Optical properties of tropospheric aerosols derived from lidar and sun photometer measurements at ALOMAR (69N) in 2005 and 2006

  1. Rodríguez, Edit. 2
  2. Frioud, Max 1
  3. Gausa, Michael 1
  4. Stebel, Kerstin 3
  5. Mogo, Sandra 24
  6. Prats, Natalia 2
  7. Torres, Benjamín 2
  8. Toledano, Carlos 5
  9. Bastidas, Álvaro
  10. Berjón, Alberto 2
  11. Cachorro, Victoria 2
  12. de Frutos, Ángel M. 2
  1. 1 Artic Lidar Observatory for Middle Atmospheric Research
  2. 2 Universidad de Valladolid
    info

    Universidad de Valladolid

    Valladolid, España

    ROR https://ror.org/01fvbaw18

  3. 3 Norwegian Institute for Air Research
    info

    Norwegian Institute for Air Research

    Lillestrøm, Noruega

    ROR https://ror.org/00q7d9z06

  4. 4 Universidade da Beira Interior
    info

    Universidade da Beira Interior

    Covilhã, Portugal

    ROR https://ror.org/03nf36p02

  5. 5 University of Television and Film Munich
    info

    University of Television and Film Munich

    Múnich, Alemania

    ROR https://ror.org/01a7snz60

Journal:
Óptica pura y aplicada

ISSN: 2171-8814

Year of publication: 2008

Issue Title: IV Workshop LIDAR measur. in Latinamerica

Volume: 41

Issue: 2

Pages: 183-190

Type: Article

More publications in: Óptica pura y aplicada

Abstract

We report the results of Sub-Arctic aerosol properties, obtained during three field campaigns conducted in 2005 and 2006. These have been carried out at the Arctic Lidar Observatory for Middle Atmosphere Research (ALOMAR), Andøya Rocket Range, Norway (69N, 16E, 380 m asl), and were supported by the eARI (enhanced Access to Research Infrastructure) program of the European Union. The instruments used for this study are the ALOMAR tropospheric Lidar and a Cimel sun photometer. Data in situ from cascade impactors are also included to know the levels of total suspended particles and major ionic components during the measurement period in 2005. Back trajectory analysis is presented. The evolution of the vertical distribution of the aerosols is analyzed, in order to study aerosol stratification and height patterns for the long-range transported aerosols to this coastal Sub-Arctic site

Bibliographic References

  • C. Ritter, A. Kische, R. Neuber, "Tropospheric aerosol characterized by a Raman lidar over Spitsbergen", Reviewed and revised papers presented at the 22nd ILRC, 12-16 July 2004, Matera, Italy, ESA Publications Div., pp 459-462 (2004).
  • E. Landulfo, A. Papayannis, P. Artaxo, A. D. A. Castanho, A. Z. de Freitas, R. F. Souza, N. D. Vieira Jr, M. P. Jorge, O. R. Sánchez-Coyllo, D. S. Moreira, "Synergetic measurements of aerosols over São Paulo, Brazil using LIDAR, sunphotometer and satellite data during the dry season", Atm. Chem. Phys. 3, 1523-1539 (2003).
  • D. Müller, I. Mattis, U. Wandinger, A. Ansmann, D. Althausen, O. Dubovik, S. Eckhardt, A. Stohl, "Saharan dust over a Central European EARLINET-AERONET site: Combined observations with Raman lidar and sun photometer", J. Geophys. Res. 108, JD002918 (2003).
  • I. Veselovskii, D. N. Whiteman, O. Dubovik, A. Kolgotin, M. Korenskii, "Comparison of aerosol microphysical properties retrieved from multi-wavelength lidar and sun photometer", Reviewed and revised papers presented at the 23rd ILRC, 24-28 July 2006, Nara, Japan., pp 309-312 (2006).
  • C. Toledano, V. Cachorro, M. Sorbias, R. Vergaz, A. Berjón, A. De Frutos, M. Antón, M. Gausa, "Aerosol optical depth at ALOMAR observatory (Andøya, Norway) in summer 2002 and 2003", Tellus 58B, 218-228 (2006).
  • B. Holben, T. Eck, I. Slutsker, D. Tanr, J. Buis, A. Setzer, E. Vermote, J. Reagan, Y. Kaufman, "AERONET- a federated instrument network and data archive for aerosol characterization", Remote Sens. Environ. 66, 1-16 (1998).
  • B. Holben, D. Tanre, A. Smirnov, T. Eck, I. Slutsker, N. Abuhassan, W. Newcomb, J. Schafer, B. Chatenet, F. Lavenue, Y. Kaufman, J. Vande Castle, A. Setzer, B. Markham, D. Clark, R. Frouin, R. Halthore, A. Karnieli, N. O'Neill, C. Pietras, R. Pinker, K. Voss, G. Zibordi, "An emerging ground-based aerosol climatology: Aerosol optical depth from AERONET", J. Geophys. Res. 106, 12067-12097 (2001).
  • O. Dubovik, M. King, "A flexible inversion algorithm for retrieval of aerosol optical properties from sun and sky radiance measurements", J. Geophys. Res. 105D, 673-696 (2000).
  • A. Smimov, B. N. Holben, T. F. Eck, O. Dubovik, "Cloud-screening and quality control algorithms for the AERONET database", Remote Sens. Environ. 73, 337-349 (2000).
  • M. Frioud, M. Gausa, K. Stebel, G. Hansen, C. Myhre, W. Singer, R. Latteck, A. De Frutos, V. Cachorro, C. Toledano, E. Rodriguez, "Observation and characterization of aerosols above ALOMAR (69°N) by tropospheric lidar, sun-photometer, and VHF radar", Proc. SPIE 6367, 19-28 (2006).
  • D. Encinas, H. Casado, "Rain-aerosol coupling in an rural area in the Basque Country (Spain): Scavenging ratios", Aerosol Sci. Technol. 30, 411-419 (1999).
  • R. S. Parmar, G. S. Satsangi, K. M. Kumari, A. Lakhani, S. S. Srivastava, S. Prakash, "Study of size distribution of atmospheric aerosol at Agra", Atmos. Environ. 35, 693-702 (2001).
  • http://aeronet.gsfc.asa.gov
  • http://www-loa.univ-lille1.fr/photons/