Weather Scenario of 3rd & 4th Sept 2009 at Narasingarao Bay Visakhapatnam

trusciencetrutechnology@blogspot.com
Vol.2009, Issue No.9. Dt.Monday, 07 September 20091:39:26 PM
The 3rd and 4th September 2009 weather Scenario at Visakhapatnam in Andhra Pradesh, India.
By Professor Kotcherlakota Lakshmi Narayana
(Retd. Prof. of Physics, SU) 17-11-10 Narasimha Ashram, Official Colony, Maharanipeta.P.O. Visakhapatnam-530002.

ABSTRACT:
The 3rd and 4th September 2009 weather scenario at the Narasingarao Bay region of coast of Visakhapatnam-530002 and the Srisailam hilly track regions of the Chitoor District region has been one of a puzzling character. While the coast experienced warm to very warm weather with dazzling bright sunlit days the Srisailam region near pavuralagutta (ht.400-500m) has experienced heavy rain with dark, dense and thick clouds. This paper tried to analyse the two different situations from purely a physical point of view and offers the explanation of dust metallic and other ash-like material deposited in the sky due to the Earth Quake of the 3rd September 2009 in the Indonesian Java area. While the Earth Quake power was felt nearly 700km away to the East justifies the model consideration that the particulate ejection had a tremendous upsurge.
Keywords: Weather, Visakhapatnam, Java earth quake, metallic material, lighter material, Srisailam, Pavuralagutta, Narasingarao Bay, Sun spot 1025, Coronal Hole.

INTRODUCTION:
The 3rd and 4th Sept.2009 Visakhapatnam coastal town region of Narasingarao Bay experienced a very warm to warm weather the full two days.[ The latitude is 17deg 42m 9” N and longitude is 83deg 22mins 30” E at Dabagardens of Visakhapatnam as per the ancient astronomy observatory records.] This is surprising since the Bay of Bengal conditions were very conducive to the formation of a Low pressure trough, somewhat unusual for this time of season of Monsoon weather in India. The weather has been one of a very complex nature since just a few hours ago on the 3rd Sept.2009 a Sun Spot No.1025 has occurred and soon disappeared. This has been followed by a Coronal Hole creation on the 3rd Sept.2009. Coronal holes are known to have extended magnetic lines of force that descend down to the Earth’s magnetosphere and create reconnection scenario. These lines of force offer an excellent path way for the ejected charged particles to enter the Earth’s atmosphere. They spiral down to the Earth’s magnetosphere. The interaction between energetic Solar originated particles and the Earth’s magnetosphere particles would eventually interact giving raise to tremendous inputs of energetic other secondary particles into the Earth’s atmosphere. Moreover the disappearance of the Sun spot shouldn’t be taken to mean that its’ effects are not feeble. It must have pushed into the solar surface region very heavy metallic particulates that overburdened the magnetic lines of force of the Sun Spot No.1025 to collapse and as a result this particulate matter got ejected or caught up with the formation of a Coronal Hole. Many photos of the sky were made by the present author to study the occultation and conjunction of the Moon and the planet Jupiter during the days of August 30th, 2009 to to-date. Earth Quake in Shillong Sept 4th ,2009 of 5.9R NE region of early Friday with epicentre at Myanmar-India border, might have also contributed to the weather scenario of Coastal Andhra Pradesh.

PRESENT MODEL:
This article offers a model of particulate matter deposition into the region of Srisailam and the Coastal Andhra Pradesh due to the Earth Quake of Indonesia, Java that occurred on the 3rd Sept.2009. Two kinds of material has been skyward ejected that travelled a parabolic path of trajectories that landed them on to the upper reaches of the terrestrial atmosphere of Andhra Pradesh.
The set of heavier material ejected by the Earth Quake of Indonesia contained several heavier metallic entities. As a result the Sun’s solar radiation already affluent with X-ray emissions from the faded Sun Spot No.1025 has produced dazzling bright Sun Light at the coastal Andhra Pradesh of Visakhapatnam. People on these days felt the extreme heat of the Sun.
The other set of material that is apparently a lighter one got deposited in the Srisailam region while the other got deposited on to the Coastal Visakhapatnam upper reaches of atmosphere at a height of anywhere from 90kms to 400km. As a result the lighter material at Srisailam helped to nucleate moisture masses into dense, thick and black water laden heavy clouds. It is easy to surmise that the thickness of these clouds in the vertical direction was of the order of 600-800feet [2]. That’s very unusual and it happened very fast in spite that the West Godavari District was experiencing incessant heavy rain for a couple of the previous days.

PAST HISTORY:
An unprecedented Mega Solar Geo-magnetic Storm occurred on the 2nd September 1859 year as reported by SpaceWeather.com. It released a billion-ton coronal mass ejection that slammed in to Earth’s atmosphere. The glow was so intense people thought it was sunrise time. People in Cuba were able to read Newspapers in the red illumination of aurora borealis. Earth was peppered by particulate matter.

CONCLUSION:
This hints at a possible justification for the Model considerations presented by me.

ACKNOWLEDGMENT:
I have been greatly benefited by my association with the researchers at the laboratories of (Late) Professor K. Rangadhama Rao D.Sc.(Madras). D.Sc. (London), under his guidance and constant encouragement in Andhra University, JVD College of Science & Technology, Visakhapatnam-530003.

REFERENCES:
1. trusciencetrutechnology@blogspot.com Vol.2009, No.9, Dt.1st September 2009-09-01, The Moon and the Bright Planet Jupiter moons Fractal Airglows Honeymoon in the Sky 2nd - 3rd September 2009 By Professor Kotcherlakota Lakshmi Narayana.(Blog posted on 7th Sept.2009).Full text of the paper with 38 photos is available at request to the author on the basis of academic collaboration.
2. Local Newspapers details regarding a helicopter crash at Pavuralagutta
3. See also the references contained in the reference 1 above.