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HYDROCARBONS PART 3 || SRO8981 ||SRO

I

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In this blog page we will discuss about Alkanes and Nomenclature and isomerism

ALKANES

→As already mentioned alkanes are saturated open chain hydrocarbons containing carbon - carbon single bonds.

→Methane (CH4) is the first member of this family. Methane is a gas found in coal mines and marshy places.

→ If you replace one hydrogen atom of methane by carbon and join the required number of hydrogens to satisfy the tetravalence of the other carbon atom, what do you get? You get C2H6.

→This hydrocarbon with molecular formula C2H6 is known as ethane.
Thus you can consider C2H6 as derived from CH4 by replacing one hydrogen atom by -CH3 group.

→ Go on constructing alkanes by doing this theoretical exercise i.e., replacing hydrogen atom by –CH3 group.

→ The next molecules will be C3H8, C4H10 …


→These hydrocarbons are inert under normal conditions as they do not react with acids, bases and other reagents.

→ Hence, they were earlier known as paraffins (latin : parum, little; affinis, affinity).
→ Can you think of the general formula for alkane family or homologous series?
→ If we examine the formula of different alkanes we find that the general formula for alkanes is CnH2n+2.

→It represents any particular homologue when n is given appropriate value. Can you recall the structure of methane? According to VSEPR methane has a tetrahedral structure (Fig. 13.1), in which carbon atom lies at the centre and the four hydrogen atoms lie at the four corners of a regular tetrahedron.

→All H-C-H bond angles are of 109.5°.



→In alkanes, tetrahedra are joined together in which C-C and C-H bond lengths are 154 pm and 112 pm respectively . You have already read that C–C and C–H σ bonds are formed by head-on overlapping of sp 3 hybrid orbitals of carbon and 1s orbitals of hydrogen atoms.

NOMENCLATURE AND ISOMERISM



→Nomenclature and isomerism in alkanes can further be understood with the help of a few more examples.

→Common names are given in parenthesis. First three alkanes – methane, ethane and propane have only one structure but higher alkanes can have more than one structure.

→Let us write structures for C4H10. Four carbon atoms of C4H10 can be joined either in a continuous chain or with a branched chain in the following two ways : Fig. 13.1 Structure of methane
→In how many ways, you can join five carbon atoms and twelve hydrogen atoms of C5H12? They can be arranged in three ways as shown in structures III–V
→Structures I and II possess same molecular formula but differ in their boiling points and other properties.

→Similarly structures III, IV and V possess the same molecular formula but have different properties.

Structures I and II are isomers of butane, whereas structures III, IV and V are isomers of pentane.

→Since difference in properties is due to difference in their structures, they are known as structural isomers. →It is also clear that structures I and III have continuous chain of carbon atoms but structures II, IV and V have a branched chain.

→Such structural isomers which differ in chain of carbon atoms are known aschain isomers.

→Thus, you have seen that C4H10 and C5H12 have two and three chain isomers respectively.

→Based upon the number of carbon atoms attached to a carbon atom, the carbon atom is termed as primary (1°), secondary (2°), tertiary (3°) or quaternary (4°).

Carbon atom attached to no other carbon atom as in methane or to only one carbon atom as in ethane is called primary carbon atom.

→Terminal carbon atoms are always primary. Based upon the number of carbon atoms.

→ Carbon atom attached to two carbon atoms is known as secondary.

Tertiary carbon is attached to three carbon atoms and neo or quaternary carbon is attached to four carbon atoms. →Can you identify 1°, 2°, 3° and 4° carbon atoms in structures I to V ?

→ If you go on constructing structures for higher alkanes, you will be getting still larger number of isomers.

→ C6H14 has got five isomers and C7H16 has nine.

→As many as 75 isomers are possible for C10H22. →In structures II, IV and V, you observed that –CH3 group is attached to carbon atom numbered as 2.

Thats all over

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HYDROCARBONS PART 2 || SRO||

Secret Research Organization SRO8981 SRO HYDROCARBONS Part:2 ||SRO ●If you not saw its part 1st then click on the link given below to see its 1st part. Click here( https://sro8981.blogspot.com/2020/05/hydrocarbo)



●So Guys In this blog page we will discuss about Classification Of Hydrocarbons.

CLASSIFICATION OF HYDROCARBONS

●Hydrocarbons are of different types. Depending upon the types of carbon-carbon bonds present, they can be classified into three main categories –
1.Saturated Hydrocarbons
They are the important sources of energy.

Saturated hydrocarbons contain carbon-carbon and carbon-hydrogen single bonds.

●If different carbon atoms are joined together to form open chain of carbon atoms with single bonds, they are termed as alkanes.

●On the other hand, if carbon atoms form a closed chain or a ring, they are termed as cycloalkanes.
2.Unsaturated Hydrocarbons
Unsaturated hydrocarbons contain carbon-carbon multiple bonds – double bonds, triple bonds or both.
3.Aromatic
Aromatic hydrocarbons are a special type of cyclic compounds.You can construct a large number of models of such molecules of both types(open chain and close chain)keeping in mind that carbon is tetravalent and hydrogen is monovalent. For making models of alkanes, you can use toothpicks for bonds and plasticine balls for atoms.

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Hydrocarbons || Part 1 || SRO

HYDROCARBONS Part:1 ||SRO Guys we are starting the new and big topic to discuss the topic is "hydrocarbons".This Topic is big and very important it is connected to our daily life.So We will share and discuss information about hydrocarbon in parts. It is The 1st part of this series. Here We Are Discuss how hydrocarbon are connected to our daily life. It is just introduction of hydrocarbon. ●The term ‘hydrocarbon’ is self-explanatory which means compounds of carbon and hydrogen only.

●Hydrocarbons play a key role in our daily life. You must be familiar with the terms ‘LPG’ and ‘CNG’ used as fuels.

●LPG is the abbreviated form of liquified petroleum gas whereas CNG stands for compressed natural gas. Another term ‘LNG’ (liquified natural gas) is also in news these days.

● This is also a fuel and is obtained by liquifaction of natural gas.

●Petrol, diesel and kerosene oil are obtained by the fractional distillation of petroleum found under the earth’s crust.

●Coal gas is obtained by the destructive distillation of coal.

●Natural gas is found in upper strata during drilling of oil wells.

●The gas after compression is known as compressed natural gas.

●LPG is used as a domestic fuel with the least pollution.

●Kerosene oil is also used as a domestic fuel but it causes some pollution.

●Automobiles need fuels like petrol, diesel and CNG. Petrol and CNG operated automobiles cause less pollution.

●All these fuels contain mixture of hydrocarbons, which are sources of energy.

●Hydrocarbons are also used for the manufacture of polymers like polythene, polypropene, polystyrene

.●Higher hydrocarbons are used as solvents for paints.

●They are also used as the starting materials for manufacture of many dyes and drugs.

● Thus, you can well understand the importance of hydrocarbons in your daily life.In this unit, you will learn more about hydrocarbons.

● Guys In Next Page Or Blog We Will Understand The Concept Of Classification Of Hydrocarbons.

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Development Of Chemistry In India

THE DEVELOPMENT OF CHEMISTRY IN INDIA

DEVELOPMENT OF CHEMISTRY IN INDIA


Chemistry, as we understand it today, is not a very old discipline. Chemistry was not studied for its own sake, rather it came up as a result of search for two interesting i. Philosopher’s stone (Paras) which would convert all baser metals e.g., iron and copper into gold.
ii.‘Elexir of life’ which would grant immortality.
People in ancient India, already had the knowledge of many scientific phenomenon much before the advent of modern science.
They applied that knowledge in various walks of life.
Chemistry developed mainly in the form of Alchemy and Iatrochemistry during 1300-1600 CE.
Modern chemistry took shape in the 18th century Europe, after a few centuries of alchemical traditions which were introduced in Europe by the Arabs.
Other cultures – especially the Chinese and the Indian – had their own alchemical traditions.
These included much knowledge of chemical processes and techniques. In ancient India, chemistry was called Rasayan Shastra, Rastantra, Ras Kriya or Rasvidya.
It included metallurgy, medicine, manufacture of cosmetics, glass, dyes, etc. Systematic excavations at Mohenjodaro in Sindh and Harappa in Punjab prove that the story of development of chemistry in India is very old.Archaeological findings show that baked bricks were used in construction work. It shows the mass production of pottery, which can be regarded as the earliest chemical process, in which materials were mixed, moulded and subjected to heat by using fire to achieve desirable qualities.
Remains of glazed pottery have been found in Mohenjodaro. Gypsum cement has been used in the construction work. It contains lime, sand and traces of CaCO3. Harappans made faience, a sort of glass which was used in ornaments.
They melted and forged a variety of objects from metals, such as lead, silver, gold and copper.
They improved the hardness of copper for making artefacts by using tin and arsenic.A number of glass objects were found in Maski in South India (1000–900 BCE), and Hastinapur and Taxila in North India (1000–200 BCE).
Glass and glazes were coloured by addition of colouring agents like metal oxides. Copper metallurgy in India dates back to the beginning of chalcolithic cultures in the subcontinent. There are much archeological evidences to support the view that technologies for extraction of copper and iron were developed indigenously.
According toRigveda,tanning of leather and dying of cotton were practised during 1000–400 BCE.
The golden gloss of the black polished ware of northen India could not be replicated and is still a chemical mystery. These wares indicate the mastery with which kiln temperatures could be controlled. Kautilya’s Arthashastra describes the production of salt from sea
A vast number of statements and material described in the ancient Vedic literature can be shown to agree with modern scientific findings. Copper utensils, iron, gold, silver ornaments and terracotta discs and painted grey pottery have been found in many archaeological sites in north India. Sushruta Samhita explains the importance of Alkalies. The Charaka Samhita mentions ancient indians who knew how to prepare sulphuric acid, nitric acid and oxides of copper, tin and zinc; the sulphates of copper, zinc and iron and the carbonates of lead and iron. Rasopanishada describes the preparation of gunpowder mixture. Tamil texts also describe the preparation of fireworks using sulphur, charcoal, saltpetre (i.e., potassium nitrate), mercury, camphor, etc. Nagarjuna was a great Indian scientist. He was a reputed chemist, an alchemist and a metallurgist. His work Rasratnakar deals with the formulation of mercury compounds. He has also discussed methods for the extraction of metals, like gold, silver, tin and copper. A book, Rsarnavam, appeared around 800 CE. It discusses the uses of various furnaces, ovens and crucibles for different purposes. It describes methods by which metals could be identified by flame colour. Chakrapani discovered mercury sulphide. The credit for inventing soap also goes to him. He used mustard oil and some alkalies as ingredients for making soap. Indians began making soaps in the 18th century CE. Oil of Eranda and seeds of Mahua plant and calcium carbonate were used for making soap. The paintings found on the walls of Ajanta and Ellora, which look fresh even after ages, testify to a high level of science achieved in ancient India. Varähmihir’s Brihat Samhita is a sort of encyclopaedia, which was composed in the sixth century CE. It informs about the preparation of glutinous material to be applied on walls and roofs of houses and temples. It was prepared entirely from extracts of various plants, fruits, seeds and barks, which were concentrated by boiling, and then, treated with various resins. It will be interesting to test such materials scientifically and assess them for use.
A number of classical texts, like Atharvaveda (1000 BCE) mention some dye stuff, the material used were turmeric, madder, sunflower, orpiment, cochineal and lac. Some other substances having tinting property were kamplcica, pattanga and Varähmihir’s Brihat Samhita gives references to perfumes and cosmetics. Recipes for hair dying were made from plants, like indigo and minerals like iron power, black iron or steel and acidic extracts of sour rice gruel. Gandhayukli describes recipes for making scents, mouth perfumes, bath powders, incense and talcum power. Paper was known to India in the 17th century as account of Chinese traveller I-tsing describes. Excavations at Taxila indicate that ink was used in India from the fourth century.
Colours of ink were made from chalk, red lead and minimum.
It seems that the process of fermentation was well-known to Indians Vedas and Kautilya’s Arthashastra mention about many types of liquors. Charaka Samhita also mentions ingredients, such as barks of plants, stem, flowers, leaves, woods, cereals, fruits and sugarcane for making Asavas
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बदल सकता है रक्षा क्षेत्र का परिदृश्य

                                  बदल सकता है रक्षा क्षेत्र का परिदृश्य





आज एक सवाल पूछा जा रहा है कि जब देश की अर्थव्यवस्था को पुनर्जीवित करने की जरूरत है, तो रक्षा क्षेत्र में प्रत्यक्ष विदेशी निवेश (एफडीआई) के नए नियमों की घोषणा की क्या जरूरत थी।
इसके दो कारण हैं। पहला, इससे देश पर कोई आर्थिक बोझ नहीं पड़ने वाला है। बल्कि यह रक्षा क्षेत्र के औद्योगिक परिसर के लिए अधिक धन ला सकता है, जहां सुधार की आवश्यकता है।
 और दूसरा यह कि ऐसा अवसर कम ही आता है, जब व्यापक आर्थिक पहल की जाए, और इस तरह अब यह करने का मौका था, इसलिए ऐसा किया गया है।

विज्ञापन भारत दुनिया के सबसे बड़े हथियार खरीदारों में से एक है, जिसके सशस्त्र बलों की जरूरत अगले दशक तक 200 अरब डॉलर से अधिक की है।
 इसने भारत को हथियार निर्यातकों का पसंदीदा बना दिया है, विशेष रूप से अमेरिका, फ्रांस और रूस की नजर में। और भारत अपनी इस क्रय क्षमता का उपयोग कर राजनयिक लाभ लेने में कभी हिचकिचाया नहीं है! हालांकि ताजा घोषणा के बाद इसमें बदलाव आ सकता है, जिसके तहत रक्षा विनिर्माण में एफडीआई की सीमा अब स्वतः 49 फीसदी से 74 फीसदी हो जाएगी और आयातित हथियारों की एक नकारात्मक सूची बनाने की जरूरत होगी।

 इससे प्रधानमंत्री की 'मेक इन इंडिया' पहल को बढ़ावा मिलेगा, जिसने रक्षा क्षेत्र में बहुत कम निवेश हासिल किया है और हथियारों के आयात का बिल कम होगा। भारत अत्याधुनिक रॉकेट और मिसाइलों का उत्पादन क्यों करता है, इसका कारण यह है कि भारत के रॉकेट वैज्ञानिकों को उन्नत देशों के रणनीतिक प्रतिबंधों के भीतर काम करना पड़ा है, ताकि यह सुनिश्चित किया जा सके कि कोई भी 'बड़ी लीग' में प्रवेश न कर सके।

 इसलिए भारत के वैज्ञानिकों ने उपग्रह प्रक्षेपण प्रणाली और मिसाइलों का उत्पादन किया है, जिसकी मांग अब दूसरे देशों द्वारा की जाती है।
हालांकि ये पी 5 देश अपनी हथियार प्रणाली को कुछ प्रतिबंधों के साथ बेचने से खुश थे।
इसलिए भारत के सशस्त्र बलों ने अक्सर महत्वपू्र्ण खरीद के रूप में विदेश से इस तर्क के साथ भारी हथियार खरीदे कि भारत के रक्षा क्षेत्र के सार्वजनिक उपक्रम (डीपीएसयू ) उनकी जरूरतों को पूरा करने में विफल रहे हैं।
और यदि निजी क्षेत्र ने गुणवत्तापूर्ण हथियार विकसित भी किए (जैसे भारत फोर्ज ने तोपखाने बनाए थे), तो उसे सैन्य एवं नौकशाही की मिलीभगत से साउथ ब्लॉक के गलियारे से बाहर ही रखा गया। इससे पहले 2016 में, मोदी सरकार ने उम्मीद की थी कि स्वचालित मार्ग से 49 प्रतिशत की संशोधित एफडीआई सीमा और खास मामले में 100 प्रतिशत तक रक्षा क्षेत्र में एफडीआई आएगी। लेकिन भारत को वर्ष 2017-18 में (10,000 डॉलर) 7,59,325 रुपये और 2018-19 में ( 21 लाख डॉलर) 16,55,32,850 रुपये मिले, जो नगण्य है।


 लेकिन अब यदि कंपनी के 74 फीसदी शेयर को विदेशी मूल उपकरण निर्माता नियंत्रित करेगा, तो उसे निवेश करने की इच्छा होगी, क्योंकि यह डीपीएसयू की 'सरकारी' कार्य संस्कृति को बदल सकता है, और इस प्रकार विश्व स्तरीय सैन्य प्रौद्योगिकी का उत्पादन होगा। कथित तौर पर इसी कारण राफेल लड़ाकू विमान के निर्माता डसॉल्ट एविएशन के साथ सौदा करने में इतनी देर लगी, क्योंकि उन्होंने एक भारतीय सार्वजनिक उपक्रम (एचएएल) को अपना भागीदार बनाने से इनकार कर दिया था।

भारत के अधिकांश बड़े व्यापारिक घराने (जिन्होंने बड़े संयंत्र और विनिर्माण आधार स्थापित किए हैं) डीपीएसयू और उनके नौकरशाहों से काफी निराश हैं, जिन्होंने यह सुनिश्चित किया है कि चीजें वैसी ही रहें, जैसी वे हैं। इसी के चलते रक्षा क्षेत्र के सार्वजनिक उपक्रमों में भारत एफडीआई हासिल करने में नाकाम रहा।

 नतीजतन इसने भारत में एक प्रभावी रक्षा विनिर्माण आधार के विकास को रोक दिया और रक्षा उत्पादन के क्षेत्र में निजी क्षेत्र को किनारे कर दिया। निर्णय लेने में देरी, 'तदर्थ' आदेशों को रखने, निविदाओं को रद्द करने और सशस्त्र बलों के अनुचित गुणात्मक जरूरतों के कारण रक्षा विनिर्माण क्षेत्र कुछ ही निश्चित कंपनियों के लिए रह गया।
 पर यदि नई पहल से विदेशी और भारतीय निवेशक आकर्षित होते हैं, तो लंबे समय से बाकी डीपीएसयूज का निगमीकरण होगा, न कि निजीकरण, जैसा कि उनके कर्मचारी संगठनों को डर है।

 यह हमारे निजी क्षेत्र को सशस्त्र बलों की फेहरिस्त को स्वदेशी बनाने का बराबरी का मौका देगा। इस समय तीनों सैन्य सेवाओं को बहुत से हथियारों की जरूरत है, जो देश की सुरक्षा जरूरतों के लिए आवश्यक हैं। अर्थव्यवस्था पर कोरोना संकट के प्रभावों के बावजूद इसकी अनदेखी नहीं की जा सकती, खासकर इसलिए कि चीन और पाकिस्तान मिलकर भारत को सीमा पर आतंकी खतरों से अस्थिर करना चाहते हैं।

दुनिया का कोई भी देश दो परमाणु संपन्न राष्ट्रों का सामना नहीं कर रहा है, जो न केवल भड़काने वाली कार्रवाई करते हैं, बल्कि जिनका उद्देश्य भारत के उदय को चुनौती देना है। हालांकि इस प्रक्रिया से उत्पादन करके सशस्त्र बलों की जरूरतों को पूरीकरने में कई साल लगेंगे।

 अतीत के अनुभव बताते हैं कि अर्जुन टैंक को बनाने में सोलह साल और तेजस के निर्माण में 30 साल लगे। और इस देरी का सारा दोष सशस्त्र बलों में नहीं मढ़ा जा सकता। हथियारों की परीक्षण प्रक्रिया बहुत लंबी होती है, जिसका जिक्र वित्त मंत्री ने एफडीआई के नियम में बदलाव की घोषणा करते हुए भी की। पर अब चीजें बदल सकती हैं। भारत को तत्काल अपनी रक्षा खरीद प्रक्रिया को सरल बनाने, भारतीय कंपनियों को पर्याप्त ऑर्डर देने और उत्पादन के लिए उचित समय देने की आवश्यकता है। लेकिन सबसे ज्यादा निर्णय लेने की प्रक्रिया को तेज करने की जरूरत है।

   इतना ही महत्वपूर्ण यह भी है कि डीपीएसयू और भारत के उद्योग को आश्वस्त खरीद ऑर्डर के साथ-साथ रक्षा उपकरणों पर स्पष्ट निर्यात नीति की आवश्यकता है, जिसका उत्पादन तो हुआ, लेकिन सशस्त्र बलों द्वारा उपयोग नहीं किया गया। भारत को उन रक्षा उपकरणों के निर्यात की जरूरत है, जो डीपीएसयू या निजी निर्माताओं द्वारा पहले से ही तैयार हैं। जब भारत स्वतंत्र हुआ, उसके एक वर्ष बाद इस्राइल राष्ट्र बना और अगर वह एक प्रमुख रक्षा निर्यातक बन सकता है, तो भारत एकाध दशक में क्यों नहीं बन सकता? ऐसा करने के लिए भारत के रक्षा उद्योग के पास दिमाग और इच्छा, दोनों है।
 केवल बाधाएं बहुत ज्यादा हैं। घरेलू प्रतिबंध के अलावा और कोई कारण नहीं है, जो भारत को ऐसा करने रोक सके। (लेखक सामरिक मामलों के विश्लेषक हैं।


ये इनफार्मेशन अमर उजाला से ली है । अगर आप को और भी ऐसी जानकारी चाहिए तो आप सब ये लिंक पर क्लिक कीजिए:~~~

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Robotics


ROBOTICS-THE FUTURE OF HUMANS

The robot revolution is a long-standing staple of science fiction, from Metropolis to The Terminator, and the spread of advanced machines in recent years has done little to contradict its seeming inevitably.
But Befro master and servant switch roles, the robot of the worlds need to conquer a simple task:efficiently recognizing a cat.
In 2014,it took some 16,000 computers running on a "neutral network" set up by Google to accomplish this feat something a toddler does by reflex.
The algorithms of determining "catness" are rapidly improving, but this distinction between thinking and calculating is a great divide that robotics engineers will need to branch before robots can truly replace humans.
A kid knows that all things with four legs,such as chairs, aren't cats.
IBM's Watson supercomputer triumphed on the quiz show Jeopardy in 2011, but it also thought Torconto was in the United States.

Robots Are increasingly moving into more corners of the world. One study Estimated That as many as 45% of jobs in United States would be eligible for robot replacement over the next 20 years.
Law Officers have already reduce the demand for paralegals because computer programs can now process legal briefs and synthesize large documents.
People have worried about being replaced by machines since the start of industrial Age .Although this has proved to be legitimate concern in many jobs, machines can also be a complement to human endeavor rather than a substitute for it.Machines and computers in general have amplified human strength through mechanized tools, augmented human intelligence Via information processing, and extended human reach via telecommunications and remote sensing.
But these robots couldn't operate autonomously. They needed instruction - a person to think up the processes and rules for each task and audit the outcome-just to be sure that the shipment form Amazon.com has a book about cats in the box , not one about woodworking or parakeets.
The online retailers is among the major adopters of robotics, and a major advocate for collaboration between human and machines.
At Amazon's massive product warehouse, fleets of heavy-lifting robots bring shelves of products to a packaging employee, so the employee doesn't have to spend time locating the correct product. The company expected to have 10,000 robots in use by the end of 2014.



Hospitals rely on robots for tasks that range from hauling laundry to assisting with delicate surgeries. The World'S first completely robotic surgery took place in 2010 at McGill University Health Center In Montreal, Canada, when a pair of robots called DaVinci (the surgeon) and the Mcsleepy (an anesthesia bot ) removed a patient's Patient's prostate .
A surgical team controlled DaVinci's arms via video control while observers in the room monitored the operation closely. Robotics allowed for greater steadiness and precision in handing the instructions than a human could achieve, but the operator still neede to decide where and when to cut or stirch-at least for now FAST FACT :--Researchers in Australia are building a microscopic robot that would move around in a manner similar to coli bacteria. The tiny machine could take a biopsy from inside the human body

GOING WHERE NO HUMANS CAN GO

Thousands of military and police robots have been deployed successfully to do work that is too dangerous for humans.Robots can clear away land mines in war zones, inspect suspicious packages on the city streets, and provide 3-D imaging of unstable buildings.
Real-life robots can scout potentially hostile environments and keep soldiers safe, like the packbot made by irobots , which to identify explosives, chemical weapons, and radioactive materials.
In March 2011 a tsunami devastated parts of japan and severly damaged reactors at the Fukushima Daiichi nuclear plant.The Radiation release resulted in the evacuation 3,00,000 people, and the development of cleanup plan that will span decades.In that unsafe environment, humans turned to robots for damage analysis, radiation monitoring, and debris removal.
FAST FACT :--One of the first robots was built in the 15th century B.C.by Archytas Of Tarentum.It was mechanical bird that could be powered by either steam or compressed air <

Robotics technologies consist of all processes necessary to design, build and maintain robots and other intelligent machines
. Robots are sophisticated, intelligent systems used to assist pilots and maneuver spacecraft without direct human intervention.

 What are robotics used for?

Robotics, design, construction, and use of machines (robots) to perform tasks done traditionally by human beings

Robotsare widely used in such industries as automobile manufacture to perform simple repetitive tasks, and in industries where work must be performed in environments hazardous to humans.


Why robotics is important in future?
Robotics is a fun way to bring STEM to life, and that's important because STEM is the key to a successful future for students with the interest and motivation to pursue careers in this field. ...
Clearly, there's a need to get students involved in STEM, and the earlier, the better.
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Nuclear Fusion


NUCLEAR FUSION

NUCLEAR FUSION

In nuclear fusion, We get energy when two atoms join together to form one.
In a fusion reactor, hydrogen come together to form helium atoms, neutrons and vast amounts of energy.
It's the same type of reaction that powers hydrogen bombs and the sun. Beryllium-6 decays into two helium-4 atoms.

Definition Of Nuclear Fusion Is-
It is a reaction in which two or more atomic nuclei are combined to form one or more different atomic nuclei and subatomic particles (neutrons or protons).
The difference in mass between the reactants and products is manifested as either the release or absorption of energy.


Steps Of Nuclear Fusion Are-

1.Two protons within the Sun fuse. Most of the time the pair breaks apart again, but sometimes one of the protons transforms into a neutron via the weak nuclear force. ...
2.A third proton collides with the formed deuterium.

3.Two helium-3 nuclei collide, creating a helium-4 nucleus plus two extra neutrons.

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Some Commonly Ask Questions And There Answers Are :-


Q1.Can fusion cause nuclear accident?
Ans:-No, Because Fusion Energy Production Is not Based On A Chain Reaction, As is fission.

Q2. Which country produces the most nuclear energy By Nuclear Fission ?
Ans:-The United States
The United States is the largest producer of nuclear power, while France has the largest share of electricity generated by nuclear power.

Q3. Why Nuclear fusion is difficult?
Ans:-On Earth it is very difficult to start nuclear fusion reactions that release more energy than is needed to start the reaction. The reason is that Fusion reactions only happen at high temperature(2 million° C), like in the Sun, because both nuclei have a positive charge, and positive repels positive.

Q4. What are the dangers of nuclear fusion?
Ans:-fusion reactors have serious problems that also afflict today's fission reactore, including neutronradiation damage and radioactive waste, potential tritium release, the burden on coolant resources, outsize operating costs, and increased risks of nuclear weapons proliferation.


Q5. Do all stars use nuclear fusion?
Ans:-All stars, from red dwarfs through the Sun to the most massive supergiants, achieve nuclear fusion in their cores by rising to temperatures of 4,000,000 K or higher. Over large amounts of time, hydrogen fuel gets burned through a series of reactions, producing, in the end, large amounts of helium-4.

Q6. How clean is nuclear fusion?
Ans:-Proponents of nuclear fusion see it is as a clean and virtually limitless energy source that could power the future.

Q7. What happens if a fusion reactor fails?
Ans:-Corrosion in the heat exchange system, or a breach inthe reactor vacuum ducts could result in the release of radioactive tritium into the atmosphere or local water resources. Tritiumexchanges with hydrogen to produce tritiated water, which is biologically hazardous.

Q8. Is Fusion more powerful than fission?
Ans:-As we know that what exactly a nuclear fusion and fission is.Nuclear fusion is the reaction that occurs in our sun and thus, fusion reaction is many times greater than fission.

Q9. Does fusion ever work?
Ans:- While work is underway to reach a technology that can produce safe, predictable, positive net energy from fusion, its realisation would only get fusion so far. In order for nuclear fusion technology to become commercially viable, it must be economical.

Q10. How small can nuclear reactors be?
Ans:-The International Atomic EnergyAgency (IAEA) defines 'small' as under 300 MWe, and up to about 700 MWe as 'medium' – including many operational units from the 20th century. Together they have been referred to by the IAEA as small and medium reactors(SMRs).

→By the end of the century, demand for energy will have tripled under the combined pressure of population growth, increased urbanization and expanding access to electricity in developing countries.
→ The fossil fuels that shaped 19th and 20th century civilization can only be relied on at the cost of greenhouse gases and pollution.
→A new large-scale, sustainable and carbon-free form of energy is urgently needed.

★The following advantages make fusion worth pursuing★

●Abundant energy: Fusing atoms together in a controlled way releases nearly four million times more energy than a chemical reaction such as the burning of coal, oil or gas and four times as much as nuclear fission reactions (at equal mass).

→ Fusion has the potential to provide the kind of baseload energy needed to provide electricity to our cities and our industries.

Sustainability: Fusion fuels are widely available and nearly inexhaustible.

→Deuterium can be distilled from all forms of water, while tritium will be produced during the fusion reaction as fusion neutrons interact with lithium. (Terrestrial reserves of lithium would permit the operation of fusion power plants for more than 1,000 years, while sea-based reserves of lithium would fulfil needs for millions of years.).Thus we can light a house by using just one glass of water

No CO₂: Fusion doesn't emit harmful toxins like carbon dioxide or other greenhouse gases into the atmosphere. Its major by-product is helium: an inert, non-toxic gas.

No long-lived radioactive waste: -Nuclear fusion reactors produce no high activity, long-lived nuclear waste. The activation of components in a fusion reactor is low enough for the materials to be recycled or reused within 100 years.

Limited risk of proliferation: Fusion doesn't employ fissile materials like uranium and plutonium. (Radioactive tritium is neither a fissile nor a fissionable material.) There are no enriched materials in a fusion reactor like ITER that could be exploited to make nuclear weapons.

No risk of meltdown: A Fukushima-type nuclear accident is not possible in a tokamak fusion device.
It is difficult enough to reach and maintain the precise conditions necessary for fusion—if any disturbance occurs, the plasma cools within seconds and the reaction stops.
The quantity of fuel present in the vessel at any one time is enough for a few seconds only and there is no risk of a chain reaction.Cost: 
The power output of the kind of fusion reactor that is envisaged for the second half of this century will be similar to that of a fission reactor, (i.e., between 1 and 1.7 gigawatts).
The average cost per kilowatt of electricity is also expected to be similar ... slightly more expensive at the beginning, when the technology is new, and less expensive as economies of scale bring the costs down.
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THE SUN #SRO8981

THE SUN 
●The Sun  is the Star at the center of the Solar System. It is a nearly perfect sphere of hot Plasam with internal Convective motion that generates a Magnetic Field via a  Dynamo Process.
●It is by far the most important source of Energy for life on Earth.
●Its diameter is about 1.39 million kilometers (864,000 miles), or 109 times that of Earth, and It's Mass is about 330,000 times that of Earth. ●
●It accounts for about 99.86% of the total mass of the Solar System.
●Roughly three quarters of the Sun's mass consists of hydrogen (~73%); the rest is mostly helium (~25%), with much smaller quantities of heavier elements, including oxygencarbonneon, and Iron.





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●The Sun currently fuses about 600 million tons of hydrogen into helium every second, converting 4 million tons of matter into energy every second as a result. This energy, which can take between 10,000 and 170,000 years to escape from its core, is the source of the Sun's light and heat. When hydrogen fusion in its core has diminished to the point at which the Sun is no longer in hydrostatic equilibrium, its core will undergo a marked increase in density and temperature while its outer layers expand, eventually transforming the Sun into a red giant. It is calculated that the Sun will become sufficiently large to engulf the current orbits of Mercury and Venus, and render Earth uninhabitable – but not for about five billion years. After this, it will shed its outer layers and become a dense type of cooling star known as a white dwarf, and no longer produce energy by fusion, but still glow and give off heat from its previous fusion.
●The enormous effect of the Sun on Earth has been recognized since prehistoric times, and the Sun has been regarded by some cultures as a deity. The synodic rotation of Earth and its orbit around the Sun are the basis of solar calendars, one of which is the predominantcalendar in use today.










The structure of the Sun contains the following layers:



◆ CORE ◆


●The innermost 20–25% of the Sun's radius, where temperature (energies) and pressure are sufficient for nuclear fusion to occur.

●Hydrogen fuses into helium (which cannot currently be fused at this point in the Sun's life). The fusion process releases energy, and the helium gradually accumulates to form an inner core of helium within the core itself.


◆ RADIATIVE ZONE  ◆


●Convection cannot occur until much nearer the surface of the Sun. Therefore, between about 20–25% of the radius, and 70% of the radius, there is a "radiative zone" in which energy transfer occurs by means of radiation (photons) rather than by convection.

◆Tachocline ◆

●The boundary region between the radiative and convective zones.


◆ CONVECTION ZONE ◆

●Between about 70% of the Sun's radius and a point close to the visible surface, the Sun is cool and diffuse enough for convection to occur, and this becomes the primary means of outward heat transfer, similar to weather cells which form in the earth's atmosphere.

Photosphere –

●The deepest part of the Sun which we can directly observe with visible light. Because the Sun is a gaseous object, it does not have a clearly defined surface; its visible parts are usually divided into a 'photosphere' and 'atmosphere'.Atmosphere – a gaseous 'halo' surrounding the Sun, comprising the chromosphere, solar transition region, corona and heliosphere. These can be seen when the main part of the Sun is hidden, for example, during a solar eclipse.




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SOLAR CORE :-

●The core of the Sun extends from the center to about 20–25% of the solar radius.

●It has a density of up to 150 g/cm3 (about 150 times the density of water)
 and a temperature of close to 15.7 million kelvins (K).

●By contrast, the Sun's surface temperature is approximately 5,800 K.

●Recent analysis of SOHO mission data favors a faster rotation rate in the core than in the radiative zone above.

●Through most of the Sun's life, energy has been produced by nuclear fusion in the core region through a series of nuclear reactions called the p–p (proton–proton) chain; this process converts hydrogen into helium.

●Only 0.8% of the energy generated in the Sun comes from another sequence of fusion reactions called the CNO cycle, though this proportion is expected to increase as the Sun becomes older.

●The core is the only region in the Sun that produces an appreciable amount of thermal energy through fusion; 99% of the power is generated within 24% of the Sun's radius, and by 30% of the radius, fusion has stopped nearly entirely.

●The remainder of the Sun is heated by this energy as it is transferred outwards through many successive layers, finally to the solar photosphere where it escapes into space through radiation (photons) or advection (massive particles).

●The proton–proton chain occurs around 9.2×1037 times each second in the core, converting about 3.7×1038 protons into alpha particles (helium nuclei) every second (out of a total of ~8.9×1056 free protons in the Sun), or about 6.2×1011 kg/s.

●Fusing four free protons(hydrogen nuclei) into a single alpha particle (helium nucleus) releases around 0.7% of the fused mass as energy, so the Sun releases energy at the mass–energy conversion rate of 4.26 million metric tons per second (which requires 600 metric megatons of hydrogen ), for 384.6 yottawatts (3.846×1026 W), or 9.192×1010 megatons of TNT per second.

● The large power output of the Sun is mainly due to the huge size and density of its core (compared to Earth and objects on Earth), with only a fairly small amount of power being generated per cubic metre.

●Theoretical models of the Sun's interior indicate a maximum power density, or energy production, of approximately 276.5 watts per cubic metre at the center of the core,which is about the same rate of power production as takes place in reptile metabolism or a compost pile.

●The fusion rate in the core is in a self-correcting equilibrium: a slightly higher rate of fusion would cause the core to heat up more and expand slightly against the weight of the outer layers, reducing the density and hence the fusion rate and correcting the perturbation; and a slightly lower rate would cause the core to cool and shrink slightly, increasing the density and increasing the fusion rate and again reverting it to its present rate.



For Such More Information Don't forget to leave a comment ◆ RADIATIVE ZONE  ◆


●From the core out to about 0.7 solar radii, thermal radiation is the primary means of energy transfer.

●The temperature drops from approximately 7 million to 2 million kelvins with increasing distance from the core.

●This temperature gradient is less than the value of the adiabatic lapse rate and hence cannot drive convection, which explains why the transfer of energy through this zone is by radiation instead of thermal convection.

●Ions of hydrogenand helium emit photons, which travel only a brief distance before being reabsorbed by other ions.

●The density drops a hundredfold (from 20 g/cm3 to 0.2 g/cm3) from 0.25 solar radii to the 0.7 radii, the top of the radiative zone.



 ◆ TACHOCLINE ◆


●The radiative zone and the convective zone are separated by a transition layer, the tachocline.

●This is a region where the sharp regime change between the uniform rotation of the radiative zone and the differential rotation of the convection zone results in a large shearbetween the two—a condition where successive horizontal layers slide past one another.

●Presently, it is hypothesized (see Solar dynamo) that a magnetic dynamo within this layer generates the Sun's magnetic field.




◆ CONVECTION ZONE ◆



●The Sun's convection zone extends from 0.7 solar radii (500,000 km) to near the surface.

●In this layer, the solar plasma is not dense enough or hot enough to transfer the heat energy of the interior outward via radiation.

●Instead, the density of the plasma is low enough to allow convective currents to develop and move the Sun's energy outward towards its surface.

●Material heated at the tachocline picks up heat and expands, thereby reducing its density and allowing it to rise.

● As a result, an orderly motion of the mass develops into thermal cellsthat carry the majority of the heat outward to the Sun's photosphere above.

●Once the material diffusively and radiatively cools just beneath the photospheric surface, its density increases, and it sinks to the base of the convection zone, where it again picks up heat from the top of the radiative zone and the convective cycle continues. At the photosphere, the temperature has dropped to 5,700 K and the density to only 0.2 g/m3 (about 1/6,000 the density of air at sea level).

●The thermal columns of the convection zone form an imprint on the surface of the Sun giving it a granular appearance called the solar granulation at the smallest scale and supergranulation at larger scales.

● Turbulent convection in this outer part of the solar interior sustains "small-scale" dynamo action over the near-surface volume of the Sun.

●The Sun's thermal columns are Bénard cells and take the shape of hexagonal prisms.



◆ PHOTOSPHERE ◆



●The effective temperature, or black body temperature, of the Sun (5,777 K) is the temperature a black body of the same size must have to yield the same total emissive power.


●The visible surface of the Sun, the photosphere, is the layer below which the Sun becomes opaque to visible light.

●Photons produced in this layer escape the Sun through the transparent solar atmosphere above it and become solar radiation, sunlight.

●The change in opacity is due to the decreasing amount of H− ions, which absorb visible light easily.

●Conversely, the visible light we see is produced as electrons react with hydrogen atoms to produce H− ions.

●The photosphere is tens to hundreds of kilometers thick, and is slightly less opaque than air on Earth.

●Because the upper part of the photosphere is cooler than the lower part, an image of the Sun appears brighter in the center than on the edge or limb of the solar disk, in a phenomenon known as limb darkening.

●The spectrum of sunlight has approximately the spectrum of a black-body radiating at 5,777 K, interspersed with atomic absorption lines from the tenuous layers above the photosphere.

●The photosphere has a particle density of ~1023 m−3 (about 0.37% of the particle number per volume of Earth's atmosphere at sea level).

●The photosphere is not fully ionized—the extent of ionization is about 3%, leaving almost all of the hydrogen in atomic form.

●During early studies of the optical spectrum of the photosphere, some absorption lines were found that did not correspond to any chemical elements then known on Earth.

●In 1868, Norman Lockyer hypothesized that these absorption lines were caused by a new element that he dubbed helium, after the Greek Sun god Helios.

●Twenty-five years later, helium was isolated on Earth.




◆ ATMOSPHERE ◆

See also: Solar corona and Coronal loop

●During a total solar eclipse, the solar corona can be seen with the naked eye, during the brief period of totality.

●During a total solar eclipse, when the disk of the Sun is covered by that of the Moon, parts of the Sun's surrounding atmosphere can be seen.

●It is composed of four distinct parts: the chromosphere, the transition region, the corona and the heliosphere.

●The coolest layer of the Sun is a temperature minimum region extending to about 500 kmabove the photosphere, and has a temperature of about 4,100 K.

●This part of the Sun is cool enough to allow the existence of simple molecules such as carbon monoxide and water, which can be detected via their absorption spectra.

●The chromosphere, transition region, and corona are much hotter than the surface of the Sun.

●The reason is not well understood, but evidence suggests that Alfvén waves may have enough energy to heat the corona.

●Above the temperature minimum layer is a layer about 2,000 km thick, dominated by a spectrum of emission and absorption lines.[82]

●It is called the chromosphere from the Greek root chroma, meaning color, because the chromosphere is visible as a colored flash at the beginning and end of total solar eclipses.

●The temperature of the chromosphere increases gradually with altitude, ranging up to around 20,000 K near the top.

●In the upper part of the chromosphere helium becomes partially ionized.


●Above the chromosphere, in a thin (about 200 km) transition region, the temperature rises rapidly from around 20,000 K in the upper chromosphere to coronal temperatures closer to 1,000,000 K.

●The temperature increase is facilitated by the full ionization of helium in the transition region, which significantly reduces radiative cooling of the plasma.

●The transition region does not occur at a well-defined altitude. Rather, it forms a kind of nimbusaround chromospheric features such as spicules and filaments, and is in constant, chaotic motion.

●The transition region is not easily visible from Earth's surface, but is readily observable from space by instruments sensitive to the

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