Model-based remote sensing algorithms for particulate organic carbon (POC) in the Northeastern Gulf of Mexico
Young Baek Son1,2,∗, Wilford D Gardner1, Alexey V Mishonov3
and Mary Jo Richardson2
1Department of Fisheries, Nagasaki University, 1-14 Bunkyo, Nagasaki, Nagasaki 852-8521, Japan.
2Department of Oceanography, Texas A&M University, College Station, Texas 77843-3146, USA.
3National Oceanographic Data Center, 1315 East West Highway, Silver Spring, MD 20910-3282, USA.
∗e-mail: sonyb@nagasaki-u.ac.jp

Abstract: Hydrographic data, including particulate organic carbon (POC) from the Northeastern Gulf of Mexico (NEGOM) study, were combined with remotely-sensed SeaWiFS data to estimate POC concentration using principal component analysis (PCA). The spectral radiance was extracted at each NEGOM station, digitized, and averaged. The mean value and spurious trends were removed from each spectrum. De-trended data included six wavelengths at 58 stations. The correlation between the weighting factors of the first six eigenvectors and POC concentration were applied using multiple linear regression. PCA algorithms based on the first three, four, and five modes accounted for 90, 95, and 98% of total variance and yielded significant correlations with POC with R2 = 0.89, 0.92, and 0.93. These full waveband approaches provided robust estimates of POC in various water types. Three different analyses (root mean square error, mean ratio and standard deviation) showed similar error estimates, and suggest that spectral variations in the modes defined by just the first four characteristic vectors are closely correlated with POC concentration, resulting in only negligible loss of spectral information from additional modes. The use of POC algorithms greatly increases the spatial and temporal resolution for interpreting POC cycling and can be extrapolated throughout and perhaps beyond the area of shipboard sampling.



Atmospheric phenomena deduced from radiosonde and GPS occultation measurements for various application related studies
C J Johny1,∗, S K Sarkar1,∗∗ and D Punyasesudu2,†
1Radio & Atmospheric Sciences Division, National Physical Laboratory,
Dr. K S Krishnan Marg, New Delhi 110 012, India.
2Department of Physics, Post Graduate Study Centre, Sri Krishnadevaraya University,
Kurnool 518 002, A.P., India.
∗e-mail: johnycj@rediffmail.com
∗∗e-mail: sksarkar@mail.nplindia.ernet.in
†e-mail: dupadu@rediffmail.com

Abstract: The tropopause height and tropopause temperature are sensitive to temperature changes in troposphere and stratosphere. These are the measures of global climatic variability. Atmospheric profiles of temperature, refractivity and water vapour are always needed for communication, navigation and atmospheric modeling studies. The tropopause characteristics over the Indian region have been studied using radio occultation measurements (CHAMP) on the basis of cold point criterion. Tropopause height shows large variation in the latitude range ∼30–40◦N during winter. Tropopause temperature less than −82◦C, assumed to facilitate troposphere to stratosphere air transport, is observed at a number of tropical Indian locations and no seasonal pattern is observed in its occurrence. The bias in temperature and refractivity deduced from radiosonde and radio occultation measurements is also presented.


Western disturbances seen with AMSU-B and infrared sensors
Dileep M Puranik∗ and R N Karekar
Department of Atmospheric and Space Sciences, University of Pune, Pune 411 007, India.
∗e-mail: dileepmp@unipune.ernet.in

Abstract: Western disturbances (WD) of winter and pre-monsoon seasons are the important sources of rainfall in the Indo-Gangetic plains. WDs are troughs or circulations in the westerly winds modified by the Himalayas. Operationally, WDs are monitored using infrared (IR) and water vapour (WV) images. Advanced Microwave Sounding Unit-B (AMSU-B), flying onboard the NOAA satellites, also allows WDs to be monitored in five microwave frequencies. Two are in water vapour window (89, 150 GHz) and three are absorption channels (centred at 183.31 GHz). Unlike the top of cloud view in IR or WV, AMSU-B radiances show the effect of moisture and hydrometeors in different layers. Two cases of WD (17 April 2001 and 18–19 February 2003) are discussed using the microwave data from AMSU-B and the IR and WV data from Meteosat-5. The aim here is to demonstrate the skill of AMSU-B in delineating structure of WDs. In particular, the cold intrusion and the moist conveyor belts are examined. It was found that the multi-channel view of the AMSU-B permits a better understanding of the moist structures seen in the conveyor belts. The `a trous wavelet transform is used to clearly bring out mesoscale features in WDs. AMSU-B brings out intense convection as a large depression of BTs (>50K) at 150/176 GHz, cirrus and moist bands at 180/182 GHz.  Mesoscale convection lines within WDs that last short time are shown here for the first time only in the AMSU-B images. Large-scale cirrus features are separated using the `a trous wavelet transform. Lastly, it is shown that there is a good likeness in the rain contours in the 3-h rain 3B42 (computed from TRMM and other data) to AMSU-B depressions in BT. Overall, AMSU-B shows better skill in delineating the structure of clouds and rain in WDs.
   

Aerosol optical depths at Mohal-Kullu in the northwestern Indian Himalayan high altitude station during ICARB
Jagdish C Kuniyal1,∗, Alpana Thakur1, Harinder K Thakur1, Sanjeev Sharma1,
P Pant2, Pan S Rawat3 and K Krishna Moorthy4
1G.B. Pant Institute of Himalayan Environment and Development, Himachal Unit, Mohal-Kullu 175 126, India.
2Aryabhatta Research Institute of Observational Sciences, Manora Peak, Nainital 263 002, India.
3Department of Physics, D.S.B. Campus, Kumaun University, Nainital, Uttarakhand, India.
4Space Physics Laboratory, Vikram Sarabhai Space Centre, Thiruvananthapuram 659 022, India.
∗e-mail: kuniyaljc@yahoo.com

Abstract: First time observations of spectral aerosol optical depths (AODs) at Mohal (31.9◦N, 77.11◦E; altitude 1154m amsl) in the Kullu valley, located in the northwestern Indian Himalayan region, have been carried out during Integrated Campaign for Aerosols, gases and Radiation Budget (ICARB), as a part of the Indian Space Research Organisation–Geosphere Biosphere Program (ISRO–GBP). AODs at six wavelengths are obtained using Microtops-II Sunphotometer and Ozonometer. The monthly mean values of AOD at 500 nm are found to be 0.27 ± 0.04 and 0.24 ± 0.02 during March and April, 2006 respectively. However, their monthly mean values are 0.33 ± 0.04 at 380 nm and 0.20 ± 0.03 nm at 870 nm during March 2006 and 0.31 ± 0.3 at 380 nm and 0.17 ± 0.2 at 870 nm during April 2006, showing a gradual decrease in AOD with wavelength. The ˚Angstrom wavelength exponent ‘α’ had a mean value of 0.72 ± 0.05, implying reduced dominance of fine particles. Further, the afternoon AOD values are higher as compared to forenoon values by ∼ 33.0% during March and by ∼ 9.0% during April 2006 and are attributed to the pollutant lifted up from the valley by the evolving boundary layer. Besides the long-range transportation of aerosol particles by airmass from the Great Sahara and the Thar Desert regions to the observing site, the high values of AODs have also been influenced by biomass burning and frequent incidents of forest fire at local levels.


On the influence of spatial heterogeneity on an internal boundary layer at a short fetch
B S Murthy1,∗, R Latha1, Cini Sukumaran1, A Shivaji2 and S Sivaramakrishnan1
1Indian Institute of Tropical Meteorology, Dr Homi Bhabha Road, NCL Post, Pune 411 008, India.
2National Centre for Antarctic and Ocean Research, Vasco-Da-Gama, Goa, India.
∗e-mail: murthy@tropmet.res.in

Abstract: Surface layer meteorological data collected at a coastal site, at Vasco-Da-Gama (15◦21N, 73◦51E, 58.5m MSL) (13–18 July, 2002) with prevailing southwesterly surface winds are analyzed to study the characteristics of internal boundary layer at a short fetch using an instrumented tower (9 m). The spectral and turbulence characteristics of wind are compared with earlier measurements made at a comparatively homogeneous terrain and the standards available in literature. The study show  the smaller eddies in the vertical velocity spectrum attains equilibrium with the underlying surface at a short fetch itself and follows spectral similarity. However, this is not followed by longitudinal and transverse velocity spectra under unstable as well as stable conditions.


Assessment of di fferent topographic corrections in AWiFS satellite imagery of Himalaya terrain
V DMishra 1 ∗, J K Sharma 2 ,K K Singh 1 , N K Thakur 1 and M Kumar 1
1 Snow and Avalanche Study Establishment,Defence Research and Development Organisation,
Chandigarh 160 036,India.
2 Rayat Institute of Engineering &Information Technology,Nawanshahr,Punjab 144 533,India.
∗e-mail:vd −mishra@redi ffmail.com

Abstract: The in fluence of topographic e ffects in optical satellite imagery is not investigated very extensively in the Himalayan terrain.The topographic variability causes a problem of di fferential illumination due to steep and varying slopes in rugged Himalayan terrain.Therefore,topographic corrections are essential for qualitative and quantitative analysis of snow cover applications.The present paper discusses the implementation of di fferent topographic correction models on AWiFS sensor onboard IRS P6 satellite images and the qualitative and quantitative comparative analysis in detail.Both the Lambertian and non-Lambertian assumptions have been considered in the present analysis with the aim to explore best suitable empirical model for rugged terrain.The main topographic methods implemented are:

•C-correction
•Minneart corrections
•Civco ’s modi fied version of cosine correction
•two-stage normalization and
•slope matching technique.

Lambertian assumptions are found to be very unrealistic over Himalayan terrain as these lead to either underestimation or overestimation of physical parameters signi ficantly both on sunlit slopes as well as the slopes away from the Sun.This problem is overcome by considering non-Lambertian assumption.Minneart constant and C-correction coe fficients for all AWiFS satellite bands are estimated using regression analysis.All the results due to topographic e ffects are investigated qualitatively and quantitatively using four criteria namely visual analysis,validation with field measurements (in-situ observations),spectral re flectance of training samples of snow on the south and north aspects and graphically.The visual analysis con firms the minimization of three dimensional relief e ffects in two-stage normalization and slope matching methods and retrieves some of  the information under mountain shadow.Due to the very bright surface of snow fields there is likely to be more di ffuse re flected light in these areas than over darker vegetated surfaces.The qualitative analysis in other methods does not extract any information on shady slopes.The quantitative validation of topographic results in satellite imagery with in-situ observations shows underestimation of spectral re flectance of snow signi ficantly except for slope matching technique. It is also apparent that although all the topographic methods correct the re flectance of training snow samples on the south and north aspects but most acceptable values are achieved using slope matching.The results obtained from graphical analysis reveal that mean re flectance after all topo- graphic corrections are  independent of illumination.This study also suggests that the suitability of topographic models can not be concluded as successful based on single criterion.Slope matching technique is the only technique which satis fies all the four criteria successfully and produces the best result for Himalayan terrain.


Shear wave splitting in the Isparta Angle, southwestern Turkey: Anisotropic complexity in the mantle
Aslıhan S¸apas ¸and Aysun Boztepe–G¨ uney
Department of Geophysical Engineering, Faculty of Mines, ˙I stanbul Technical
University of ˙I stanbul 34390, Maslak, Turkey.
∗e-mail: sapasa@itu.edu.tr

Abstract: This study presents shear wave splitting analysis results observed at ISP (Isparta)broadband station in the Isparta Angle,southwestern Turkey.We selected 21 good quality seismic events out of nearly 357 earthquakes and calculated splitting parameters (polarization direction of fast wave,φ and delay time between fast and slow waves,δt )from mainly SKS and a few SKKS phases of the selected 21 seismic events.Then,we compared calculated splitting parameters at ISP station (56 ◦≤φ ≤205 ◦;0 .37 s ≤δt ≤4 s)with those previously calculated at ANTO (Ankara) and ISK (˙Istanbul)stations (27 ◦≤φ ≤59 ◦;0 .6s ≤δt ≤2 .4sand26 ◦≤φ ≤54 ◦;0 .6s ≤δt ≤1 .5s) which are located at 230 and 379 km away from ISP station in central and northwestern Turkey, respectively.The backazimuthal variations of the splitting parameters at ISP station indicate a di fferent and complex mantle polarization anisotropy for the Isparta Angle in southwestern Turkey compared to those obtained for Ankara and ˙Istanbul stations.


Magnetic anomalies across Bastar craton and Pranhita–Godavari basin in south of central India
I V Radhakrishna Murthy* and S Bangaru Babu
Department of Geophysics, Andhra University, Visakhapatnam 530 003, India.
∗e-mail: ivr −murthy@yahoo.com

Abstract: Aeromagnetic anomalies over Bastar craton and Pranhita –Godavari (P –G)basin in the south of  central India could be attributed to NW –SE striking ma fic intrusives in both the areas at variable depths.Such intrusions can be explained considering the collision of the Bastar and Dharwar cratons by the end of the Archaean and the development of tensile regimes that followed in the Paleoproterozoic,facilitating intrusions of ma fic dykes into the continental crust.The P –G basin  area,being a zone of crustal weakness along the contact of the Bastar and Dharwar cratons, also experienced extensional tectonics.The inferred remanent magnetization of these dykes dips upwards and it is such that the dykes are oriented towards the east of the magnetic north at the time of their formation compared to their present NW –SE strike.Assuming that there was no imprint of magnetization of a later date,it is concluded that the Indian plate was located in the southern hemisphere,either independently or as part of a supercontinent,for some span of time during Paleoproterozoic and was involved in complex path of movement and rotation subsequently.  The paper presents a case study of the utility of aeromagnetic anomalies in qualitatively deducing the palaeopositions of the landmasses from the interpreted remanent magnetism of buried intrusive bodies.


Calculation of the CIPW norm: New formulas
Kamal L Pruseth
Institute Instrumentation Centre, Indian Institute of Technology Roorkee, Roorkee 247 667, India.

Abstract: A completely new set of formulas,based on matrix algebra,has been suggested for the calculation of  the CIPW norm for igneous rocks to achieve highly consistent and accurate norms.The suggested sequence of derivation of the normative minerals greatly deviates from the sequence followed in the classical scheme.The formulas are presented in a form convenient for error-free implementation in computer programs.Accurate formulas along with the use of variable molecular weights for CaO and FeO;corrected formula weights for apatite,pyrite and fluorite;and suggested measures to avoid signi ficant rounding o fferrors to achieve absolute match between the sum of the input weights of the oxides and the sum of the weights of the estimated normative minerals.Using an analogous procedure for determining the oxidation ratios of igneous rocks as used in the SINCLAS system of Ver ma et al (2002,2003),the suggested calculation scheme exactly reproduces their results except for apatite for reasons explained in the text,but with a superior match between the totals for about 11,200 analyses representing rocks of a wide range of composition.


Trace fossils from Talchir carbonate concretions, Giridih basin, Jharkhand
S S Das* and Mahesh Kumar Tripathi
Department of Earth and Planetary Sciences, Nehru Science Centre, University of Allahabad,
Allahabad 211 002, India.
∗e-mail: siddharthasankar −das@yahoo.co.in

Abstract: The carbonate concretions occurring at the bottom of Talchir fissile shale facies preserved signatures of various trace fossils along with a cast of doubtful organisms and cyanobacterial mat structures. The host shale deposited under glacial melt water fed lacustrine condition.The concretions,formed in poorly oxygenated conditions,are either of syndepositional origin and/or deposited a little below the sediment water interface and were later exhumed to the depositional surface due to erosion of soft mud overlying them.
The trace fossils are both megascopic and microscopic in nature.The megascopic trace fossils are identi fied on the basis of their morphology as Monocraterion and Rhizocorallium Some of the megascopic structures described remain problematic at present.The microscopic trace fossils are formed due to the activity of marine meiofauna (possibly by nematodes),which,although produced morphologically show similar traces of known larger ichnogeneras but much smaller than them. The discovery of these trace fossils apparently indicate the in flux of saline water into a lacustrine domain during the Talchir sedimentation at Giridih basin.Moreover, presence of the above two megascopic trace fossils in the marine lacustrine carbonate concretions may lead researchers to consider their much wider environmental signi ficance than hitherto believed.