President delivers first Dr. Dara Antia memorial lecture
Following is the text of the First Dr. Dara Antia Memorial Lecture which was delivered by the President,
Dr. A.P.J. Abdul Kalam in Pune today:
Material Science and National Development
“I am delighted to deliver the first
Dr. Dara Antia Memorial Lecture in this beautiful environment of Kadakhavasala
lake. My greetings to scientists, technologists, academics and other invited
guests.
When I studied the life of Dr. Dara
Antia I found that the research and development were in the forefront of his
career. Apart from the research Dr Dara Antia himself carried out, he piloted
research as a member of metals committee of CSIR and the governing council of
National Metallurgical Laboratory. He also played crucial role in establishment
of defence metallurgical research laboratory and was on its governing body for
many years. He has spoken and written on technology transfer and how R & D
and technology development should be organized for rapid industrialization. Dr
Dara Antia also promoted the design, development of many new strategically
important alloys. My respects to Dr. Dara Antia for his outstanding
contribution to the development of metallurgy in India.
While I am with this audience I would
like to share my experiences with four metallurgists with whom I have worked.
Firstly, I would like to talk about Prof Brahm Prakash, who was well known as
the pioneer in establishing the Nuclear Fuel Complex in Hyderabad.
Innovations in Aerospace material
During the development of SLV-3 we
were ready to go for the first static test S-2 (3/4), the second stage motor
static test with the flight hardware. While we were ready to do the test at
SHAR, there was a debate whether to go for a test or not. The structural
specialists had analysed all the aspects and declared that the defects which
had come to the notice on the 15 CDV6 Nozzle backup hardware is going to be a
failure after 80% of burn time. This may even lead to opening up of Nozzle or
explosion. All the members of Space Council declared that the test should be
called off. Dr. Srinivasan, a structural specialist had his own analysis on the
nature of crack and crack propagation based on his experience. I requested
Prof. Brahm Prakash for his view based on his experience that he had with the
metal. He spent considerable time in the evening and night and concurred for
the test. The test was eventually successful. Dr. Brahm Prakash?s guidance
paved way for the establishment of the acceptance standard and crack levels in
metallic welding for the particular type of steel was established. This event
is still ringing very clearly in my mind.
Prof Brahm Prakash was instrumental
in taking a decision to go for Maraging Steel against 15 CDV-6. Because of this
decision the country is producing adequate quantity of Maraging Steel today.
When
he was a Director of VSSC, Dr. Brahm Prakash took the path breaking decision of
using of using new generation Maraging Steel for future satellite launch
vehicles like PSLV, GSLV boosters. Because of this futuristic decision Maraging
stel in being produced in India much to the dismay of the developed countries.
How to take the challenge?
I would now like to narrate an event
which took place thirty years ago. During 1976, for realizing the Inertial
Measuring Unit (IMU) for Satellite Launch Vehicle (SLV-3) , we needed a
precision IMU housing unit which can house 3 accelerometers and 3 rate
integrating Gyros along with the connected processing electronics. The weight
budget given for the entire inertial measuring unit was only 3 kg. Such a
precision housing within this weight budget can be made only by using magnesium
alloy. I was in search of a foundry which can do this casting. I visited number
of industries both in the private and public sector. When I asked them, whether
they can cast the housing, all of them told that it will take minimum three
months for as a metallic mould would be mandatory. In a periodic review of the
SLV-3 programme by Prof. Satish Dhawan, IMU housing was on the critical path.
Then he suggested that there is a tall metallurgist working in DMRL. I am sure
if you go and tell your problem, he will be able to help you. When I reached
DMRL, I found a tall scientist who was busy discussing with his team in one of
the laboratories. He was none other than Dr. V.S. Arunachalam. He asked me what
my problem was. I told him that I needed a magnesium alloy precision casing for
the inertial measuring unit within a weight budget of 3 kg. I also told him, I
would like to have one Unit of the cast casing for testing within a week. He
immediately told that there is no problem. He said, you be with me, I will get
you the casting within a week. He called his team members and explained the
task. Members were studying various options. Dr. Arunachalam gave a suggestion
that they can cast using a thermo-cole mould with certain lining, which is the
fastest method to get the casting in time. With this method, I got the casting
within a week. When others were thinking of making casting through a metallic
die, which is a time consuming process, Dr. Arunachalam provided an innovative
solution to meet the timeframe. The only problem here was, you have to make a
mould for every casting. This was my first meeting with Dr. Arunachalam. At
that time, I was not aware that I am going to work with him in the DRDO in the
later years.
Development of Critical Materials
Prof P. Rama Rao after his academic
stint in Banaras Hindu University joined DRDO. His key contribution to
metallurgy was in the analysis of behaviour of metals and alloys especially in
the area of fracture and fatigue. Utilizing this specific knowledge he has been
able to develop new generation of low cost high strengths steel which are
competitor to the very expensive high strength alloys. He provided the
leadership for the development of heavy alloy penetrators used in the tank ammunition
which led to the establishment of a fully automated heavy alloy penetrator
plant as a collaborative venture between DRDO and Ordnance Factory Board.
Today, the country is fully self-reliant in tank ammunition. As you are aware,
India has the largest amount of titanium ore in the world. Prof Rama Rao
facilitated the establishment of extraction technology of titanium from its ore
in DMRL. Availability of this technology is enabling Kerala Metals and Minerals
Limited to establish a titanium sponge plant with the collaboration of Indian
Space Research Organization. At DMRL, Prof Rama Rao gave the leadership for the
development of critical aero engine materials (Nickel alloys) and components
required for LCA gas turbine engine. The special emphasis was on the production
of investment single crystal investment castings of directionally solidified
blades and vanes for both LCA main engine and jet fuel starter which is the
auxiliary engine for the aircraft. Prof Rama Rao has developed a strategic
vision for exploiting minerals and metals wealth of the nation.
Heat shield design and development
Next I would like to talk about Smt
Rohini Devi, who is the senior most women Scientist working in DRDO. She is in
the development of advanced processed technologies, establishment of facilities
and development of state-of-the art products which have to withstand the rigors
of re-entry. When Agni re-enters the atmosphere traveling at 15 times the speed
of sound. It experiences tremendous friction which makes the outer surface
blating leading to very high temperature of 3000 to 4000 degree centigrade. We
needed a protection system to ensure that the inside temperature does not
exceed 50 degree centigrade. Special composite product was developed which will
ablate layer by layer, keeping the inside cool. This involves four dimensional
weaving technology for the nose tip which is to be further impregnated at very
high temperatures and pressures of the order of 1000 atmosphere. Special
equipments like hot isostatic press and multi axis winding and stitching
machines and curing machines are needed.
Multi-directional pre-form technology
is a closely guarded secret of the western world. By pooling up the research
talent in the country available in ISRO, ADA, DRDO and Universities through a
consortium approach and nurturing the young minds she could successfully
develop products which have been put to operational use in Agni programme. This
also led to the development of calipers called Floor Reaction Orthosis (FROs )
extending the benefit of this strategic technology for human good.
FRO Technology: During
this time Dr. B.N. Prasad of Nizam?s Institute of Medical Sciences (NIMs)
Hyderabad contacted me and asked how the high technologies of defence can be
used for medical science. They brought out the specific problem of polio
appliances, which are required in great numbers and conventional method of
their fabrication, will not be able to cater to the needs of the country.
Moreover, they felt that there was a need to improve upon the materials and
quality. Immediately, I thought of Rohini Devi?s work on advanced composite
materials, used in the fabrication of missile airframes, which are quite light
weight and very strong. I thought that why do I not use them for the
fabrication of light weight, ultra strong and durable standardized walking
aids. The standardization was the only way to mass produce these walking aids
in order to cater the needy children. Then, a team consisting of scientists
from DRDO and doctors from NIMS was formed to study the problem and later a
project was sanctioned jointly by Department of Science and Technology and
Ministry of Social Justice and Empowerment. This has lead to the production of
over 10,000 FROs in the country. We have fitted the FROs to the children in
different parts of the country through number of FROs camp organized by DRDO
and Nizam Institute of Medical Sciences.
Now I would suggest this programme
has to be intensified and we should plan to provide FROs to hundred thousand
children before 2010. This will involve creation of a training centre and three
or four production units for the FROs. This mission has to be carried out as a
collaborative venture between Ministry of Social Welfare and Empowerment, State
Governments, multiple orthopaedic medical institutions, DRDO and societal
reformers.
Convergence of Technologies
The information technology and
communication technology have already converged leading to Information and
Communication Technology (ICT). Information Technology combined with
bio-technology has led to bio-informatics. Now, Nano-technology is knocking at
our doors. It is the field of the future that will replace microelectronics and
many fields with tremendous application potential in the areas of medicine,
electronics and material science. When Nano technology and ICT meet, integrated
silicon electronics, photonics are born and it can be said that material
convergence will happen. With material convergence and biotechnology linked, a
new science called intelligent bioscience will be born which could lead to a
disease free, happy and more intelligent human habitat with longevity and high
human capabilities. Convergence of bio-nano-info technologies can lead to the
development of nano robots. Nano robots based on DNA when they are injected
into a patient with a particular disease, my expert friends say, will diagnose
and deliver the treatment exclusively in the affected area and then eventually
would get digested.
Emerging area in energy research: Recently,
I was reading the ?New Scientist?, where I found that, there is a possibility
of making solar cells as small as a molecule. Victor Klimov says that, one
photon of sunlight can give two electron?s worth of electricity. In all solar
cells now in use, in everything from satellite to pocket calculator each
incoming photon contributes at most one energized electron to the electric
current it generates. At Los Alamos National Laboratory, Klimov and his team
have broken through this barrier. They have shown that by shrinking the elements
of a solar cell down to a few nano meters or millionth of a millimeter, each
captured photon can be made to generate not one but two or even more charge
carriers. If this effect can be harnessed, it could change the whole energy
debate by making solar power much more efficient and economical. This is a
unique approach, which gets to the very root of the process and compliments all
other methods.
I am sure material scientists will be
able to carry out studies and work towards the realizing the national goal of
achieving energy independence through material science and technologies.
Vision for Metallurgists and Material
Scientists
I would suggest the scientists and
technologists assembled here to consider taking up action in following areas.
a.
As you are aware India?s raw material resources both in the
land and the seabed are not fully explored. There is an urgent need to enhance
our exploration activity particularly in the energy material area such as
oil, coal and uranium. For this we may have to acquire advanced and exhaustive
exploration capabilities.
b.
After exploring we have to intensify our activity in processing
and upgrading the raw material to an acceptable grade. For example, the quality
of Indian iron ore can definitely be improved through beneficiation.
c.
Action is required to draw technology map for converting raw
material to product for deployment in advanced systems. This technology map
will enable us to see the technology gap which exists in making the final
product. Mission mode programmes are needed for bridging these technology
gaps. One such area where the gap has been filled is in the development of
titanium sponge. This has to be replicated in many other metals.
d. Design, development, cost effective production and marketing
of various types of titanium alloys beyond aerospace application into commercial
applications.
Conclusion: Creative Leadership
There are 540 million youth below 25
years in the population of a billion people. The nation needs young leaders in
material science who can command the change for transformation of India into a
developed nation embedded with knowledge society. The leaders are the creators
of new organizations of excellence. I have seen and worked with creators of
vision and missions. Quality leaders are like magnets that will attract the
best of persons to build the team for the organization and give inspiring
leadership even during failures of missions, as they are not afraid of risks.
One of the very important ingredients for success of the vision of transforming
India into a developed nation by 2020 is the evolution of creative leaders. Who
is that creative leader? What are the qualities of a creative leader? The
creative leadership is exercising the task to change the traditional role from
commander to coach, manager to mentor, from director to delegator and from one
who demands respect to one who facilitates self-respect. The higher the
proportion of creative leaders in a nation, the higher the potential of success
of visions like ‘eveloped India.’
Now
the question comes, in the present dynamic situation of India, will the
creators of creative leaders emerge? Poetically, I can say that when the
horizon is fully red or fully green,
creator of creative leaders appear in the horizon. I believe and I am
sure that this is the time; creators of creative leaders will emerge for
finding new innovative solutions for achieving the goal of prosperous, peaceful
and secure planet earth.
My best wishes to all the scientists
and technologists for success in their missions of applying science and
technology for societal transformation.
May God bless you.”
* * *
HS/CS
(Release ID :18297)