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Centre for Astroparticle Physics and Space Sciences – A National Facility at Bose Institute

Centre for Astroparticle Physics and Space Sciences – A National Facility at Bose Institute ( A project under IRHPA Scheme ) Sibaji Raha Bose Institute Kolkata. Acharya J.C. Bose (1858 – 1937).

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Centre for Astroparticle Physics and Space Sciences – A National Facility at Bose Institute

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  1. Centre for Astroparticle Physics and Space Sciences – A National Facility at Bose Institute (A project under IRHPA Scheme) Sibaji Raha Bose Institute Kolkata

  2. Acharya J.C. Bose (1858 – 1937)

  3. “Thus the lines of physics, of physiology and psychology converge and meet. And here will assemble those who would seek oneness amidst the manifold”– Acharya J.C.Bose

  4. Genesis & Mission • Drawn by Nationalist zeal, Missionary vision, Faith in the ability of Indians Not merely a laboratory but a temple • 1896 – visit to Royal Institution, London Took firm roots of the Idea • 1915 – Retirement from Education Service • 1917 – Bose Institute was Founded

  5. “And in this country through millenniums, there always have been some who, beyond the immediate and absorbing prize of the hour, sought for the realization of the highest ideal of life – not through passive renunciation, but through active struggle”

  6. “The advancement of science is the principal object of the Institute, andalso the diffusion of knowledge”

  7. “ In this institute…the claim of art has not been forgotten, for the artist has been working with us, from foundation to pinnacle and from floor to ceiling of this very hall….

  8. “And beyond the arch, the laboratory merges imperceptibly into the garden which is true laboratory for the study of life. There the creepers, the plants and trees are played upon by natural environment, sunlight and wind… and where they will be subjected to chromatic action of different lights, to invisible rays, to electrified ground or thunder-charged atmosphere.”

  9. “India is drawn into the vortex of international competition. She has to become efficient in every way – through spread of education, through performance of civic duties and responsibilities, through activities both industrial and commercial. Neglect of these essentials of national duty will imperil her very existence.”– Acharya J.C.Bose

  10. Origin • In-house expertise : Need for consolidation • Darjeeling Campus : Location & Opportunities (a) Cosmic Ray (b) Atmospheric Chemistry (c) Radiometric studies

  11. Four major programmes 1. Cosmic ray studies at high altitude 2. Changing airspace environment in Eastern Himalayas 3. Children’s science resource centre 4. Manpower development – training programmes

  12. Cosmic Ray studies

  13. Electrons – electric cherge - EM force – Photon Quarks - Colour Charge - Strong force – Gluon

  14. Quark – three colours - Red , Blue , Green Gluons – eight - red + anti-blue and other combinations Mesons – quark+antiquark – colour+anticolour – WHITE Baryons – three quarks – red+blue+green - WHITE

  15. H- matter  P.T.  Q – matter SQM  Ground state of matter First idea : Bodmer (1971) Resurrected : Witten (1984) Stable SQM : Conflict with experience ???? 2-flavour energy > 3-flavour Lowering due to extra Fermi well Stable QM  3-flavour matter Stable SQM  significant amount s quarks For nuclei  high order of weak interaction to convert u & d to s

  16. SQM & Strangelet Search : • SQM : • Early universe quark-hadron phase transition • Quark nugget  MACHO • 2. Compact stars (Core of Neutron Stars or Quark Stars) • Strangelets : • Heavy Ion Collision • Short time • Much smaller size A ~ 10-20 • Stability Problem at high temperature • 2. Cosmic Ray events : • Collision of Strange stars or other strange objects Shower

  17. Detection of strangelets  Propagation mechanism of strangelets  How far can it travel through atmosphere  How does it interact with atmosphere ? Important observations  Stability of strange matter  Small positive charge  massive s quark  Z/A  1

  18. Remarks :  Detection of strangelets : Passive detectors  Active detectors : Air shower studies in collaboration

  19. Study of Changing airspace environment in Eastern Himalayas

  20. Indo-Gangetic plane :  Agricultural as well as Industrial activity  Source of atmospheric pollutants  Vulnerable place from changing environment • Himalaya is subject to (a) emissions from IGP regions (b) pollutants transported from long distances • Himalaya : Unique place to monitor airspace environment

  21. Eastern Himalaya : wet with rich forest cover and lesser population Western Himalaya : dry, scanty forest cover and high population Monitoring stations : Mostly in western Himalaya

  22. Eastern Himalaya Monitoring stations Pyramid Station 5034 meters Sandakphu 4200 meters Kathmandu ICIMOD-UCSD Station Darjeeling 2500 meters North Bengal University, Siliguri

  23. Physical Environment Chemical Environment Monitoring of trans-boundary pollutants H2O: mm waves O3, CO, NOx, SO2: Trace Species Aerosols: Scattering/ Absorbing Met Data 3-D Trajectories Eastern Himalayas 23.8 GHz (Water Vapour) 31.4 GHz (Liquid Water) Distrometers (DSD) Radio Environment Emission Inventories Air Pollutant Dispersal 3-D Chemical Modeling Chemical, Physical, and Radio Mapping of the region

  24. Project II-AI (IITM) Atmospheric Chemistry-Aerosol-Climate Interaction • Objectives* To monitor physical, chemical and optical characteristics of aerosols under different air mass situations * To investigate the role of radiative forcing of aerosols in the climate system using experimental observations and model computations* To assess the influence of terrain / meteorological conditions on aerosol parameters

  25. Project II-AII (NPL) Chemical behaviour of aerosols, greenhouse gases, trajectory analysis and impact of particulate matter loading on human health • Objectives* To monitor greenhouse gases and pollutants for understanding trans-boundary flow * To investigate the chemical characteristics of aerosols and back trajectory analysis for source apportionment* To assess the impacts of particulate matter loading on human health

  26. Expected outcome • Mass-size distribution of aerosols • Monthly, seasonal and diurnal variation of aerosol, trace and green house gas, partulate matter concentrations • Influence of meteorological parameters on air pollutants • Chemical composition of precipitation and aerosols • Impacts of aerosol loading on atmospheric radiative forcing • Trans-boundary flow of pollutants • Impact of pollutants on regional climate • Relation between atmospheric pollution loading and human health hazards

  27. Various measurements, as mentioned below, will be undertaken. Continuous monitoring will take place at the Darjeeling site and measurements at Siliguri and Sandakphu will be made in campaign mode. These measurements at varying altitudes will provide some information about height profiles. • Atmospheric surface ozone • Columnar ozone (indirect) • Radiation measurements including UV radiation • Trace and Green House gases (NO2, SO2, NOx, SOx, CO, CO2, CH4 and N2O) • Physical and chemical characteristics of Aerosols (Scattering/absorbing) including carbonaceous aerosols • Precipitation chemistry • Biogenic organic particulate matter • Meteorological Parameters

  28. Project II-B STUDIES ON ATMOSPHERIC WATER VAPOUR AND CLOUD LIQUID WATER USING DUAL FREQUENCY RADIOMETER AND RELATED RAIN/FOG ENVIRONMENT AT THE HIGH ALTITUDE STATION AT DARJEELING

  29. IWV and LWP with a dual-frequency radiometer operating at 23.8 and 31.4 GHz. • Rain attenuation over earth-space paths by receiving satellite signals at Ku/Ka bands. • Rain rate with an optical rain-gauge • Rain drop size distribution with a Disdrometer. The following studies are proposed with the above-mentioned experimental measurements: • Variation of atmospheric water vapour, cloud liquid water content with time season, season, and their relationship with surface weather parameters, such as, temperature, relative humidity etc. • Modelling of cloud liquid water content and comparison of the derived model with the available global models. • To indicate the inter-relationship between IWP and LWP • To relate the rain attenuation over earth-space paths with the rain rate at the receiving site of satellite signal that will give an integrated picture of rain rate over the satellite path. • To relate rain DSD with radiometric observations during rain. Also, rain DSD will provide liquid water content in rain, which may be related with IWV and LWP. These integrated measurements will be used to study the interrelation among cloud liquid water, water vapour and rain at Darjeeling

  30. Children’s Science Resource Centre

  31. 1. Formation of science clubs in schools 2. Train them to record local meteorological data 3. Once in a month meeting, recording of data taken by students in the central data base 4. Train some of the interested students for cosmic ray experiments 5. Introductory level lectures by scientists

  32. Manpower development

  33. Workshops and summer schools on various aspects of the : cosmic ray physics Instrumentation Environmental science Weather modeling studies Numerical simulation with hands-on training Aimed at : Masters level and beginning doctoral students

  34. Thank You

  35. Cosmic rays Cosmic rays are high energy charged particles, originating in outer space, that travel at nearly the speed of light and strike the Earth from all directions. Cosmic ray ions at the top of the energy range produce in the atmosphere showers of many millions of fragments, covering many acres, and their more energetic fragments register even in deep mines, a mile underground. back

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