Lecture to the Students of Iit Karagpur at Karagpur, West Bengal(Lecture-ii)
IIT, KHARAGPUR, WEST BENGAL : 17-05-2007
Convergence of Technologies
"Creativity leads to thinking"
India is well on its way to become a knowledge society. There is all round growth in all sectors of the economy namely agriculture, manufacturing and services. Today we have an opportunity to take the leadership in the knowledge revolution. Knowledge Revolution is indeed the foundation for leading India into a Developed Nation. For this, the time is ripe because of the ascending trajectory of the economy, availability of great institutions for capacity building of the human resource, abundant bio-diversity, and other natural resources and above all, our 540 million youth who are determined to make the nation prosperous, happy and a safe place to live well before 2020. With this background India is taking the lead in mobilizing and integrating national and international knowledge resources. Keeping this in mind, I would like to discuss with you on the topic, ?Convergence of Technologies.?
Convergence of Technologies
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 would 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 when they are injected into a patient, my expert friends say, will diagnose and deliver the treatment exclusively in the affected area and then the nano-robot gets digested as it is a DNA based product.
Convergence of ICT, aerospace and Nano technologies will emerge and revolutionize the aerospace industry and electronics leading to nano computing systems. This technological convergence will enable building of cost effective low weight, high payload, and highly reliable aerospace systems, which can be used for inter-planetary transportation. Till recently, silicon and its siblings were considered to be inefficient as sensors, actuators and for photosynthesis. Things are changing. The convergence of computers, communication and sensing into a single smart device and the ability to have mobile and communicate between them is leading the research and development in an important area of Sensor networks. This research is revolutionizing our monitoring systems be it in the area of environment and pollution control, be it in the area of agriculture for crop health monitoring or be it in the area of surveillance. The sensor networks are finding newer applications. This is another convergence of functions that will be very important in our future systems.
With this background of convergence of technologies, I would like to discuss some of the nanoscience and technology products in which India has made certain progress.
Products progress in Nano Science & Technology in India ? some examples
a. Water: Nano tube filter ? water purification
The scientists from Banaras Hindu University, Varanasi have devised a simple method to produce carbon nanotube filters that efficiently remove micro-to nano-scale contaminants from water and heavy hydrocarbons from petroleum. Made entirely of carbon nanotubes, the filters are easily manufactured using a novel method for controlling the cylindrical geometry of the structure. The filters are hollow carbon cylinders several centimeters long and one or two centimeters wide with walls just one-third to one-half a millimeter thick. They are produced by spraying benzene into a tube-shaped quartz mould and heating the mould to 900C. The nanotube composition makes the filters strong, reusable, and heat resistant, and they can be cleaned easily for reuse.
The carbon nanotube filters offer a level of precision suitable for different applications. They can remove 25-nanometer-sized polio viruses from water, as well as larger pathogens, such as E. coli and Staphylococcus aureus bacteria. The researchers believe this could make the filters adaptable to micro fluidics applications that separate chemicals in drug discovery.
b. Power: Gas flow induced generation of voltage from solids
Prof AK Sood, Professor of Physics at Indian Institute of Science, Bangalore and his student have studied, experimented and found that the liquid flow in carbon nano tubes can generate electric current. One of the most exciting applications to emerge from the discovery is the possibility of a heart pacemaker ? like device with nanotubes, which will sit in the human body and generate power from blood. Instead of batteries, the device will generate power by itself to regulate defective heart rhythm. The Indian Institute of Science has transferred the exclusive rights of the technology to an American start-up Trident Metrologies. They will develop the prototypes and commercialize the gas flow sensors.
d. Microwave CNTs Production unit
Defence Materials and Stores, Research and Development Establishment (DMSRDE), Kanpur is synthesizing non-aligned, quasi-aligned and aligned CNT with a batch size of 50 grams using a fast synthesis process. It has a maximum operating temperature 12000 C. The CNTs will have applications in EM absorbers, composites, gas sensors, flow monitors, field emission devices.
e. Healthcare: Typhoid Detection Kit
Typhoid Detection Kit has been developed by Defence Research and Development Establishment, Gwalior using the nano sensor developed by Indian Institute of Science, Bangalore. Typhoid fever caused by Salmonella typhi is a major health problem and an important challenge to health authorities of third world countries due to unsatisfactory water supply, poor sanitary conditions, malnutrition, emergence of antibiotic resistant strains etc. According to an estimate the worldwide incidence to typhoid fever is 16 million cases annually and mortality rate is 600,000 individuals per year worldwide. In India, the morbidity due to typhoid varies from 102 to 2219/100,000 population in different parts of the country. In some areas typhoid fever is responsible for 2-5% of all deaths.
In India for routine diagnosis for typhoid disease Widal test is performed with single serum sample which does not provide the correct diagnosis of infection. Therefore a Latex agglutination based test has been developed at DRDE, Gwalior using recombinant DNA technology and immunological technique for rapid diagnosis of typhoid infection. The test detects ?S? typhi antigen directly in patient?s serum within 1-3 minutes which is very important for initiating early treatment and saving human life. The collaborative work between DRDO and Indian Institute of Science, Bangalore has resulted in increasing the sensitivity of the test by 30 times by applying a small electric charge (1.5 V).
Nano technology product survey: There may be many more achievements in our scientific laboratories; I suggest DST and CII to jointly conduct a survey to prepare the technological breakthroughs accomplished in nano technology products in India. Now let me discuss, what I have witnessed on the convergence of technologies in Bio-Nano and Info in Singapore and Republic of Korea.
Nano cluster: Nanyang Technological University has created a Nano science and Nano Technology cluster, which is a NTU wide network of research center with shared facilities for Nano fabrication, Nano characterization and exploitation of Nano technology applications. Focused areas of research, development and commercialization include Nano devices, Energy & Catalysis, Nano Magnetics & Photonics, Organic Molecular Electronics, Nano ? Biotech and Nano Materials: Synthesis. I visited the Nano Cluster labs and witnessed the developed products such as:
a. Electronic Biochips: Microfluidic protein biochip for electrochemical immunoassays with dual ring electrode.
b. Development of PLZT (Lanthanum-substituted lead zirconate titanate) electro-optical ceramics for eye-protection devices: It can rotate the plane of incident light polarization from 00 to 900 by electric-induced birefringence. So, PLZT ceramics can be applied in eye protection devices, protecting eyes or optical sensors from suddenly incident intense light. It provides low driving voltage and fast response time.
c. Field emission x-ray source: Development of compact x-ray source based on CNTs (Carbon Nano Tubes) and carbon nano fibers as an electron emitter for 3-D inspection and biomedical applications.
Nano Fab: I had visited the Samsung Electronics, Giheung Plant in Korea during my recent visit to Republic of Korea. They are the leaders in semiconductor, tele-communication, digital media and digital convergence technologies. Out of the eight new fabrication lines, Samsung is designing four with capacities higher than conventional lines with the possibility of a 300 mm or lager wafer-unit, it includes one R&D line. This has resulted in a steep growth in global memory semiconductor market share for Samsung on a year to year basis. Also, I had a glimpse of the nano technology research in Samsung. Using this technology and the bioinformatics the researchers in Samsung are developing a chip that can be used to diagnose common diseases even at home. Once the patient knows reasonably well the problem, will use the information to chose the doctor, the treatment options, and possible outcome.
This visit has given me an insight, about how they plan and execute right from science, research, technology development, product development and commercialization aiming at positioning the products in the world market within a specified time frame. I have witnessed that the integrated planning includes capacity building, establishment of centers of excellence, creation of world class infrastructure, transfer of technologies to industrial partners and marketing.
A way ahead
I have studied India?s scientific and technological work after independence. There have been some excellent areas of basic research in very advanced topic right from late 1950s and 60s. For example we had excellent work on aero science, material science and also excellent work on semi-conductor research. Some world class scientists published papers also. Later even in the Liquid Crystal Display (LCD) area some original work was done by Raman Research Institute. We should now work to realize world class materials.
However, when one studies the technological and commercial aspects of these areas, the results have not been commensurate. We never produced an indigenous aircraft until very recently. Also we missed micro electronic revolution in the 70s. Similarly, in Liquid Crystal Display, we never even started a good commercial production whereas countries like Taiwan and South Korea have become world leaders in commercial production of these products. If we study, many areas, such trend seems to be the pattern.
We should not repeat this again in areas like Nano-Technology and Convergence of nano-technology with ICT and BT. Therefore, even while we are concentrating on basic research with eminent scientists working in it, simultaneously Indian industrial group small, big and medium should concurrently work on commercialization of nano-technologies. It may well be that the technologies are developed in India or in USA or in other countries. The main focus should be speedy commercialization to fit into the global market. The time is now ripe since our economy is in the ascent phase and the manufacturing sector has established adequate capacity to promote rapid commercialization of products. Towards this, I suggest that separate funds which can be used primarily for commercialization by Indian industry either for in-house or partnership mode for specific product should be encouraged at the earliest. And innovative managerial mechanism has to be there to utilize these funds with utmost speed and with commercial success in mind. The project should be market driven. I would suggest to the government to set apart sufficient funds on non-lapsable basis for nano-technology commercialization, and I would like industries to take a lead in this matter. Simultaneously, there is a need to take action to build the human resource required for undertaking the challenging tasks in this new sector. I would recommend the nano-technology community, particularly, the industrialists to read the book titled ?Nano-Technology Market and Company Report? ? finding hidden pearls prepared by Deutsche Bank and other experts, with details of over 350 nanocompanies and interviews with over 100 entrepreneurs.
We should mount a mission mode operation to deliver tangible products to meet our national demand as well as to be beneficial to the other countries. Let me discuss some of the national missions and the possible areas of research, design, development and production of products with reference to the areas of importance for development using nano science and technologies.
Possible areas of Cooperative Missions
Agriculture and food processing: We are in the mission of generating 400 million tones of food grains with reduced land, with reduced water and with reduced workforce. It is essential to take up agro food processing in a big way which will bring employment potential in rural areas.
Some of the possible areas of research in agriculture and food processing are: Nano-porous zeo-lites for slow-release and efficient doses of water and fertilizers for plants, and of nutrients and drugs for livestock, nano-capsules for herbicide delivery, nano sensors for soil quality and for plant health monitoring. Nano-composites for plastic film coatings used in food packaging, antimicrobial nano-emulsions for applications in decontamination of food equipment, packaging or food processing are other important areas of research.
Infrastructure: India is aspiring to build hundred million houses within next ten years. The infrastructure development in metropolitan and tier-2 cities needs to be enhanced in the form of new bridges, airports, marketing complexes and industrial units. 40% of the rural areas need to be covered with all weather roads; we need to double the present national highways ratio per 100 square kilometer area.
Nano-science material and technology research can definitely provide a solution. Our research focus in the nano-material should be towards cheaper rural housing, surfaces, coatings, use of concrete with heat and light exclusion. Can we develop heat resistance nano-material to block ultraviolet and infra red radiation? We should also develop a nano-molecular structure to make concrete more robust to water seepage, with self cleaning surfaces and bio active coating.
Energy: Energy Independence is India?s first and highest priority. We are determined to achieve this by the year 2030 through three different sources namely renewable energy (solar, wind and hydro power), electrical power from nuclear energy and bio-fuel for the transportation sector. Energy independence throws very important technological challenges to the world: The solar cell efficiency has to increase from the present 15% to 20% to 45 to 50% through intensified research on CNT based solar cells. For thorium reactors, as it is known, thorium is a non-fissile material. It has to be converted into a fissile material using Fast Breeder Technology. In the Bio-fuel area, the challenge is bio-fuel plantation for higher yield, esterification technologies for the higher output and the modification to automobile power plants. These three research areas definitely need intensive cooperation between Greece and India.
Safe Drinking Water: We have embarked on a mission for water purification, water de-toxification, water desalination through nano membranes and nano sensor for detecting contaminants and pathogens? How the nano-porous zeo-lites, nano-porous polymers can be used to design and develop products for water purification.
Healthcare: India has already patented the development of drug delivery system using nano-technology. Stem cell research in India is advancing in the field of cardiology, ophthalmology, diabetic research, endocrinology, oncology and immunology. It is essential to develop drug delivery system for stem cell implantation into the specific organs of the body related to the ailment using nano technology.
Aerospace: Emerging technologies such as MEMS, Nano, Information technology, biotechnology, space research, Hypersonic, High power lasers and microwave will be dominating the future in every field and applications. The advancements in material science and technology will give a major thrust to the realization of advanced aerospace systems. We are today at the convergence of Nano, Bio and Information technologies, that will lead to new generation aerospace devices and products.
Molecular nano technology has enormous potential for future aerospace systems. Research has shown that newly discovered class of molecules, particularly carbon nano tubes built from graphite sheets curved into a wide variety of close shapes, may lead to tougher, high temperature materials that can survive in vacuum and other harsh environments. Carbon nano tubes are normal form of carbon with remarkable electrical and mechanical properties. It is hoped that such materials could revolutionize electronic design and open the space frontier by radically lowering the cost of launch to orbit.
Carbon Nano Tubes reinforced with polymer matrix will result in composites which are super strong, light weight, small and intelligent structures in the field of material science. This has tremendous aerospace applications.
ICT: Molecular switches and circuits along with nano cell will pave the way for the next generation computers. Ultra dense computer memory coupled with excellent electrical performance will result in low power, low cost, nano size and yet faster assemblies. This will result in the small scale assembly of computers, tablet PCs, display systems etc.
Collaborative Programme in Nano Science and Technology
Next ten years will see nano technology playing the most dominant role in the global business environment and is expected to reach $ one trillion. In this scenario, with the core competence of IITs and Indian R&D institutions in collaboration with international institutions and industries, we can create vertical missions under a joint venture organisation for at least 10 nano technology products in Water, Energy, Agriculture, Healthcare, Space and Defence and ICT sectors. In these identified vertical missions, R&D institutions, Universities, private and public Industries from India and other partnering countries should work together for faster design, development and production of products for world market.
In order to achieve this mission, we need to connect all the relevant institutions participating in this mission using the high bandwidth fiber optics network into a Knowledge Grid specially established for the nano technology mission.
Conclusion
Since, I am in the midst of students and scientists of IIT, Karagpur, I would like to share some of the research areas where we can focus on.
1. In the energy sector, increasing the solar photovoltaic cell efficiency from the existing 15% to 45% using silicon as a base with Carbon Nano Tube is an important research challenge. Scientists in reputed laboratories in the world have established the fact that the alignment of the CNT with the polymer composites substrate is the key issue and this aligned CNT based PV cells would give very high efficiency in photovoltaic conversion. The polymer composites increase contact area for better charge transfer and energy conversion. In this process, the researchers could achieve the efficiency of about 50% at the laboratory scale. The intensity of research in Indian research institutions has to be enhanced to realize commercial production of CNT based Photovoltaic cells.
2. India has to go for nuclear power generation in big way using thorium based reactors. Thorium, a non fissile material, is available in abundance in our country. Intensive research is essential for converting thorium for maximizing its utilization and generating electric power through thorium based reactors.
3. Proteomics is the study of all the proteins expressed by the genome of a cell. It is the logical extension of genomics. Proteomics helps to understand the basic biological processes critical to normal cellular functions as well as the development of diseases. It identifies the essential components of these processes and exploits these components as targets in the development of new methods to prevent or treat diseases. The type of work involved is huge and challenging, and much bigger than the Human genome programme. There is a national programme in proteomics. This has to be given thrust with cooperation of International Scientific community.
4. There is much research and development and progress in testing of vaccine in the country for prevention of HIV/AIDS disease. It is indeed a big challenge for life science scientists to have an integrated vaccine development leading to production in three years time.
5. Stem cell research through three areas such as Adult stem cells, umbilical cord stem cells, and embryonic stem cells has to be pursued on a mission mode for finding cure for many diseases.
6. In many places in our planet, we experience severe earthquakes resulting in loss of life, loss of wealth and in some cases it destroys the decades of progress made by the country and its valuable civilizational heritage. India has earthquake problems periodically in certain regions. It is essential for us to work on mission mode research for forecasting the earthquake using multiple parameters using precursors such as pre-shock conditions, electromagnetic phenomena prior to final rupture and atmospheric and ionospheric anomalies.
7. The quantum of rainfall in a particular area for a particular cloud condition within a specified duration is not being determined by the present monsoon prediction system. Heavy rains in Mumbai, Chennai, Hyderabad in our nation during the last few years and Katrina hurricane in US has created enormous loss of life and property. This brings out the necessity for global monsoon research for determining intensity and quantum of rain in a particular cloud condition through a validated prediction system with detailed research. With this system scientists should be able to provide the information for the particular cloud condition, how much rain will come in what period through the use of Polorimetric radar.
Solutions to these seven research areas: first two relating to solar power and nuclear power area, third relating to healthcare, fourth relating to HIV/AIDS, fifth relating to stem cell research, sixth relating to forecasting of earthquake and seventh relating to precision forecasting of rain content for particular cloud condition are challenging areas for the young researchers in India.
My greetings to all the students and faculty of IIT, Karagpur. My best wishes to all of you in your mission of promoting scientific discoveries, technological inventions and innovations for societal transformation.
May God bless you.
Dr. A. P. J. Abdul Kalam