciences of India. He was an honorary fellow of many earned institutions. Laurels came to Bhabha from all corners of the world throughout his lifetime.

Bhabha was a member of many scientific advisory committees of the United Nations and the International Atomic Energy Agency. He also served as the Chairman of the Scientific Advisory Committee to advise the Government of India. In 1955 Bhabha was elected as the President of the first International Conference on the ‘Peaceful Uses of Atomic Energy’, organized by the United Nations atGeneva. The conference was another step in international cooperation. Bhabha was the first to advocate, from international forums, the peaceful uses of atomic energy.
A Many-Faceted Personality

Bhabha was not confined to the four walls of his laboratory. He was a lover of art and a good friend of his colleagues.

He made friends, he kept his friends and he made new friends. He was a tender hearted man. He helped many persons who were. in distress. He commanded the loyalty of his colleagues. His was a voice, which never expressed bitterness.
The Road to Excellence

Two outstanding virtues of Bhabha’s work were his insistence on excellence and his faith in self-reliance. He showed to the world that Indian scientists could reach great heights. He was a practical person. He believed in planning and in executing the plans.

Bhabha liked persons who were active and dynamic. If any one had made mistakes in the course of his work, he had the generosity to forgive the lapses. But he disliked carelessness, laziness and indifference. He tolerated honestmistakes, but not stupidity. He had always a good word for good work. He was human to the tips of his fingers and always concerned to help in solving the personal problems of others.

Bhabha started a training center to train young scientists in different fields of nuclear science. He invited talented young men and women from all parts of the country and arranged for special instruction. He brought together many famous scientists on the same platform and arranged lectures. He toiled much to bring to light the latent talents of the young scientists in India.

Not only did Bhabha arouse in Indians awareness for the need to study and apply science, but also inspired the young men to do their work with confidence. He encouraged them to be industrious. Thus, Bhabha was responsible for creating a band of efficient workers. This indeed is a great asset that Bhabha has left for us.

His duty was Bhabha’s first love. It was more pronounced in scientific research, planning and direction. When Bhabha was invited to become the Minister of Atomic Energy in the Union Cabinet, he declined. Science was dearer to Bhabha than the charm of ministership.

Bhabha’s ambitions were sky-high but he also worked tirelessly to realize them. He was not a scientist who sat in an ivory tower. He was a man of action. He was a rare blending of idealism and realism.

The future is often misty but Bhabha, an untiring worker had a clear vision. He had always an open mind on every issue. He respected the views of others.
Life is for Living

Bhabha was a bachelor. When once asked about his marriage, he said: “I am married to creativity.”

In 1938 Bhabha wrote in one of his letters: ‘You can give a new direction to everything in life-except death.’ These words show clearly the degree of his self-confidence.

Bhabha believed that life was worth living and that one should get out of it that entire one can. He sought to understand the true values of life. He thought that art, literature and music enhanced the beauty of life.
Scientist - Artist - Leader

Bhabha often said: “A scientist does not belong to a particular nation. He belongs to the whole world. The doors of science should be kept open to all those who work for the welfare of humanity.”

Bhabha foresaw that a time might come when production of power may suffer because of the shortage of coal and oil. He firmly believed that the standard of living of our people could be improved only through fuller utilization of nuclear energy.

Bhabha possessed a rare combination of a b reliant mind, a tremendous capacity for organization and boundless energy. Indians will always remember him as a great scientist, a remarkable administrator and an outstanding leader, He had a feel for creative work. He had the scientist’s precision with the artist’s exuberance.

Bhabha opened up new vistas of atomic glory. Nuclear Physics attained a new dignity and a new status on account of his personality. India stepped right out of the bullock-cart age into the Atomic age. This ‘Atom Man’ diverted the atom from the path of destruction to that of construction.
Bridging two Cultures

Bhabha was proud but charming; thought ful but gay. He was soft-spoken and well dressed. He believed in gracious living and loved things, which were beautiful and aesthetic. His interest spread beyond science to culture and art. He had an eye for detail; nothing escaped his penetrating eyes.

Bhabha did not want any friction between scientific culture and artistic Culture. He always tried to bridge the gap between these two cultures. He believed that both science and art should enrich human life. These thoughts made Bhabha a great humanist of his age.

Bhabha could have become a great musician or expert artist or a renowned writer, but he served the nation as a scientist. What is science for if not for research, truth and beauty?

Bhabha was a great patron of art and music. He once dreamt of a career as a composer. He gave encouragement to modern painters, purchased their works and displayed them on the walls of the buildings of Trombay Establishment. He was a lover of South Indian music and never missed any good performance of leading artists. A man of many talents, he had a wonderful collection of paintings. He was also a great collector of works of art. He could talk with authority on painting and music and on trees and plants and flowers, which he loved. He was a versatile genius.

He had a great love for trees and flowers. At his instance a number of trees were transplanted to the new premises of the Tata Institute. He saved many a tree from the clutches of death. He was indeed a ‘Friend of Trees.’

When the construction work at Trombay was in progress, Bhabha spent many sleepless nights and finalized the layout for the campus. Today it is a home of loveliness, with vast lawns, shady trees and multi-colored flowers. The Trombay Center faces the sea on one side and a tall hill on the other. Nature is at her loveliest at Trombay. Trombay is undoubtedly a living example of Bhal5ha’s taste for good things and love of the beauty of Nature.
The Tragic End

Bhabha was going to attend an international conference. He was on a mission of peace. The Air India Boeing 707 ‘Kanchenjunga’ in which Bhabha was travelling, crashed in a snowstorm on January 24, 1966 at Mout Blanc. Bhabha thus met with a tragic end. He died comparatively young and at the height of his fame. It was a loss too deep for tears.

In the death of Dr. Bhabha India lost an eminent scientist and one of her great sons.

Bhabha had disliked the, practice of stopping work when some one passed away. He considered that the best homage was hard work. When the members of the staff at Trombay heard the news of Dr. Bhabha’s death, they worked as usual and thus paid their respect to their departed leader.

As a tribute to Dr. Bhabha, the Atomic Energy Establishment, Trombay, was renamed as the Bhabha Atomic Research Center, on January 12, 1967.

The progress of mankind is based on the talents and achievements of a few extraordinary individuals. Bhabha was one such a great man. Birth and death are laws of Nature. But life finds a new meaning in the great accomplishments and achievements of man. Bhabha was in many ways a complete man’.

“Here was a great man.

When comes such another?”

Introduction

One of the greatest scientists of India. As Chairman of the Atomic Energy Commission, he guided research of the greatest importance to the country. A born scientist and a beloved teacher.
Author - P.S.V.Shetty

Vikram Ambalal Sarabhai

When a great man dies, the first question people ask is: “After him, who?”Generally, this question is soon answered. But, sometimes, it remains without a answer for a longer time because it may be difficult to find another person of such abilities as the dead man. This shows how great the dead man was.

Homi Jahangir Bhabha was one such man. He was a world-famous physicist. He was the Chairman of the Indian Atomic Energy Commission. Several countries in the world were making atom bombs. Should India also do so? When this question came up, some people said, “It costs a lot of money to make an atom bomb. India is a poor country and if she spends such huge amounts, she will be in great trouble for money.” At such a time Bhabha calculated the cost of making an atom bomb and showed it would not be too expensive and India could produce it. This great scientist died an untimely death in an airplane crash in 1966. Then “Who, after him?” -this became a big question. Who could replace such a great physicist?

Four months later, every one’s answer was: “Vikram Ambalal Sarabhai.”

Thus, in 1966, Vikram Sarabhai succeeded Dr. Bhabha as the Chairman of the Atomic Energy Commission.

What A Guru!

“He’s coming; tell him.”

“I didn’t damage it. You tell him yourself.”

“No, I can’t. You tell him. I am afraid. ”

Two persons were engaged in this conversation. Just then Vikram Sarabhai came to them. “What is the matter?” he asked.

“The Electric Meter has gone out of order, Sir. We allowed too heavy a current to pass through it.” “Is that all? Don’t mind it too much. Such things do happen when students are learning. If students don’t make mistakes, how can they learn? It is enough if you learn to be more careful in future.”

The above dialogue took place in a small research laboratory in Ahmedabad in1948. R. P. Kane and another student were conducting some experiments in the Mahatma Gandhi Science Institute, in the - physics laboratory. ‘During an experiment, because of the heavy current, the meter was burnt. At that time, it was very difficult to get such meters in the market. For want of one meter, many important experiments had to be suspended for months. Vikram Ambalal Sarabhai had started this laboratory in a very recent time. So the students were afraid of what Vikram Sarabhai would say when he would come to know of what had happened. That is why the two were discussing the matter. But, when Sarabhai was told about it, let alone becoming angry, he did not even show a trace of irritation or annoyance in his f ace. Instead, he spoke to them comfortingly.

Praful D. Bhavsar had taken his B.Sc. (Bachelor of Science) Degree. In 1948, he went to Poona to study for the Master of Science Degree. He could not secure admission to any college there. Then, Dr. L. A. Ramdas (of the India Meteorological Department at Poona) told him of the Physical Research Laboratory that Vikram Sarabhai had recently started at Ahmedabad. He told Bhavsar that if he met Vikram Sarabhai his problem would be solved. Bhavsar went to see Sarabhai.

By that time Sarabhai was in a small room, engaged in, blowing a piece of glass tube. He was wearing white Khaddar trousers and a bright green coat. Vikram welcomed Bhavsar with a smile and requested him to wait till his work to be completed. He appeared very simple and free from vanity. Bhavsar had his own mental picture of a great experimental physicist. That picture seemed to have come to life in Sarabhai. Therefore, Bhavsar was ready at that very moment to accept Sarabhai as his Guru (teacher). Sarabhai put him many questions. After finding out why he wanted to study physics, how keen his interest in the subject was and such other details, he admitted him to the Laboratory.

These incidents show how powerfully Vikram Sarabhai influenced his students.

After India became free, Vikram Ambalal Sarabhai was among the few scientists who devoted their entire life to the progress of science in this country.
Early Education

Ahmedabad is the capital of Gujarat. It has a large number of textile mills. The Sarabhais are famous industrialists

and social workers of that city. They are also very rich. In this family was born Vikram on 12th August 1919. It was the Garuda Panchami Day, auspicious for sisters and brothers. His father was Ambalal and his mother, Sarala Devi. They had eight children.

When their first daughter, Mridulaben, was just three years old, they considered how and where she should be educated. No existing school was found suitable. Just at that time, the Montessori System of Education was gaining fame. But there was still no school, which had adopted this system. So the Sarabhais started such a school in their own house. As the children grew up, the needs of the school also increased. In this school, there were separate teachers to teach languages, the sciences, the arts, gardening, technology etc. There were laboratories and work shops also. At one time, there were thirteen teachers in the school for the eight children of the Sarabhai family. Of these, three were Ph.Ds, trained in Europe and three ordinary graduate’s two teachers from Andhra and Bengal were teaching the arts. Gurudev Rabindranath Tagore him- self selected an artiste to teach dancing. The children studied in this school up to matriculation and went to government schools for their Matriculation Examination.

Vikram was influenced not only by the school but also by many great men of the land who were well-known to the Sarabhai family. Gurudev Rabindranath, J. Krishna Murthi, Motilal Nehru, V. S. Shrinivasa Shastri, Jawaharlal Nehru, Sarojini Naidu, Maulana Azad, C. F. Andrews, C. V. Raman and such great men used to stay with the Sarabhai family when they visited Ahmedabad. The greatest of them all, Mahatma Gandhi him, stayed in their house while recovering from an illness. There is no doubt that this close contact with such great men deeply influenced young Vikram. His intelligence developed, and he gained interest in spiritual matters. His teacher, Shri Badami, has said, I never saw Vikram lose his temper and shout at people.”

When Vikram was five or six years old, the entire family went to Simla for the summer. There, the little boy noticed that his father was getting many letters every day. He wished he, too, could get letters. So he took some envelopes from his father’s office, affixed stamps wrote his own address and posted them in the box. When his father found that Vikram was receiving letters every day, he asked the boy about the letters. Vikram laughingly replied, I am writing letters to myself!”

From his childhood, Vikram loved adventure. When he was eight, he learnt to ride a bicycle. He would astonish his people with many tricks with the bicycle. As the bicycle shot forward, he would raise his hands, stretch his legs forward, close his eyes and pedal. He would not listen to anyone who pleaded him not to perform such dangerous acrobatics.

There was a pool in their compound; there was also a boat. Vikram would take a servant and one or two children for boating. On one occasion, the boat capsized and every one fell into the water and began to shout for help. The gardeners working nearby heard their cries for help, jumped into the water and saved them.

Vikram showed greater earnestness and interest in his studies than the others. He was very enthusiastic about mathematics and science. His teachers have said he would work hard without leisure in the holidays and, when the school reopened, he would be far ahead of other students.

When Vikram was two years old, the poet Rabindranath Tagore visited the family. It appears that when he saw this little child, he predicted that he would become a famous man.

After completing his college education Vikram Sarabhai went to England to continue his studies at Cambridge University.

For centuries two universities in England have been very famous -Oxford University and Cambridge University. To get a degree from one of these universities is considered an honor. In 1939, when Vikram was only twenty, he passed the Tripos Examination in Physical Sciences.
With C. V. Raman and H. J. Bhabha

The Second World War broke out in 1939. Soon after, Vikram returned to India. Right from his boyhood, Vikram had great love for physics. During the forties, the most famous center for scientific research in India was the Indian Institute of science (the Tata Institute) at Bangalore. Its Physics Department was headed by the world-famous scientist, Dr. C. V. Raman. The highest award in science is the Nobel Prize. Dr. C. V. Raman was awarded this prize as early as in 1930. When Sarabhai returned to India, he came down to Bangalore to carry on research under Dr. C. V. Raman. The famous Dr. Homi Jahangir Bhabha was also at the institute by that time; he was engaged in research on Mesons and Cosmic Rays.
The Study of Cosmic Rays

What are mesons and cosmic rays? If we split any substance on the Earth we get only three fundamental particles - electrically charged negative particles (electrons), positive particles (protons) and neutral particles (neutrons). If the weight of the electron is taken as 1, then the weight of protons and neutrons is 1836. But it has been discovered that there are other types of particles besides these three in space. The weight of particles not belonging to these classes is different from the weights of electrons, protons or neutrons. These other particles are called mesons. Scientists who have done research on mesons are of the opinion that they are produced by cosmic rays. Cosmic rays are very fine and very powerful and come from somewhere outside the Earth. They race to the earth from al directions.

Every minute, day and night, about 600 such cosmic rays pass through the human body. They can pass through rocks hundreds of meters thick.

Vikram Sarabhai conducted research on the changes in the intensity of cosmic rays. His very first scientific paper was on the periodical variation of the intensity of cosmic rays’ It was published (1942) in Bangalore in a scientific journal. This research helped him later to take up the studies of interplanetary space (space between planets), the relationship between the sun and the earth and earthmagnetism.

During this period, he did research for sometime a, the Poona Central Meteorological Station. Here he got the idea of establishing a cosmic ray research institute. In 1943, he went to the Himalayan peaks in Kashmir to study the intensity of cosmic rays at such high places. There he conceived a brilliant idea. This was to establish a research center at a great height above the surface of the earth.

In 1945, the Second World War ended. Sarabhai again went to Cambridge to continue his study of cosmic rays. In 1947 he got his Ph.D. for this work.

A student does not get the Ph.D. Degree by passing an examination. He has to choose a professor to guide him. The professor suggests a subject for deep study and research. The student has to study the subject by himself under the professor’s guidance; he has to organize the information he gets from his experiments; he has to draw his own conclusions, and gather all these into a large scientific article or ‘thesis’. This thesis is then sent to four specialists in the subject. Only if they agree that the work and the thesis deserve a doctorate will the Ph.D. Degree be conferred on thestudent. It is, therefore, no easy task to secure a Ph.D. Degree. Although Sarabhai went to Cambridge in 1945, he had started his work for the Ph.D. Degree in 1942. His family used to go to Kashmir every summer. Vikram would carry his cosmic ray research equipment to Kashmir. Apharwat, on the banks of Lake Alpathari, is about 13,000 feet above sea level. It was here, that Sarabhai continued his research. In his Ph.D. thesis he included photographs of the equipment he used there.

Shortly after he returned from Cambridge he established the Physical Research Laboratory (mentioned earlier) at Ahmedabad. A scientist by name Dr. K. R. Ramanathan was appointed as its first Director in 1948. The Institute was started with only a few Students and Laboratory Assistants. In a few years this group developed into a dedicated team of scientists and research workers. In spite of his many duties in later years, Sarabhai maintained close contact with this Institute till his end. At first he was Professor of cosmic ray research; from 1965 he worked as the Director. This Institute sponsored a cosmic ray research center established in 1955 at Gulmarg, in Kashmir. The work done at this center attracted the notice of the Atomic Energy Department of the Government of India and won its appreciation. This Department established a full-fledged High Altitude Research Center at the same place -the only research center ‘ in the world to be set up at such a high altitude. At last, Sarabhai’s long dream became a reality. Later on, similar centers were opened at Kodaikanal in Tamilnadu and at Trivandrum in Kerala.

One thousand and two hundred years ago Adi Shankaracharya established four religious centers or Mutts at Shringeri, Puri, Dwaraka and Badrinath for the revival of Hindu Dharma and left his foot prints there. Vikram Sarabhai established centers for scientific research in several places from Kashmir to Kanyakumari and has left his footprints there.
Successor to Bhabha

Dr. Homi Bhabha, Chairman of the Atomic Energy Commission, died in 1966. He was a very capable man. Many thought no one in India could replace him. In this depressing atmosphere they found in Vikram Sarabhai the man to continue Bhabha’s work at the Atomic Energy Commission. He did his work quite ably and showed his capacity to direct and continue Successfully the work of the Commission.

On 29th December 1971, Sarabhai was in Trivandrum to guide the work at the, Rocket Launching Station, Thumba. He was staying in a hotel there. He talked with every one as usual and went to bed. He never got up again. The man who at birth was blessed by Lakshmi, the Goddess of Wealth, but who worshipped Saraswathi, the Goddess of Learning, died when he was busy with his research. He was then 52.

Vikram Sarabhai had married the famous dancer Mrinalini Swaminathan in 1942. They had a son, Karthikeya and adaughter, Mallika.
Scientific Achievements

For a long time, only some individuals were interested in science and devoted themselves to it. That science is important for the development of the country and that the entire nation should take interest in it and help in its progress are modern ideas. In olden days some persons got interested in science, and then they did not think of food or water; they forgot their families and the whole world, and dedicated themselves to scientific research. Archimedes, Newton and Faraday are examples of such dedication. It was only a hundred years ago that nations began to realize the importance of science and scientists, and began to help them. After atomic science developed, it became difficult for any one individual to carry on research, without help from others. So teams of scientists undertook research. In addition, atomic research had to be carried on by several scientific institutes as no one institute could have all the facilities. So scientific research, which was only of individual interest, gained national importance. In fact, science has now crossed even national boundaries and has attained international status. That is, scientists of several countries share their knowledge and results, and work in cooperation. Space research which began in 1957 is responsible for this international cooperation. Even though one country may be engaged in such research, it cannot progress without the cooperation of other countries. Americans may launch an artificial satellite that revolves round the Earth. But its movement has to be studied at different points of the world. Only then all the necessary information about the experiment can be put together. So other countries have to put up tracking or observation centers. If it is a communication satellite - one, which receives and sends radio messages and television pictures from one country to another, thousands of miles away -such communication, will not be possible without the cooperation of other countries. Vikram Sarabhai was one of the leading scientists engaged in space research. During his studies on cosmic rays he discovered that the intensity of the cosmic rays changes twice a day. This discovery helped to understand the nature of inter- planetary space and its elect rd- magnetic properties. (If a small wire is wound round a piece of iron and electricity is passed through the wire, the iron becomes a magnet. If the magnet is moved about a wire, an electric current is produced in the wire. This production of magnetism by electricity and of electricity by magnetism is known as Electro- magnetic property.) As stated before, space research was started in 1957. Sarabhai made use of this research to find out if the results of his cosmic ray experiments were correct. America and Japan had set up a joint High Altitude Research Station at Chakaltaya in Bolivia. There they had set up equipment to discover mesons. Sarabhai sent a post-graduate student of his to yielded good results. Sarabhai conducted experiments in Trivandrum, Allbagh, Honalulu and Gulmarg; he showed that the reasons for the changes in the Earth’s magnetism which was accepted by scientists till then, were wrong;the changes were due to other reasons. (The Earth behaves as a magnet. The Earth’s magnetic power is known as the Earth’s Magnetism.)
Personality

Sarabhai was a genius. His fame had spread to many countries. We have to remember him forever for his work on cosmic rays and atomic power. There is also another important reason toremember this great man. He tried to secure for our country an honored place in the scientific world. He was always earnestly thinking how our lives can be improved and our objects achieved through science.

Vikram Sarabhai was a very modest and simple man. He always spoke gently. He was very polite. He was a great scientist and an efficient administrator; moreover, he treated others with friendliness and sympathy. He had very heavy work; his responsibilities, too, were great. He had no leisure at all. But yet, to the last, he remained a lover of beauty. He was not the kind of scientist who sits alone on a mountain peak far from all, living beings and society. For twenty years he looked after the group of the industrial concerns of his family. He had the unique fortune to combine extraordinary learning rich industrial experience and great wealth. Those who have even one of these are usually not modest and friendly. But Sarabhai, who held learning, power and money in the palm of his hand, was very modest and friendly. Sometimes, people who did not know how busy he was would waste his time with their long tales of difficulties and misfortunes. Sarabhai would listen to them patiently and comfort them. If some one asked, “Aren’t they wasting your precious time?”, he would reply, “In our vast land people come from many backgrounds. Not every one is lucky enough to have the education we have. So, we have to listen to everything they say to understand what is in their mind.”

To be in the company of Sarabhai was itself a pleasure. Even if he did not speak a word, his very smile would encourage his fellow workers. Even if a man carried a number of problems to him the moment the man saw Sarabhai’s bright and hopeful eyes and smile, he would feel that he could himself solve his own problems. He inspired such confidence in his men. He was always ready to help any one who was in trouble or difficulties. One day, a coolie was drawing a handcart loaded with heavy boxes. He was finding it difficult to draw it inside the Institute. When Sarabhai saw this, he ran to his help and pushed the cart. In the early days of the Institute, he would not seek anybody’s help to move heavy equipment from room to room. He would do it himself. He looked ‘on all men as equals. Even a servant could approach him freely, without feeling inferior. He would offer him a seat and let him speak frankly and without hesitation. Sarabhai believed that all men, whatever their status, should be treated with respect. He would’ not ignore any man just because the man was poor or ignorant or illiterate. He firmly believed that a man should be judged not by his salary but by his work and responsibility. He wanted every one to work hard for the good of the organization of which he was a part.

His clothes were always simple. In the beginning he was fond of loud colored shirts; on one day he wore bright green, on the next day dark blue, on another day red and so on, changing the color every day. Later on he changed over to pyjamas, ordinary kurta and sandals.
With Students

One of the objects of the Physical Research Laboratory at Ahmedabad, was to train young scientists.Although Sarabhai had various duties and was very busy, he never neglected this training. He encouraged about 20 students to conduct advanced research and get their Ph.D. Degrees.

Sarabhai working in his laboratory even at midnight was a common sight. Even at that hour his uppermost thought was the research work of his students. Even when he was waiting to board a plane he would be seen in a corner of the airport discussing with his students their problems. In Baroda, there was a big pharmaceutical factory (a factory to produce medicines) of the Sarabhais. Every Friday he would go to Baroda to supervise the work of thefactory and give instructions. He did not wish to waste his time during the railway journey from Ahmedabad to Baroda. He would take one or two students with him and discuss with them their problems.

He went abroad several times. However busy he was with his own work, he would spare sometime to meet Indian students in foreign countries; he would encourage them to return to India and continue their research in their motherland. But he also encouraged students to go abroad for higher studies, to get acquainted with the latest developments in science and technology and to return to our country to serve the motherland. He was sure that if a proper atmosphere was created in India for the young scientists to pursue their chosen line of research, they would gladly return. He had such great confidence in our young scientists.

Sarabhai’s Hopes and Views

Even when the study of atomic energy was still in its early stages, Dr. Homi Bhabha dreamt a dream. He dreamt of an India, which did not depend on foreign countries for experts. He wanted India to have her own specialists in every field. For this purpose, he established several organizations and research institutes. Vikram Sarabhai also had his dream. That was to use atomic energy for a variety of purposes - for the development of agriculture and industry, for communication satellites, for national integration and the promotion of literacy, for weather forecast and for exploration of mineral wealth etc. To his last breath he worked for the realization of this dream.

It is possible to produce atomic energy independently with our own knowledge, machines, equipment and men. To do so we must have our own heavy water factory and nuclear fuel manufacturing plant. That was his great desire and he took the first steps to establish these factories. But he did not live to see their completion.

A nation’s progress and prosperity depend on how well the people use science and technical knowledge for development purposes. Only by the planned use of the fundamental sciences, technical knowledge and industrial experience can there be rapid economic development. Before harnessing our natural wealth and resources, we should gather enough capital, give good training to our young men and women and produce great scientists. We should find out the needs of the country and prepare a technical plan to produce them. This planning should not take too much time. We should learn the most advanced and new research techniques from all parts of the world. At the same time, we should encourage the growth of such research techniques in our own country. This was Sarabhai’sapproach to the progress of India.
Greatness Recognized

Usually the President of the All India Textile Research Association would not be a mill owner. Sarabhai belonged to a mill owner’s family. But yet, in 1955 the members of the Association requested Sarabhai to be their President.

In 1956, the Productivity Congress met in Japan. The Indian Government selected him as the leader of the Indian delegation. He was only 37; and he was the first Indian to attend this Congress.

The only institution which reviews the progress of science in this country is the Indian Science Congress. Sarabhai presided over the Physics Section of the Conference in 1962. Very few have achieved such a distinction at the age of 40.

The Government of India awarded the Shanti Swarup Bhatnagar Medal in Physics to Sarabhai in 1962. In 1966 he received the Padma Bhushan Award. In the same year he was appointed as the Chairman of the Atomic Energy Commission. When he was the Chairman he prepared a master plan for the development of Atomic Energy and Space Research for the decade 1970-80. In 1968, the United Nations organized a Conference on Exploration and Peaceful Uses of Outer Space. Sarabhai was the Chairman. After his death, the Government conferred on him, in 1972, the title of Padma Vibhushan.
The Creator of Organizations

Sarabhai was immersed in scientific research. He wanted that science and technology should grow together, that

intelligent young men should be trained in science and technology and that the right atmosphere for their work should be created in the country. For this purpose he established several organizations. The very first one was his, own Physical Research Laboratory at Ahmedabad. In this, he formed the ‘Group for the Improvement of Science Education’, in 1963.

In 1947, when he was only 28 years old, he was entrusted with the organization of the Ahmedabad Textile Industry’s Research Association. He ‘ had then no experience of textile mills or textile technology. Yet, with great confidence, he built up the institution.

In 1963, he established the Nehru Foundation for Development, for the study of social and educational problems. In 1966, under its auspices, he established the Community Science Center, whose object was to spread scientific knowledge, to create interest in science and to promote experimentation among students, teachers and the general public. To train efficient managers of factories, he started the Indian Institute of Management at Ahmedabad.

Of all the institutions he established the most important were the Indian Space Research Organization with Centers at Thumba (near Trivandrum), Ahmedabad, Shriharikota (north of Madras) and Arvi (near Bombay). At Thumba and Shriharikota he established Rocket Launching Stations. There is an organization called Pugwash Continuing Committee whose aim is to establish peace on earth and promote disarmament, particularly of dangerous weapons, all over the world. Sarabhai founded the Indian Branch of this Committee.

In the midst of all this work, he had set apart sometime for the pharmaceutical industry. He was one of those who wanted to preserve the highest standards in the manufacture of drugs.
Capsules Of Wisdom
Vikram Sarabhai used to repeat constantly two sentences. They are capsules of wisdom. Every one should ponder over these sentences:
‘No great importance is to be given to mere experience.
‘He who can listen to the music in the midst of noise can achieve great things.’

Introduction

The genius who won the Nobel Prize for Physics, with simple equipment barely worth RS. 300. He was the first Asian scientist to win the Nobel Prize. He was a man of boundless curiosity and a lively sense of humor. His spirit of inquiry and devotion to science laid the foundations for scientific research in India. And he won honor as a scientist and affection as a teacher and a man.
Author - A.Krishna Bhatt

Dr. C.V. Raman

One day in 1903, Professor Eliot of Presidency College,
Madras, saw a little boy in his B.A. Class. Thinking that
he might have strayed into the room, the Professor asked
, “Are you a student of the B.A. class?”

“Yes Sir,” the boy answered.

“Your name?”

“C.V. Raman.”

This little incident made the fourteen - year - old boy well known in the college. The youngster was later to become a world famous scientist.

A Child Genius

Tiruchirapalli is a town on the banks of the river Cauvery. Chandrasekhara Ayyar was a teacher in a school there. He was a scholar in Physics and Mathematics. He loved music. His wife was Parvathi Ammal. Their second son was born on 7th November 1888. They named the boy Venkata Raman. He was also called Chandrasekhara Venkata Raman or C.V. Raman.

Raman grew up in an atmosphere of music, Sanskrit literature and Science. He stood first in every class and was. Talked about as a child genius. He joined the B.A. class of the Presidency College. In the year 1905, he was the only boy who passed in the first class. He won a gold medal, too.

He joined the M.A. class in the same college and chose Physics (study of matter and energy) as the main subject of study. Love of science, enthusiasm for work and the curiosity to learn new things were natural to Raman. Nature had also given him the power of concentration and intelligence. He used to read more than what was taught in the class. When doubts arose he would set down questions like ‘How?’ ‘Why?’ and ‘Is this true?’ in the Margin in the textbooks.

The works of the German scientist Helmhotlz (1821 - 1891) and the English scientist Lord Raleigh (1842 - 1919) on acoustics (the study of sound) influenced Raman. He took immense interest in the study of sound. When he was eighteen years of age, one of his research papers was -published in the ‘Philosophical Magazine’ of England. Later another paper was published in the scientific journal ‘Nature’.
Officer - Scientist

Raman’s elder brother C.S. Ayyar was in the ‘Indian Audit and Accounts Service’ (I.A.A.S.). Raman also wanted to enter the same department. So he sat for the competitive examination. The day before this examination, the results of the M.A. examination were published. He had passed in first class recording the highest marks in Madras University up to that time. He stood first in the I.A.A.S. examination also.

On May 6, 1907, Raman married Lokasundari Ammal.

At the age of nineteen, Raman held a high post in the government. He was appointed as the Assistant Accountant General in the Finance Department in Calcutta. And the same year something happened to give a new turn to his life.
210, Bow Bazaar Street

One evening Raman was returning from his office in a tramcar. He saw the name plate of the ‘Indian Association for the Cultivation of Science’ at 210, Bow Bazaar Street. Immediately he got off the tram and went in. Dr. Amritlal Sircar was the Honarary Secretary of the Association. There were spacious rooms and old scientific instruments, which could be used for demonstration of experiments.

Raman asked whether he could conduct research there in his spare time. Sircar gladly agreed. Raman took up a house adjoining the Association. A door was provided between his house and the laboratory. During the daytime he would attend his office and carry out his duties. His mornings and nights were devoted to research. This gave him full satisfaction. So he continued his ceaseless activities in Calcutta.

From Accounts to Science

At that time Burma and India were under a single government. In 1909, Raman was transferred to. Rangoon, the capital of Burma. When Chandrasekhara Ayyar passed away in 1910, Raman came to Madras on six months’ leave.

After completing the last rites, Raman spent the rest of his leave period doing research in the Madras University laboratories.

The Science College of Calcutta University was started in 1915.

There a chair for Physics was established in memory of Taraknath Palit, a generous man. Raman was appointed Professor. He sacrificed the powerful post in the government, which brought a good salary.

The Indian Science Congress was started in 1913. Its aim was to bring together scientists engaged in research; theyshould meet and exchange ideas. Its first session was held in 1914. Asuthosh Mukherjee was the President. Raman was the President of the Physics section. Later he worked for many years as the Secretary of the Science Congress. He presided over its annual sessions in 1929 and 1948.
Professor Raman

In 1917, at the age of 29, Raman became the Palit Professor. He continued research along with the new assignment.

Raman was very deeply interested in musical instruments such as the Veena, the Violin,the Mridangam and the Tabala. He began to work on them. Around 1918 he explained the complex vibrations of the strings of musical instruments. He later found out the characteristic tones emitted by the Mridangam, the Tabala etc.

Amritlal Sircar, who was devoting all his time to the welfare of the Indian Association for the Cultivation of Science, passed away in 1919. Professor Raman became its Honarary Secretary. Two laboratories - those of the College and of the Association - were under him; and this gave a new stimulus to his researches. Both his body and his mind could do all the work that had to be done. Many students came to him from different parts of the country for post-graduate studies and research. 210, Bow Bazaar Street and the University Science College Laboratory - these became the active research centers of India. Research workers like Meghnad Saha and S.K. Mitra, who became famous later, worked at these centres.
The Great Teacher

That was a time when Raman was completely immersed in experiments and research. According to the terms of the Palit Chair, he could have remained free from teaching work, doing research only. But Raman had great pleasure in teaching. Students were inspired by his lectures. They were eager to listen to him. He would not stick to one particular textbook. His lectures brought the fragrance of fresh research. They reflected Raman’s great curiosity about the secrets of nature. Usually the lecture was of an hour’s duration. Forgetting the time in the discussion of the subject, Professor Raman would sometimes lecture for two or three hours. Any doubt or question from a student would stimulate new scientific ideas.
Not a Minute to Waste

Absorbed in experiments, it was not unusual for him to forget food and sleep. Sometimes working late at night, he would sleep in the laboratory on one of the tables.

In the mornings too, most of his time was spent in the laboratory. He worked in informal clothes. At 9.30 a.m. he would rush home. After a shave and a bath he would dress up and send for a taxi. He

Would finish his breakfast in two or three minutes and get into the taxi. Racing over a distance of four miles, he would reach the class on time. He never wasted time.
In England

The Congress of the Universities of the British Empire met in 1921 in London. Raman went to England as the represen- tative of Calcutta University. This was his first visit abroad.

Raman lectured in the ‘Physical Society’ of London. People came in large numbers to listen to him. He was introduced to J.J. Thomson and Ernest Rutherford, the famous English Physicists. Raman visited St. Paul’s Church in London. A whisper at one point of the church tower is heard clearly at another point. This effect, produced by the reflection of sound, aroused his curiosity.
The Blue of the Sea

Raman’s journey to England and back was by sea. In his leisure hours, he used to sit on the upper deck of the ship and enjoy the beauty of the vast sea. The deep blue color of the Mediterranean Sea interested the scientist in him. Was the blue due to the reflection of the blue sky? If so, how could it appear in the absence of light? Even when big waves rolled over the surface, the blue remained. As he thought over the problem, it flashed to him that the blue color might be caused by the scatter- ing of the sun’s light by water molecules. He turned over this idea in his mind again and gains. Immediately after his return to Calcutta, he plunged into experiments. Within a month, he prepared a research paper and sent it to the Royal Society of London. Next year he published a lengthy article on the molecular scattering of light.

Raman never held the wrong belief that research could be carried out only with foreign-made or very complicated equipment. No doubt, he imported some equipment. No doubt, he imported some equipment. But he prepared much of the equipment he used with the help of his students.

New Contacts

Scientists of many countries appreciated the research papers of Raman and his colleagues. The Royal Society, the oldest and the most important science society of England, honored Raman in 1924 by electing his as its ‘Fellow’ (that is, a member).

The annual session of ‘The British Association for the Cultivation of Science’ was held in the same year in Toronto (Canada). Raman inaugurated the seminar on the scattering of light. R.A. Millikan, the famous American Physicist, who also attended, was full of admiration for Raman. They became fast friends too.

At the Mount Wilson Observatory in California (U.S.A), a telescope of 100-inch width was in use. Those were the times when discoveries in the field of astronomy (study of stars and planets and their movements) filled people with wonder. Raman was always eager to learn new things. He spent a couple of days onMount Wilson. During the nights he viewed the Nebula (bright or dark patch in the sky caused by distant stars or a cloud of gas or dust.) Through the telescope and was thrilled.

He went to Russia in 1925 to participate in the twohundredth anniversary of the ‘Russian Academy of Sciences’.

The Guide

Many scholars were working in the Calcutta laboratories to unlock the secrets of sound and light. To all of them Professor Raman was the ‘Guru’ and the leader. He had observed the blue color of the deep glaciers (mass of ice or snow) in the Alps mountain ranges. Taking the clue from this, some of the research workers studied some scattering of light in ice and quartz crystals. They also studied the scattering of light in liquids such as pure water and alcohol, as well as in vapors and gases.

With a complete mental picture of the phenomenon, Raman would proceed to experiment systematically. After that he would write the research paper based on the results of the experiments and arrange for its early publication. Sometimes it would be late in the day by the time the final copy was prepared. Then he would rush to the General Post Office in a taxi to catch the last mail. Then he would enjoy a feast of Rasagulla with his students.

He started ‘The Indian Journal of Physics’ in 1926 to make the prompt publication of research papers possible.

Raman wanted the young men working with him to take up indepenent positions and to serve the nation. He felt that his laboratory was a centre of training for young talent, but not a permanent storehouse.

Raman’s research on sound became famous allover the world. ‘Handbuck der Physic’, a German Encyclopaedia of Physics, was published in 1927. Raman was the only foreign scientist invited to contribute an article to it.

Raman Effect

Sometimes a rainbow appears and delights our eyes. We see in it shades of red, orange, yellow, green, blue, indigo and violet. The white ray of the sun includes all these colors. When a beam of sunlight is passed through a glass prism a patch of these *color- bands are seen. This is called the spectrum. The Spectro- meter is an apparatus used to study the spectrum. Spectral lines in it are characteristic of the light passing through the prism. A beam of light that causes a single spectral line is said to be monochromatic.

When a beam of monochromatic light passes through a transparent substance (a substance which allows light to pass through it), the beam is scattered. Raman spent a long time in the study of the scattered light.. On February 28, 1928, he observed two low intensity spectral line corresponding to the incident mono- chromatic light. Years of his labor had borne fruit. It was clear that though the incident light was monochromatic, the scattered light due to it, was not monochromatic.Thus Raman’s experiments discovered a phenomenon which was lying hidden in nature.

The 16th of March 1928 is a memorable day in the history )f science. On that day a meeting was held under the joint auspices of the South Indian Science Association and the Science Club of Central College, Bangalore; Raman was the Chief Guest. He announced the new phenomenon discovered by him to the world. He also acknowledged wit h affection the assistance given by K.S. Krishnan and Venkateshwaran, who were his students.

The phenomenon attracted the attention of research workers all over the world. It became famous as the ‘Raman Effect’. The spectral lines in the scattered light were known as ‘Raman Lines’.

Is light wave-like or particle-like? This question has been discussed from time to time by scientists. The Raman Effect confirmed that light was made up of particles known as ‘photons’. It helped in the study of the molecular and crystal structures of different substances.

World-Wide Interest in Raman Effect

Investigations making use of the Raman Effect began in many countries. During the first twelve years after its discovery, about 1800 research papers were published on various aspects of it and about 2500 chemical compounds were studied.Raman Effect was highly praised as one of the greatest discoveries of the third decade of this century.

After the ‘lasers’ (devices that produce intense beams of light, their name coming from the initial letters of ‘Light Amplification by Stimulated Emission of Radiation) came into use in the 1960’s, it became easier to get monochromatic light of very high intensity for experiments. This brought back scientific interest in Raman Effect, and the interest remains alive to this day.
The World Honors Raman

Raman received many honors from all over the world for his achievement. In 1928 the Science Society of Rome awarded the Matteucci Medal. In 1929 the British Government knighted him; thereafter Professor Raman came to be known as Professor Sir C..V. Raman. The Royal Society of London awarded the Hughes Medal in 1930.Honorary doctorate degrees were awarded by the Universities of Freiburg (Germany), Glasgow(England), Paris (France), Bombay, Benaras, Dacca, Patna, Mysore and several others.
The Nobel Prize, Too

The highest award a scientist or a writer can get is the Nobel Prize. In 1930, the Swedish Academy of Sciences chose Raman to receive the Nobel Prize for Physics. No Indian and no Asian had received the Nobel Prize for Physics up to that time. At the ceremony for the award, Raman used alcohol to demonstrate the Raman Effect. Later in the evening alcoholic drinks were served at the dinner. But Raman
did not touch them. He remained loyal to the Indian traditions.

A Keen Eye

However minute the results of an experiment, they could not escape the searching eyes of Raman. And his mind retained every detail of what he observed. An incident, which took place at Walter, the seat of Andhra University, may be mentioned. After the discovery of the Raman Effect, spectra of different substances were being studied there.

On one of his visits there, Raman found the research workers puzzled at not getting the expected spectral lines. Raman examined the plate containing the spectrum and exclaimed with joy, “There it is, you see!” He immediately got a projector and made the weak spectral lines clearly visible on the white screen.
In Bangalore

He came to Bangalore as the Director of the Tata Institute (the Indian Institute of Science) in 1933. The Tata Institute soon became famous for the study of crystals. The diffraction of light (the very slight bending of light around corners) by ultrasonic waves (high frequency sound waves which we cannot hear) in a liquid was elegantly explained by Raman and Nagendranath. This became known as the ‘Raman-Nath Theory’.

Raman’s Day

Raman was an early riser and used to take morning walks regularly. The sight of tall trees against the sky at dawn delighted him. By six in the morning he would be in the chamber where he worked. Up to 9 a.m. he would devote his time to discussion with students who were experimenting and to the study of research papers. At 10 o’clock he would be in the Directors office. He would complete the office work and return to the laboratory. He would be immersed in research till 8.30 p.m. He used to arrange two or three seminars every week. At these seminars all the workers would come together to discuss various problems of their research.

‘Use a 10-Kilowatt Brain’

Whenever students showed new results, Raman was delighted. He would guide them to do further work. If they appeared to be depressed he would inspire them to fresh efforts.

A student was once experimenting with an X-ray tube of one-kilowatt power. He learnt that a scientist in England was experi- menting on the same problem with a five-kilowatt X-ray tube, and grew depressed. When Raman, who was on his rounds, came to know of this, he said with a smile, “There is a very simple solution; use a 1 0-kilowatt brain on the problem.”

Raman possessed supreme self- confidence and he generated -it in his students also. Raman used to enquire about his students even after they left his Institute. If they had any difficulty he would help them as best he could.

Judging Talent

Raman had his own method of judging the merit of a student. Once he set a question concerning the vibrations of theMridangam at the Post-Graduate Examination of the Allahabad University. This was different from the other questions based on textbooks. Only one student answered it and he had spent all the allotted time on this one answer. Raman was pleased with his talent and personally congratulated him.

Once a candidate attended an interview for a research post in the Tata Institute. He had passed in the first class. He was asked, “Are there any scientific problems you would like to work on?” There was no satisfactory answer. Physically also the candidate was weak. Raman advised him, “Research is strange work. Success in it brings limit less joy whereas failure pushes one to deep despair. Joy and despair - both require bodily strength. You should first improve your bodily strength through sports and exercises.”

The Indian Academy of Sciences

In order to encourage scientific research in India, Raman established the Indian Academy of Sciences in 1934. From that year the science journal ‘The Proceedings of the Academy’ is being published every month.

The Government of Mysore granted 24 acres of land to promote the activities of the Academy. It was his earnest desire ‘to bring into existence a centre of scientific research worthy of our ancient country, where the keenest intellectuals of our land can probe into the mysteries of the Universe’. He fulfilled his wish by establishing a Research Institute atHebbal, Bangalore. He did not seek help from the Government but have away all his property to the Institute. The Executive Committee of the Academy named the centre ‘Raman Research Institute’.

The Raman Research Institute

In 1948 this great scientist entered on one more active phase of life when he became the Director of the Raman Research Institute. The Institute became the centre of all his activities. A garden and tall eucalyptus trees surrounded it. He used to say, “A Hindu is required to go to the forest in old age, but instead of going to the forest, I made the forest come to me.” At the Institute he could concentrate on things that interested him. He was alone with his work and was happy. At the entrance to the Institute was a board bearing the words, “The Institute is not open to visitors. Please do not disturb US.”

He did research on sound, light, rocks, gems, birds, insects, butterflies, sea shells, trees, flowers, atmosphere,weather and physiology of vision and hearing. His study covered such different fields of science as Physics, Geology, Biology and Physiology. Among them sound and colors particularly attracted him. Once he even went round shops to select sarees of different color designs.

Delight in Color and Light

Raman collected rocks and precious stones. His invaluable collection included hundreds of objects such as sand that melted due to lightning, rock indicating the lava flow during a volcano and diamonds, rubies and sapphires. Many fluorescent minerals (that is,minerals having the property of receiving short invisible rays and sending out long visible rays) were kept in a dark room. There he could create a small twinkling world by switching on the ultra-violet light. Thin layers of some crystals were prepared for study. No color was seen when they were viewed perpendicularly. But the viewer had only to change the angle - and blue, green and yellow colors delighted the eye. After a deep study of diamonds Raman explained many of their characteristics.

Once in Paris he went shopping for diamonds and crystals. There two beautiful butterflies with blue wings in a shop window attracted him. He bought them and later collected thousands of specimens.

Raman loved flowers for their colors. He grew many flower plants. He used to visit flower exhibitions to examine flowers.

Raman used to announce his newscientific discoveries at the annual sessions of the Academy. At the Madras session (1967) he discussed the influence of the earth’s rotation on its gaseous envelope. Next year he put forward his theory of the physiology of vision.

Many countries and institutions continued to honor him. The membership of the American Optical Society (1941), the National Professorship of India (1948), the Franklin Medal of the Franklin Institute (1951), the International Lenin Prize (1957), the Membership of the Pontifical Academy of Science (1961) -these were some of the honors conferred on him.

The greatest honor the Government of India confers on an Indian is the award of ‘Bharat Ratna’. Raman became a ‘Bharat Ratna’ in 1954.

Interest in Music

Raman was a great lover of music. He used to say, “I should live long, because I have not heard all the music I want to hear.” He was a frequent visitor to a shop selling musical instruments in Balepet, in Bangalore. He collected a variety of musical instruments like the Mridangam, the Tabla, the Veena, the Violin and the Nagaswaram.

‘The Catgut Acoustical Society’ of America is devoted exclusively to the study of violins. It elected Raman as its honorary member.

‘A General Practitioner in Science’

When Raman stepped into the field of research, Modern Physics was in its infancy. It developed numerous branches by the time he began working in his own Institute. Then research workers had access to modern equipment and methods, which were not available six decades earlier. They tended to study a small field and to specialize in it. But Raman never limited his activities and interests to a narrow field.

Raman once inaugurated the ‘General Practitioners’ Conference’ in Bangalore. A general practitioner is a doctor who treats common illnesses. Raman humorously commented on that occasion that he was a general practitioner in science. He liked all scientific problems whether they were small or big. His interest and satisfaction lay in finding a solution to the problem.

In 1969, the daughter of Nagendranath (who had been a research student under him thirty years earlier) was married; Raman and his wife attended thereception. Raman drew Nagendranath aside and explained his new problem; he was trying to find a theory of earthquakes taking into account the actual shape of the earth and the wave-like nature of the quakes. Raman was not a person to be satisfied with his past achievements. He was always seeking new and vaster fields of study.

Raman was a delightful speaker. Sprinkled with good humor, his talk was usually focussed on realities. Raman used to say that the color of the sea interested him more than the fish, which lived in it. He thought that we should have our own ships for oceanographic research (the study of the sea). He often said that India lost her freedom because she took no interest in the seas.

A Lion’s Heart

Friends and admirers organized a special function at the Annual Session of the Academy at Ahmedabad to honor him on his eightieth birthday. Many people expressed warm sentiments. Raman never took much interest in birthday celebrations. Still, at the end. He thanked the organizers; and with a twinkle in his eyes, he said, “I wish some one had said that I had a lion’s heart!” All who had spoken forgot to make mention of his great asset, namely courage.
His God and His Religion

Raman would not speak much about God and religion. Science was his God and work his religion. He believed that new discoveries confirm the existence of God; if there is God we have to find Him in this universe.

A journalist once asked him, “What do you feel about the long and eventful period of your scientific work and achievements?” Raman replied promptly, “I have no time to think of the past and I am not inclined to do so. I spend my life as a scientist. My work gives me satisfaction.”

As he was completing his 82 year Raman organized a weeklong conference of the members of the Academy in September 1970. On that occasion he invited young scientists to present papers on different subjects.

Every year he used to deliver a popular science lecture on the Gandhi Jayanthi Day. In 1970, he spoke on the new theories about hearing and the eardrum. This was his last lecture.

A few days before his 83 birthday Raman suffered a mild heart attack. But there was quick recovery. He never dreamt of a life without work. He had told his doctor, “I wish to live a hundred- per-cent active and fruitful life.”

Raman, a seeker of truth throughout his life, passed away on the 21st of November 1970.

Radhakrishnan, his younger son, became the Director of the Raman Research Institute.

Without much encouragement, Raman had entered the field of science in his early years. Deeply attracted by the secrets of sound and light, he marched ahead in the world of science. By his achievements and self-respect he earned a honored place for India in the world of science. He laid the foundations of a scientific tradition in India by building up institutes for research, by publishing science journals and by encouraging young scientists. Truly he was the ‘Grand Old Man of Indian Science’.

Raman possessed the curiosity of a little boy to know new things, and the intuition of a great genius in understanding the secrets of Nature. The life of this great scientist was truly the life of a great seer.