Cell phone signals create cancer --WHO

Though the World Health Organization officials are of judgment that mobile phones are a cause for health hazards ranging from vomiting to cancer the Indian counter parts are not convinced with it. They would present their paper only after a thorough study and when would they complete the study is known to none. Cell phone is a convenient gadget which makes life easy and (sometimes miserable too) nevertheless latest research in this direction are not at all favourable. The harmful radiation of microwave frequency or less might cause cancer in the brain. Why can’t one bear in mind the heating property of microwave oven where food stuffs are cooked by passing microwave through water soaked food material? The region around one’s ear contains blood and the microwave from a cell phone in fact cooks the flesh round one’s ear. In addition these electromagnetic radiations create cancerous cells in the brain.

The mobile phone companies by their lavish spending in channels and news papers keep media promoters friendly. And that is why studies adversely affecting the sale of mobile phones are not seeing light. However, in the wake of UN study the mobile users have to make an introspection and restrict the use of mobile phones for their own health. What is the use a cell phone once the brain cells are tampered? It is unwise to depend on mobile phone manufacturers for remedy as they are never going to provide any solution for the radiation hazard.

It is not for the first time warning about radiation hazard is being published. However, this sort of warning took a dimension only now with WHO findings. If people are unwilling to give up their bad habit of extensive use of cell phones, they should alone bear the brunt.
K A Solaman

Heaven, afterlife are beyond human mind-K A Solaman

Stephen Hawking believes there is no heaven (No afterlife, no heaven: Stephen Hawking, May 17). The Cambridge-based scientist said that the belief in heaven or an afterlife is a “fairy story” for people who are afraid of death. Being a scientist, it is natural for Mr Hawking to look at everything from a scientific perspective. But death and afterlife are abstract ideas and are beyond the ability of the human mind to fully comprehend. The renowned astrophysicist’s observation is unlikely to affect the prospects of clergies and swamis who live by preaching about life after death and heaven.

K.A. Solaman
Kerala
The Asian Age daily, London 31 May 2011

Statistical Mechanics and Thermodynamics

Question Paper 2011 June Batch
Statistical Mechanics and Thermodynamics
The question paper contain 3 parts
Part A contains 20 questions. Answer any 15 questions (Each question carries 2 marks)
Part B contain 20 questions and all are compulsory (Each question carries 3.5 marks)
Part C contains 25 questions. First 10 are compulsory and from remaining 15, answer any 10 questions (Each question carries 5 marks)
There will be negative marks @ 25% of each wrong answer.

Time : 3hrs
Marks: 200

PART A
For polyatomic gases such as hydrogen the corresponding Phase Space would be ------- dimensional.
3N
3Nf
2Nf
6N
On a (T -S)) diagram, i.e., temperature (T) entropy (S), the isothermals are ---
Parallel to S axis
Parallel to T axis
May have any orientation
Some parallel to T and some parallel to S axis
In a gas the expression for the average speed of the molecule is given by----
√(2kT/m)
√(3kT/m)
√(8kT/πm)
√(kT/m)
Specific heats of a gas at constant volume (Cv) and at constant pressure (Cp) are related as
C_p/C_v =1-R
C_p-C_v=R
C_p-C_v=1/R
C_p+C_v=R
The expression for Maxwell’s distribution of velocities, δn/δc is
4πn (m/2πkT)^(3⁄2) e^(-(mc^2)/2kT) c
4πn (m/2πkT)^(3⁄2) e^(-(mc^2)/2kT) c^2
4πn (m/πkT)^(3⁄2) e^(-(mc^2)/2kT) c^2
4πn (m/2πkT)^(3⁄2) e^(-mc/2kT) c^2
A reversible heat engine can have 100% efficiency if the temperature of sink is-
Less than that of source
Equal to that of source
0oC
O K
In a gas the relative magnitudes of the most probable speed (v_p), the average speed (v ̅)and the root mean square speed(〖 v〗_rms) of the molecule are related by an expression
√2:√(2/π):√3
√2:√(4/π):√3
√2:√(8/π):√3
√2:√(8/π):√6
The combined form of the first and second law of thermodynamics is given by-
TdS=dU+PdV
dQ=TdS+PdV
dU=TdS+dQ
TdS=dU-PdV
A system has N distinguishable particles. Each particle can occupy one of the two non-degenerate states with an energy difference of 0.1 ev. If the system is in thermal equilibrium at room temperature, the approximate fraction of particles in the higher energy state is
exp (-10)
exp (-4)
exp (-2)
Zero
The work done W during an isothermal process in which the gas expands from an initial volume V1 to a final volume V2 is given by
R(V_2-V_1)〖log〗_e (T_1/T_2)
R(T_2-T_1)〖log〗_e (V_1/V_2)
RT〖log〗_e (V_2/V_1)
RT〖log〗_e (V_1/V_2)
Consider the Fermi-dirac distribution function F(E) at room temperature (300 K) where E refers to energy. If Ef is the Fermi energy, which of the following is false?
F(E) is a step function
F(E_f) has a value of ½
States with E F(E) is large and tends to infinity as E decreases much below Ef.
The change in entropy is-
Positive in a reversible change
Negative in an irreversible change
Positive in an irreversible change
Negative in a reversible change
In a micro canonical ensemble, a system A of fixed volume is in contact with a large reservoir B. Then
A can change only energy with B
A can change only particles with B
A can exchange neither energy nor particles with B
A can exchange both energy and particles with B
If a system is in thermal equilibrium separately with B &C, then B and C are also in thermal equilibrium with each other. This statement is –
Zeroth law of T D
First law of T D
Second law of T D
Third law of T D
In a canonical ensemble, a system A of fixed volume is in contact with a large reservoir B. Then-
A can change only energy with B
A can change only particles with B
A can exchange neither energy nor particles with B
A can exchange both energy and particles with B
In a cyclic process-
Work done is zero
Work done by the system is equal to quantity of heat given to the system
Work done does not depend on the quantity of heat given to the system
The internal energy of the system increases
In a grand canonical ensemble, a system A of fixed volume is in contact with a large reservoir B. then-
A can change only energy with B
A can change only particles with B
A can exchange neither energy nor particles with B
A can exchange both energy and particles with B
The ratio of specific heat of a diatomic gas is-
1.66
1.33
1.40
1.52
In case of Bose- Einstein Condensation-
Number of particles increases in lower energy levels at low temperatures and high pressures
Number of particles decreases in lower energy levels at low temperatures and high pressures
Number of particles increases in lower energy levels at high temperatures and low pressures
Number of particles decreases in lower energy levels at high temperatures and low pressures
Which of the following is not Maxwell’s thermodynamic relation?
(∂S/∂V)_T=(∂P/∂T)_V
(∂S/∂P)_T=〖-(∂V/∂T)〗_P

Heat transfer-Objective questions and answers

KAS Physics
Thermal Physics Test number 202

1. Radiation is the chief method of energy transfer
*a. from the sun to an earth satellite b. from a gas flame to water in a teakettle
c. from a soldering iron to metals being soldered. d. from water to an ice cube floating in it e. from a mammal to the surrounding air.

2. of the processes below, the one in which practically all the heat transfer is by conduction is: a. from the sun to an earth satellite b. from a gas flame to the top layer of water in a teakettle. *c. from a soldering iron to metals being soldered d. from the bottom of a glass of water to an ice cube floating in it. e. from a mammal to the surrounding air.

3. two kg of water are heated by stirring, if this raises the temperature of the water from 15˚C to 25˚C, how much work, in joules, was done to the water by the stirring?
a. 20,000 b. 40,000 c. 60,000 *d. 80,000 e. 100,000

4. In a certain steam engine, the average pressure on the piston during a stroke is 50 N/m2. The length of each stroke is 12 cm, the area of the piston is 120 cm2 and the diameter of the flywheel is 5m. the amount of work done on the piston during each stroke is, in N-m, approximatelyy
a. 250 *b.0.072 c. 0.54 d.1.63 e. 12.62

5. the work done by a system is characterized as
*a. Positive b. Negative c. either positive or negative d. indeterminate
e. of no consequence

6. which of the following can actually lower the internal energy (cool) a room?
a. Fan b. refrigerator with door open
c. refrigerator with door closed d. an air conditioner in the middle of the room
*e. an air conditional partially exposed to the outside

7. 30 joules of heat flow into a system. the system in turn does 50 J of work. The internal energy of the system has
a. increased by 80 J b. decreased by 80 J c. increased by 20 J d. decreased by 20 J
*e. remained constant

8. dark, rough objects are generally good for
a. Conduction *b. Radiation c. Convection d. Reflection e. refraction

9. dark plastic handles are often used on kitchen utensils because
a. the black material is a good radiator *b. the plastic is a good insulator
c. The plasticic is a good conductor d. the plastic softens gradually with excessive heat.
e. the material is thermoplastic

The Golden Ratio and Beauty in Art

The Golden Ratio has a great impact on art, influencing artists' perspectives of a pleasant art piece. Have you ever wondered why Da Vinci's Mona Lisa looks so beautiful? Da Vinci, a sculpture, painter, inventor and a mathematician, was the first one who first called Phi the Golden Ratio. And scientifically, her face actually appears in a golden rectangle, which also makes her face appear more beautiful to human eyes. Also another masterpiece, the Last Supper, contains Golden Ratios. The French Impressionist painter George Seurat is famous by his new technique of drawing - Pointilism, he is said to have "attacked every canvas by the golden section."
Mona Lisa

Mona Lisa's face is a perfect golden rectangle, according to the ratio of the width of her forehead compared to the length from the top of her head to her chin.

The golden ratio = 1.61803399

General Science MCQ and A

Here are some general science quiz questions along with answers to increase your general knowledge about science.
General Science Quiz Questions

1. Which instrument is used to measure pressure?
1. Saccharimeter
2. Ammeter
3. Manometer
4. Lactometer

2. What does Angstrom measure?
1. Quantity of liquid
2. Length of light waves
3. Length of cables
4. Speed of ships

3. Light year is related to
1. Energy
2. Speed
3. Distance
4. Intensity

4. Match the following columns
Column 1 Column 2
A. Relative 1. Pyrometer humidity
B. Anemometer 2. High temperature
C. Navigation 3. Hygrometer
D. Direction of wind 4. Chronometer
1 2 3 4
a. B D A C
b. D B A C
c. A D B C
d. C A D B

5. Which of the following instruments is used to measure pressure of gases?
1. Barometer
2. Manometer
3. Ammeter
4. None of these

6. Joule is the unit of
1. Temperature pressure
2. Energy
3. Heat

7. How many Dynes are there in one gram weight?
1. 900
2. 375
3. 981
4. 250

8. How many Ergs are these in 1 Joule?
1. 102
2. 104
3. 106
4. 107

9. The unit of current is
1. Ohm
2. Watt
3. Ampere
4. None of these

10. The unit of energy in MKS system is
1. Volt
2. Erg
3. Ohm
4. Joule

11. The intensity of an earthquake is measured with a
1. Barometer
2. Hydrometer
3. Polygraph
4. Seismograph

12. Centigrade & Fahrenheit scales give same reading at
1. - 40°
2. - 32°
3. - 273°
4. - 100°

13. Match the following columns
Column 1 Column 2
A. Anemometer 1. To measure underwater depth using sound
B. Aneroid barometer 2. To measure very small distances
C. Micrometer 3. Find out wind speed
D. Fathometer 4. Find out direction of wind
5. Measure atmospheric pressure
1 2 3 4
a. A4 B5 C3 D1
b. A3 B5 C2 D1
c. A5 B1 C3 D4
d. A3 B1 C5 D2

14. Who among the following described protoplasm as the physical basis of life?
1. T. H. Huxley
2. Leeuwenhoek
3. Rudolf Virchow
4. J. C. Bose

15. The scientist who first discovered that the earth revolves round the sun was
1. Newton
2. Dalton
3. Copernicus
4. Einstein

16. Alexander Fleming discovered
1. Penicillin
2. X-ray
3. Streptomycin
4. Telephone

17. Who among following invented the steam engine?
1. Marconi
2. James Watt
3. Thomas Savery
4. Wright Brothers

18. Who invented typewriter?
1. Shockley
2. Pascal
3. Sholes
4. Waterman

19. Match the following columns:
Column 1 Column 2
A. Proton 1. Chadwick
B. Neutron 2. Millikan
C. Charged Electron 3. Goldstein
D. Shelled nature of atom 4. Rutherford
5. Madam Curie
a. A1 B2 C3 D5
b. A2 B1 C4 D3
c. A2 B3 C1 D4
d. A4 B2 C3 D1

20. Who discovered circulation of blood in human body?
1. Edward Jenner
2. Joseph Lister
3. William Harvey
4. Jonon Esals

21. The first attempt in printing was made in England by
1. James Arkwright
2. James Watt
3. William Caxton
4. Isaac Newton

22. Who was the surgeon who pioneered antiseptic surgery in 1865?
1. Edward Jenner
2. Joseph Lister
3. Henry William
4. John Sleeman

23. The credit of inventing the television goes to
1. Faraday
2. Baird
3. Edison
4. Marconi

24. The credit of developing the polio vaccine goes to
1. Jonas Salk
2. Alb E. Sabin
3. Selman Waksman
4. None of these

25. Mark the wrong combination
1. James Watt: Steam Engine
2. A.G. Bell: Telephone
3. J. L. Baird: Television
4. J. Perkins: Penicillin

26. Choose the correct combination
1. Typewriter: Remington
2. Dynamite: Dunlop
3. Evolution: Darwin
4. Aeroplane: Harway

27. Who invented the ball point pen?
1. Waterman
2. Oscar
3. Wilson
4. Lazlo Biro

28. Blaze Pascal is associated with
1. Calculating machine
2. Computer
3. Cinema
4. None of these

29. Wright Brothers are regarded inventors of the
1. Balloon
2. Bicycle
3. Aeroplane
4. None of these

30. Which of the following pairs is incorrect?
1. Roentgen: X-ray
2. Newton: Law of gravitation
3. Faraday: Diffusion of gases
4. Pasteur: Bacteriology

31. Philology is the
1. Study of bones
2. Study of muscles
3. Study of architecture
4. Study of languages

32. Anatomy is the branch of science which deals with
1. Structure of animals and plants
2. Functioning of body organs
3. Animal behavior
4. Cells and tissues

33. Study of earthquakes is known as
1. Ecology
2. Seismology
3. Numismatics
4. None of these

34. Ecology deals with
1. Birds
2. Cell formation
3. Relation between Organisms and their environment
4. Tissues

35. Meteorology is the science of
1. Weather
2. Meteors
3. Metals
4. Earthquakes

36. Oncology is the study of
1. Birds
2. Cancer
3. Mammals
4. Soil

37. Study of life in outer space is known as
1. Endobiology
2. Exobiology
3. Enterobiology
4. Neobiology

38. Numismatics is the study of
1. Coins
2. Numbers
3. Stamps
4. Space

39. Eugenics is the study of
1. Altering humans beings by changing their genetic components
2. People of European origin
3. Different races of mankind
4. Genetics of plants

40. Ornithology is the
1. Study of bones
2. Study of birds
3. Study of smells
4. None of these

41. Who invented the Doctor’s thermometer?
1. Fahrenheit
2. Edison
3. Galileo
4. None of these

42. The velocity of light was first measured by
1. Einstein
2. Newton
3. Romer
4. Galileo

43. Who proposed the chemical evolution of life?
1. Darwin
2. Lammarck
3. Oparin
4. Haechel

44. The telephone was invented by
1. John Logie Baird
2. Alexander Graham Bell
3. Thomas Elva Edison
4. James Watt

45. Who among the following evolved the concept of relationship between mass and energy?
1. Einstein
2. Planck
3. Dalton
4. Rutherford

46. Match the following columns:
Column 1 Column 2
A. Radioactivity 1. Planck
B. Periodic Table 2. Thomson
C. Quantum Theory 3. Rutherford
D. X-Rays 4. Mendeleev
5. Roentgen
6. Becquerel
a. A1 B3 C5 D2
b. A6 B5 C3 D5
c. A3 B2 C1 D5
d. A6 B4 C1 D5

47. Match the following columns:
Column 1 Column 2
A. Marconi 1. Radio
B. Darwin 2. Natural selection theory
C. Laennec 3. Orthogenesis theory
D. Baird 4. Stethoscope
5. Television
a. A1 B3 C4 D5
b. A5 B4 C3 D2
c. A1 B2 C4 D5
d. A3 B5 C2 D4

48. Robert Koch worked on
1. Tuberculosis
2. Cholera
3. Malaria
4. Diabetes

49. Who discovered Uranus?
1. Herschel
2. Ganleo
3. Copernicus
4. None of these

50. Who among the following is associated with the invention of computers?
1. Edison
2. Babbage
3. Mac Millen
4. Rangabhashyam

Answers to General Science Quiz Questions

1. c 2. d 3. c 4. a 5. b
6. c 7. c 8. d 9. c 10. d
11. d 12. a 13. b 14. a 15. c
16. a 17. b 18. c 19. c 20. c
21. c 22. b 23. b 24. a 25. d
26. c 27. d 28. a 29. c 30. c
31. d 32. a 33. b 34. c 35. a
36. b 37. b 38. a 39. a 40. b
41. a 42. c 43. c 44. b 45. a
46. d 47. c 48. a 49. a 50.

Wafer-thin majority of UDF cheers none.

The wafer-thin majority of two seats in the 140-member Assembly for Congress-led UDF cheer none in the front and the people who wished to see the end of misrule of LDF for last five years. UDF won only 72 seats, crossing the magic figure of 71 required for a simple majority. It is all with Achuthanandan’s propaganda the LDF succeeded in staving off the anti-incumbency trend against the government, which was reflected in the 2009 Lok Sabha polls and civic elections last year. Pinarayi and coterie have no contribution to the 68 seats of the LDF.

Oommen Chandy and company are on the way to Raj Bhavan, however, sleepless nights await Chandy. It is very tough to sail over with Virendra Kumar, Shibu Baby John, T M Jacob and all other ministerial berth mongers of the UDF.

-K A Solaman

എസ്‌.എസ്‌.എല്‍.സി ഫലം ഇന്ന്‌ 3.30ന്‌

Posted On: Thu, 28 Apr 2011
തിരുവനന്തപുരം: എസ്‌.എസ്‌.എല്‍.സി പരീക്ഷാ ഫലം ഇന്ന്‌ വൈകിട്ട്‌ 3.30ന്‌ പ്രസിദ്ധീകരിക്കുമെന്ന്‌ പൊതുവിദ്യാഭ്യാസ ഡയറക്‌ടര്‍ എ.പി.എം മുഹമ്മദ്‌ ഹനീഷ്‌ അറിയിച്ചു. നാലരയ്ക്ക്‌ പ്രഖ്യാപിക്കുമെന്നായിരുന്നു നേരത്തെ അറിയിച്ചിരുന്നത്‌.
ഇന്ന്‌ ഉച്ചയ്ക്ക്‌ പരീക്ഷാ ബോര്‍ഡ്‌ യോഗം ചേര്‍ന്ന്‌ ഫലത്തിന്‌ അന്തിമരൂപം നല്‍കും.

മന്ത്രി എം.എ. ബേബി സെക്രട്ടേറിയറ്റിലെ പബ്‌ളിക്‌ റിലേഷന്‍സ്‌ ചേംബറില്‍ വാര്‍ത്താസമ്മേളനം നടത്തിയാണ്‌ ഫലം പ്രഖ്യാപിക്കുക. ഉടന്‍ www.results.itschool.gov.in എന്ന പോര്‍ട്ടലില്‍ ഫലം ലഭിക്കും. മാര്‍ക്ക്‌ ഷീറ്റിന്റെ പ്രിന്റൗട്ടും കിട്ടും. പ്‌ളസ്‌വണ്‍ പ്രവേശനത്തിന്‌ അപേക്ഷിക്കാന്‍ ഈ പ്രിന്റൗട്ട്‌ മതി.

Cooment: No meaning in saying it a result. It is after all a promotion list of all students. The time 3.30pm is best suited for publication of result as it is just after 'Raahu'(1.30 to 3.30pm)
K A Solaman

Momentous life of Sri Satya Sai Baba.

Spiritual leader Sri Sathya Sai Baba is no more. He entered into the last phase of man’s life. Many broke down in tears as his exodus gave deep sorrow to millions of followers worldwide. Celebrities expressed sadness at the Baba’s departure. Baba was a great pious personality who worked selflessly to help others. As the honourable Prime Minister pointed out “Baba’s death is an irreparable loss to all’’ especially the ailing and the poor.

He is truly the re-embodiment of god not in the sense of making rings, watches and "vibhuti" from nowhere but for making an asset of worth Rs 40000 crore from emptiness for helping the poor. His life was incredibly momentous.

K A Solaman

RTI Act is not a cure-all

RTI Act 2005 gives citizens a right to get information from public authorities. However petitions filed against defaulters are not well attended by many commissioners functioning with the Commission. Many of them are appointed on the basis of their association with political parties and this connection reflects in most of their verdict. The illiterate and the labourers get little remedy from RTI Commission.
Persons with moral strength having no political or trade union affiliation should be considered for appointment in the post information commissioners.

K A Solaman

The bright and the dark sides of the election

The bright side of this election is the able management of the conduct of election by Chief Electoral officer Nalini Netto. Strict adherence to Voter ID card or Election Commission issued slip is a bold step. The dark side is the mutual fight by party followers.

K A Solaman

India-the World Champions!

Pakistan lost, Sri Lanka lost and finally India won. Indian Cricket Team will now be known as ‘The World Champions’ every time they play a One Day International. People all over the world viewed the classic event. While the affluent thousands applauded the team sitting at Mumbai Wankhade Stadium, the less privileged ones cheered before home TV and street TVs. The final game was not won because of Sachin Tendulkar but was won for Sachin Tendulkar by his young colleagues. Notably, the win spells out that Indian cricket is in safe hands under the leadership of Mahendra Singh Dhoni.

Some prayed for India’s victory and some others for Sri Lanka in the final. Some prayers were heard and others including that of Sri Lankan President were rejected. Perhaps the Indian God discarded the prayer of Sri Lankan President against India. Nevertheless, the media hype given to this game is avoidable. The people drank thousands of gallons of liquor and spoiled their money,health and valuable time. We need an alternative game like football in the place of cricket to save the people from spoiling themselves with what is called the ‘rich man’s game’.

K A Solaman

Are English medium schools a threat to Malayalam medium ones?

This is a pertinent question that is still lingering in the minds of all malayalees. The politicians who are not well versed in English are deadly against English in schools and for them English is definitely posing threat to Malayalam language.

Nevertheless, learning of English is definitely very important for higher education, to communicate with multi-lingual Indians and for venturing abroad for education or business purposes. Almost all computer and internet literature are available in English and the regional language like Malayalam should take decades to attain that might. The only positive aspect of Malayalam is it is our mother tongue and anything said and written in that language is tastier for us. This doesn’t mean than we have to translate all the English scientific terms to Malayalam in school classes as it is practised now and later students are asked to study them in English too. This is a time waste and in schools itself, if medium of instruction is Malayalam, science terms should be taught in English so that a future effort can be avoided to learn the translation.

Among English learned people there exists absolutely no rivalry between English and Malayalam. They love both languages with equal respect avoid situations for a combat between the two. To remain devout to the Malayalam language, one need not have to reject English. It is the desire of the parents to make their children’s life better and that is why they send their children to English medium schools. It is also the responsibility of the parents toimplant in their children a sense of pride in their mother tongue.

The State Government should shun all actions to give supremacy to Malayalam medium schools instead it should definitely establish a brilliant infrastructure of English education in all the schools, but with due emphasis on Malayalam language as well. And all public notices, circulars, advertisements, application forms etc should be in both the languages so that all people could easily understand them. Policy making bodies should be filled not only with Malayalam poets and novelists but with people having English education and scientific knowledge.
Malayalam lovers should remember that Malayalam is only a regional language with local identities and do not have a global appeal. Everyone is free to speak or write any language of his choice in India and by using a specific language; other languages do not lose their appeal. So it would be wrong to presume that English is a threat to any other language.

In fact, English language has its impact throughout the world because many people understand this language. In India there are various languages but each has its own identity and background. So, none of the languages are in any way inferior to the other languages. There is no doubt that English language has created its impact in India but it does not see other languages inferior. According to Gandhiji learning of many languages is a pleasure so we should not be prejudiced with any language.

K A Solaman

CSIRJRF/NET Physical Science Model Question Paper- 2011June

GENERAL SCIENCES

MODEL QUESTION PAPER

PART A

ANSWER ANY 15 QUESTONS

1. Profit of a firm grows at a rate of 15% per year for the first three consecutive years. For the next three years, the profit level remains stagnant. From the 6th year till the 9th year, it again grows at a rate of 15% per year. Which of the following graphs depicts these facts?

2. A pond is deepest at its centre and becomes shallow uniformly towards the edge. If the depth of water at the centre in May is half its value in August, the water contained in the pond
(1) in May is greater than half that in August
(2) in August is equal to twice that in May
(3) in May is less than half that in August
(4) in August is less than twice that in May

3. The series representing the sum of the areas of the shaded equilateral triangles in the figure below is
1. 3+2+1+1
2. 23411113333
3. 23411114444
4. 1111481632

4. Which of the following vitamins will not be synthesized in a person confined to a dark cell for a long time ?
1. A
2. B
3. C
4. D

5. Flowering is some plants is strongly influenced by the photo period. A farmer was growing two species of plants, A and B near a sea coast where a light house was located. He observed that species A flowered profusely while species B did not. Which of the following is correct ?
1. Species A requires long duration of day while species B needs a shorter day
2. Species B requires longer duration of day while species A needs a shorter duration
3. Both species require short duration of day
4. Both species require long duration of day

6. Pneumatophores are modified roots in some plants like Rhizophora growing in swampy areas that come out of the ground and grow vertically upwards. The main function of such roots is to
(1) help obtain oxygen for respiration
(2) provide support
(3) adsorb and conduct water and minerals
(4) store food

7. A cube of side 1 cm is painted by putting a lacquer of thickness δ, negligible compared to the side of the cube. The volume of the painted cube is approximately
(1) 1 + δ cm3
(2) 1 + δ3 cm3
(3) 1 + 3δ3 cm3
(4) 1 + 3δ cm3
8. A candle is burning inside a sealed glass jar. The pressure and temperature of the air within the jar are plotted as a function of time. Which of the following graphs represents this process correctly?

9. The result of taking 1’s complement of the sum of the binary numbers 110 and 101 will be
(1) 1011
(2) 0011
(3) 0100
(4) 0110

10. Which of the following straight lines passes through the point (1,1)?
(1) y = 2x + 3
(2) 2y = x−6
(3) x = 1
(4) x = y + 1

11. Which of the following 1 molar (aqueous) solution has the highest number density of ions?
(1) Glucose
(2) CaCl2
(3) NaNO3
(4) KCl

12. How many two-digit even numbers can be composed from nine digits 1, 2, 3 … 9?
(1) 50
(2) 81
(3) 45
(4) 36
13. Complete combustion of cyclohexane (C6H12) is represented by the equation
C6H12 + x O2 → y CO2 + z H2O
The values of x, y and z, respectively, are
(1) 9, 6, 6
(2) 10, 6, 4
(3) 6, 12, 10
(4) 4, 8, 12

14. How many distinct trichlorobenzenes (C6H3Cl3) should exist, given that benzene (C6H6) has a regular hexagonal geometry?
(1) 6
(2) 1
(3) 2
(4) 3

15. Mercury is closer to the Sun than Venus. Yet Venus is hotter because it has
(1) a dominant CO2 atmosphere
(2) a dominant methane atmosphere
(3) sulphuric acid clouds
(4) an atmosphere devoid of oxygen

16. In a simple pendulum experiment, a student records the following readings. If the true period of the pendulum is 10 s, then the percent error is the largest for the observation with serial number
Serial Number
Number of Oscillations
Time
1
2
3
4
10
20
50
100
100.2
200.3
500.5
1000.8
(1) 1
(2) 2
(3) 3
(4) 4

17. A container holding normal air (1 bar pressure, room temperature) is being evacuated. The normal composition of air is approximately 78% N2, 21% O2, 0.9% Ar and traces of CO2 (0.04%) and water vapour (0.02%). After the pressure in the container falls to about 10–3 mbar, the relative fractions of the components will be
1. N2 and O2 approximately equal and greater than H2O
2. N2, O2, Ar approximately equal and greater than H2O
3. N2, O2, Ar in the original proportion, but N2 less than H2O
4. N2, O2, Ar in the original proportion, and N2 greater than H2O

18. An endoscope is a device for observing internal organs, using a combination of a lamp and an optical fibre. The image seen is due to
(1) light reflected by the organ and transmitted by internal reflection through the fibre
(2) light refracted by the organ and transmitted by refraction through the fibre.
(3) light refracted by the organ and transmitted by internal reflection through the fibre.
(4) light emitted by the organ and transmitted by refraction through the fibre.

19. How many times in a day is the angle between the minute and hour hands of a clock equal to an angle θ, where 00 < θ < 1800 (1) 24 (2) 12 (3) 36 (4) 48 20. A typical enzyme catalyzed reaction is shown below What do you think the component x might be? 1. Substrate concentration or temperature 2. Substrate concentration or enzyme concentration 3. Substrate concentration or pH 4. pH or temperature PART B 21. The value of the integral 2 0 x xe dx    is equal to 1. 2  2.  3. 0 4. 1 2 22. If   1 Tij2 xi y j xj yi and   ij i j j i S  x y  x y 2 1 are components of tensors T and S(i,j = 1, 2, 3) respectively then , ij ij i j T S is 1. 0 2. 2 2 i i i x y 3. 2 2 i i i x y 4. 4 4 i i i x y 23. An unbiased coin is tossed n times. The probability that exactly m heads will come up is 1. m n 2 2. !( )! ! 2 1 m n m n n  3. !( )! ! 2 1 m n m n m  4. n m 2 24. Given the Legendre polynomials ( ) 1, ( ) , 0 1 P x  P x  x and 2 3 1 ( ) 2 2 x  P x , then the polynomial (3x2 + x – 1) can be expressed as 1. P2(x) – P1(x) 2. 2P2(x) + P1(x) 3. P2(x) + P1(x) 4. 2P2(x) + P1(x)+ P0(x) 25. A circular ring rotates about an axis passing through its centre and perpendicular to its plane. Each point on it moves with a speed c 2 , where c is the speed of light in vacuum. The relative velocity between any two diametrically opposite points on the ring is 1. 2c 5 2. c 2 3. 4c 5 4. c 26. For what value of  will transformation q  Q = q cos2p and pP=q sin2p be canonical? 1.  = 1 2.  = ½ 3.  = ‒1 4.  = 2 27. Consider a spherical ball of radius R and constant density . Which of the following graphs shows the gravitational potential V(r) as a function of the radial coordinate r ? . . . 28. A quantum particle of mass m moves in two dimensions in an anisotropic harmonic oscillator potential 1 2 2 2 2 2 V(x, y) m x 2m y . The energy eigenvalues are (n is a positive integer or zero) 1.  2n1 2.  n1 3. 2 n1 4.  3  2  n 29. The ground state energy of the Hydrogen atom is 13.6 eV. The energy of the second excited state is 1. 27.2 eV 2. 6.8 eV 3. 1.5eV 4. 4.5 eV 30. Consider a one-dimensional infinite square well potential        otherwise x L V x 0 ( ) If each of the lowest two energy levels are occupied by identical non-interacting bosonic particles (one in each level), then the unnormalized wave function of the combined system is 1.                L 2 x sin L x x ,x sin 1 2 1 2 2. 1 2 2 1 1 2 2 2 ( , ) sin sin sin sin x x x x x x L L L L                               3. 1 2 1 2 1 2 2 2 2 ( , ) sin sin sin sin x x x x x x L L L L                               4. 1 2 1 2 1 2 2 2 ( , ) sin sin sin sin x x x x x x L L L L                               31. The total spin-angular momentum of a system of three free electrons is 1. Stot = 1 2 and Stot = 3 2 2. Stot = 1 2 only 3. Stot = 3 2 only 4. Stot = 0 and Stot = 1 32. A conducting spherical shell of inner radius a and outer radius b has a point charge q located at the centre of the shell. The potential at a distance r from the centre (a < r < b) is 1. 0 2. 0 1 4 q  a 3. 0 1 4 q  b 4. 0 1 4 q  r 33. Consider the electric and magnetic fields of an accelerating charge. How should the fields vary with r (the retarded distance) for the Poynting vector to remain finite at arbitrarily large distances? 1. 1 r 2. 2 1 r 3. r 4. 2 r 34. According to Kirchoff‟s laws for circuits, the sum of the currents at any junction is equal to zero. Which of the following equations for the current density j  describes this situation? 1.  j  0   2. .j 0   3. 2  j 0  4. j/t0  35. Two equal and opposite charges are placed at a distance r from each other. A large metallic sheet is placed at a distance d from them as shown in the figure. Due to the presence of the sheet, the attractive force between the charges along the direction joining them 1. decreases 2. increases 3. remains unchanged 4. decreases if r > d/2 and increases if r < d/2. 36. A non-interacting system has two energy levels, 0 and . The lower level is doubly degenerate while that of energy  is non-degenerate. If the system is in thermal equilibrium at temperature T, the single-particle partition function is 1. Z e kBT / 2   2. Z e kBT / 1 2    3. Z e kBT / 2    4. Z  e kBT  / 2 1    37. A system of weakly interacting two-dimensional harmonic oscillators is in thermal contact with a heat bath of absolute temperature T. The average kinetic energy of an oscillator is 1. kBT 2. 2kBT 3. 3 kBT/2 4. kBT/2 38. Which of the following expresses the Second law of thermodynamics? (Symbols have their usual meanings.) 1. FW 2. S Q T 3. U QW 4. S  0 39. For the op-amp circuit shown in the figure below, which is the correct output waveform? 1. 2. 3. 4. 40. Which of the following circuits has an appropriate voltage divider for biasing the transistor? 1. 2. 3. 4. PART C COMPULSORY QUESTIONS 41. The value of the contour integral  1 2i dz f (z) C  where 2 1 2 ( ) 2 1 z z f z z z     and the contour C is a circle of radius 2 centered at the origin, traversed in the counter-clockwise direction is 1. 2 2. 1/2 3. 1 4. 3 42. The matrix A, defined by 1 0 0 0 0 A a b b a          is orthogonal if 1. a = 1, b = –1 2. a = 1/ 2 , b = 1/ 2 3. a = 1/ 2 , b = i/ 2 4. a = 1, b = 1 43. Given the Lagrangian L = 2 1        dt dx where x is a co-ordinate and t is the time, the Hamiltonian is 1.  dx dt       2 / 1 dx dt       2 2. 2 1       dt dx 3. 2 1 1      dt dx k 4. 2     dt dx 44. In a nonmagnetic dielectric medium with dielectric constant  4 r  ,the electric field of a propagating plane wave with  = 10 8 rad/s is given by E  i j j t k r       ˆ  3ˆ exp    . The propagation vector k  (in units of m-1) is given by 1. k i ˆj 3 ˆ 1 3 1    2. k zˆ 3 1   3. k i ˆj 6 ˆ 1 2 3 1    4. k i ˆj 3 ˆ 1 3 1     45. Two small circular loops, each of area 1cm2 carry currents 1A and 2A respectively. They are placed in a plane at a distance of 5 meters from each other. If one of the loops is lifted 5 meters in the vertical direction while maintaining it flat, the electrical work done in the process is ( 0  is the magnetic permeability of vacuum) 1. 2.75  10 9 2 0  J 2. 1.46  10 10 2 0  J 3. 1.88  10 10 2 0  J 4. 4.74  10 9 2 0  J 46. Consider a three dimensional harmonic oscillator with Hamiltonian H= 2  2 2 2  2 2 2 2 1 2 2 2 m x y z m p m p m p x y z       . A. The number of distinct eigenstates with energy eigenvalue  2 5 is 1. 5 2. 3 3. 2 4. 1 B. The eigenvalue of L 2 (where L  is the angular momentum operator) in the ground state is 1. 2  2. 2 2  3. 0 4. 2 6 47. The states |m>, m = -1, 0, 1 are the eigenstates of S z , the z component of the spin
angular momentum of a particle with S =1. Sz m  m m.
A. The expectation value of S z in the state 1
2
1
0
2
1
1
2
1
     is
1.  / 4
2. -  / 2
3.  / 2
4. -  / 4
B. Consider the states 1
3
1
0
2
1
1
6
1
1      and
1
3
1
1 0
6
1
2     a   . The value of a for which these states are
orthogonal is
1. 1/ 3
2. 1/2
3. 1/ 2
4. 1/ 2
48. The free energy of a system having magnetization m is given by
F = -  2
2
m
J
k T B 







 


 

 



 



 
2
1
ln
2
1
2
1
ln
2
1 m m m m
,
where J is the exchange energy, T is the Temperature, and B k is the Boltzmann
constant.
A. The equilibrium value of magnetization is determined by
1. m = sinh
k T
Jm
B
2. m = cosh
k T
Jm
B
3. m = tanh
k T
Jm
B
4. m =








 


 


  


 


2
3
1
1
k T
Jm
k T
Jm
B B
B. If m is determined through the relationship m =








 


 


  


 


2
3
1
1
k T
Jm
k T
Jm
B B
,
then the system undergoes
1. no phase-transition
2. a second order phase transition at T C B  J / k
3. a first order phase transition at T C B  J / k
4. a phase transition that cannot be classified as either first or second
order.
49. A piece of metal of heat capacity 500 JK–1assumed to be independent of
temperature is at 500 K. The metal piece is cooled to 300K in two steps: it is first
plunged into a liquid bath at 400 K. After cooling it is plunged into a colder
liquid bath at 300 K. The metal piece is then heated to 500 K in two steps: it is
plunged into a liquid bath at 400 K first and then into a liquid bath at 500 K.
During the cooling-heating process, the metal piece and the liquid baths gain or
lose entropy. The total change in entropy of the system (the metal piece and the
liquid baths) is
1. 1500 ln (5/3)JK-1
2. Zero
3. –200 JK–1
4. +200JK–1
50. Shown in the figure is a circuit to measure light intensity and convert it to a digital
signal. The photodiode P has a responsivity of 0.1A per watt of incident light
intensity. The op-amp converts the induced photocurrent to a voltage which is
digitized by the 10-bit A/D converter with a reference voltage of 4V.
A. For a light intensity of 25 μW incident on the photodiode, the voltage
output of the op-amp is
1. 0.25V
2. 1.0V
3. 4.0V
4. 2.5V
B. The range of light intensity which can be measured by this set up is
1. 100nW to 100μW
2. 100nW to 100μW
3. 40nW to 40μW
4. 40nW to 40μW
ANSWER ANY 10 QUESTIONS OUT OF THE REMAINING 15
51. Under a small rotation  about the x – axis, the component of a second
rank tensor Γyz transforms as
1. Γyz = (1 +  ) Γyz
2. Γyz = Γyz +  (Γyy – Tzz)
3. Γyz = Γyz +  (Γyx – Γzx)
4. Γyz = Γyz +  Γxx
52. The partial differential equation
0
u u
x y
x y
 
 
 
.
Upon change of variables to z = x + iy z* =x–iy becomes
1.

u
z

u
z*  0
2.

z
u
z*  z* u
z
 0
3.

z
u
z
 z* u
z*  0
4.

z
u
z
 z* u
z*  0
53. A large slab consists of two materials with dielectric constants 1 and 3 divided by
a plane interface as shown in the figure. An electric field exists in this slab, which
uniformly makes an angle of 30  with the normal to the interface on the left side
of the (=1). The angle the field makes on the other side of the interface is
1. tan 1 (3)
2. sin 



 
2 3
1 1
3. 60 
4. tan 1 (1/3)
54. Given the vector A  y,x,0

, the line integral .
c
 Adl
 
 , where C is a circle of
radius 5 units with its centre at the origin, (correct to the first decimal place) is
1. 172.8
2. 157.1
3. -146.3
4. 62.8
55. An electron is placed in an uniform magnetic field H

that points in the
xˆ direction. The Hamiltonian of the system is H= KS H
 
  where k >0 is a
constant and S

is the electron spin operator.
A. The energy of the ground state of the Hamiltonian is
1.  KS
2. KH
2
1
3. KH
2
1

4. 0
B. The expectation value of z S in the ground state of this Hamiltonian is
1.   / 2
2. 0
3.  / 2
4. 
56. Positronium is an atom formed by an electron and a positron. The mass of a
positron is the same as that of an electron and its charge is equal in magnitude but
opposite in sign to that of an electron. The positronium atom is thus similar to the
hydrogen atom with the positron replacing the proton.
A. The binding energy of a positronium atom is
1. 13.6 eV
2. 6.8 eV
3. 27.2 eV
4. 3.4 eV
B. If a positronium atom makes a transition from the state with n  3 to a
state with n  2, the energy of the photon that is emitted in this transition
is closest to
1. 1.88 eV
2. 0.94 eV
3. 1.13 eV
4. 2.27 eV
57. A particle of mass m and charge q is constrained to move along a straight line
joining two other equal charges q fixed at x =  a. The time period of small
oscillations is
1. am
q
a
T 0
2



2. r am
q
a
T 0
4



3. r am
q
a
T 0  
4. am
q
a
T 0
2



58. A Carnot engine operates between a heat source at 500 K and a heat sink at 300
K. The temperature of the source is increased by 20K. In order that the
efficiency of the engine remain unchanged, the temperature of the sink should be
changed by
1. +20K
2. +12K
3. –12K
4. –20K
59. The following table shows the relationship between an independent quantity x, a
two measured quantities y and z.
A. In order to get a straight line graph relating y to x we should plot
1. y vs log x
2. y2 vs x
3. y vs x2
4. y2 vs log x
B Similarly, in order to get a straight line graph relating z to x, we should
plot
1. z2 vs x3
2. (z + 4)2 vs x3
3. (z – 4)2 vs x3
4. log z vs log x
60. The cross-section for the excitation of a certain atomic level A under electron
impact is 20 2 1.4 10 cm A
    . The level A has lifetime s 8 2 10    and decays
10% of the time to level B and 90% of the time to level C, as shown in figure.
x 0 1 2 3 4 5
y –0.1 2.1 8.1 17.9 32.2 49.7
z –4 –3 2 2  4
3 3  4 4 5 5  4
When an electron beam of 5mA/cm 2 is passed through a vapour of these atoms at
a pressure of 66.65 dynes/cm 2 at a temperature of 27  C, the equilibrium
population per cm3 in level A is
1. 1.4  10 4 cm 3
2. 1.55  10 5 cm 3
3. 4.66  10 5cm 3
4. 3.1  1016cm 3
61. Consider the CO molecule as a diatomic rigid rotor with a bond length of 1.12Å.
The reduced mass of the system is obtained from the atomic masses of C and O.
The rotational energies are defined in terms of B (the rotational constant) and J
(the rotational quantum number). If 1  and 2  denote the frequency of the first
rotational resonance lines for the molecules 12 C16 O and 13 C18 O respectively,
their ratio 1  / 2  is approximately
1. 1.5
2. 1.1
3. 0.9
4. 1.01
62. A metal at temperature T is placed in a static uniform electric field E

. An electron
in it experiences a collision, and then, after a time t, a second collision. In the
Drude model, energy mean speed of an electron emerging from a collision does not
depend on the energy that the electron acquired from the field since the time of the
last collision. The average energy lost by the electron in the second of the two
collisions mentioned previously (note that the average is taken over all directions in
which the electron may emerge after the first collision) is equal to
1.
 2
2
eEt
m
2.
 2
eEt
m
3.
 2
1
4 2
eEt
 m
4.
 2
1
4
eEt
 m
63. The Fermi energy of a two-dimensional electron gas with number density n is
equal to
1.
m
n
2 

2.  
m
n
2
2
2
2 2/ 3 

3.  
m
n
2
3
2
2 2/ 3 

4.
m
n
2
2 
64. The binding energy of a nucleus with atomic number Z and atomic mass number
A is given by the semi-empirical mass formula
B ( Z,A) = aA - bA s 2/3  
A
A Z 2  2
- d 1/ 3 1/ 2
2
A A
Z 

where a = 15.8 MeV, b = 18.3 MeV, s = 23.2 MeV, d = 0.7 MeV and
 = (+11.2, 0, -11.2) MeV for nuclei which are (odd-odd, odd-even, even-even).
If we consider all possible isobars of mass number 216, the most stable nuclide is
1. Pb 216
82
2. Fr 216
87
3. At 216
85
4. Rn 216
86
65. The activity of a radioactive sample is defined as  N where  is the decay
constant and N is the number of atoms. In an experiment, the activity of a sample
of Cr 55
24 was found to change as
After(min) 0 5 10 15 20
 N(m curie) 19.2 7.13 2.65 0.99 0.37
The half life of Cr 55
24 is
1. 5.08 min
2. 3.52 min
3. 3.57 min
4. 5.16 min

Discovery- a great leap to mankind.

The historic journey ends. Discovery finished its 27 years of service and landed at the Kennedy Space Centre. The mission delivered an extra room along with supplies and equipment, including a human-like robot, known as Robonaut 2, the first such robot ever sent into orbit. The oldest shuttle in the fleet, Discovery has cumulatively spent a year in orbit and logged many spaceflight firsts. It was the first shuttle to return to flight after the Challenger disaster in 1986 and after Columbia's disintegration while re-entering orbit.
Discovery launched the trailblazing Hubble Space Telescope, made the first US rendezvous with the Russian Mir space station, and was the first and last shuttle to rotate crews on the space station.
Discovery's next destination will be a museum where hundreds of children could watch and learn about the scientific pursuit of their forerunners.

K A Solaman

Gyro-frequency and gyro-radius- any takers?

Gyro frequency

Also known as the cyclotron frequency or Larmor frequency, the frequency of rotation of a charged particle or ion as it spirals a magnetic field.

The trajectory of a charged particle acted on solely by a magnetic force is a helix with its axis parallel to the magnetic induction. In any plane perpendicular to the magnetic induction the particle describes a circular orbit with gyro-frequency qB/m, where q is charge, m is mass, and B is the magnitude of magnetic induction.

Gyro-radius
The gyroradius is also known as radius of gyration, Larmor radius or cyclotron radius. It is the radius of the circular motion of a charged particle in the presence of a uniform magnetic field.

r = mv/qB

where is the gyro-radius, m is the mass of the charged particle, v is the velocity component perpendicular to the direction of the magnetic field, q is the charge of the particle, and B is the constant magnetic field.

K A Solaman

God is surprised at mankind!

God is surprised at mankind because of the following reasons
Reason 1: Man gets bored in childhood, he wishes to grow up and then longs to be a child.
Reason 2: He loses his health to make money and then loses his money to restore his health.
Reason 3: He thinks anxiously about future, forgetting the present. So he lives neither in future nor in present.
Reason 4: He lives as if he will never die, but die as if he has never lived.


K A Solaman

Whats the difference between 1G, 2G, 3G wireless networking systems?

First, about cellular generations. First 1G service was based on a TDM voice infrastructure -- built around class x switches and 64 kbps slots. It had data, but circuit switched over a 64Kpbs voice bearer.

Second, 2G service had the same switched TDM backbone, but added a true Data Bearer and a digital voice bearer. Data rates were still limited to the max 64kbps of a single time slot.

2.5G added a packet bearer to the mix, still limited to 64kbps slots.

Third generation (3G) changed the backbone slightly to allow a full T1 or E1 or J1 to be consumed by a data sub-scriber, but is still based on an ISDN style backbone. Sure you have packet switched data, but its carried over a traditional TDM backbone. There still a circuit voice backbone and while the data rates are high enough for VoIP, the latency of the data service is to great to base all of the "bearer services" on it, so you still have circuit voice, circuit data and packet data bearers.

Finally, 4G systems will utilize a packet infrastructure rather than a traditional telephone architecture. Services will be horizontally layered on top of a proper low latency, QoS enabled packet switch (read IP) infrastructure. Gone will be the circuit voice and circuit data bearers.

So "G" has more to do with the infra-structure and less to do with the data rates. The data rates over the air are driven by the organization of the infrastructure and other than that have little to do with what generation they are.

In that sense, this NexTel trial is a 4G trial.
K A Solaman

Kerala School Kalosvam Manual-HSS-Grace marks!

PROCEEDINGS OF THE DIRECTOR, DIRECTORATE OF HIGHER
SECONDARY EDUCATION, HOUSING BOARD BUILDINGS, SANTHI
NAGAR, THIRUVANANTHAPURAM
Sub:- Higher Secondary Education – Higher Secondary Examination, March
2010 – Appendix 16 and Appendix 17 appended to Notification
partially modified – Orders issued – reg.
ORDER No. EX II (1) 53388/HSE/09 Dated: 20/01/2010
Read:- 1. Appendix 16 and Appendix 17 appended to Notification of Even
No. dated 27-10-2009.
2. Kerala School Kalosvam Manual, 2008
ORDER
In accordance with the norms stipulated in the Kerala School Kalolsavam
Manual, 2008 cited (2) the Appendix 16 (page 39) appended to Notification for the
Higher Secondary Examination, March 2010 is partially modified as detailed below.
(a) Grace marks are given to the winners in the State Level Higher
Secondary School Youth Festival as given below.
(1) A Grade - 30 Score
(2) B Grade - 24 Score
(3) C Grade - 18 Score
Grace marks will be awarded only after the Second Year Higher Secondary
Examination. It will be awarded only once even if a student gets eligible grade in State
Level Youth Festival twice, during the course of study.

►CSIR UGC NET New Exam Scheme for Single Paper From June 2011

CSIR-UGC (NET) EXAM FOR AWARD OF JUNIOR RESEARCH FELLOWSHIP AND ELIGIBILITY FOR LECTURERSHIP


EXAM SCHEME FOR SINGLE PAPER CSIR-UGC NET Exam
FROM June 2011

CSIR-UGC NET Exam for Science stream is conducted by CSIR in the following areas: -

1. Chemical Sciences
2. Earth Sciences
3. Life Sciences
4. Mathematical Sciences
5. Physical Sciences



It has been decided to introduce Single Paper MCQ MCQ (Multiple Choice Question) based test from June 2011 exam. The pattern for the Single Paper MCQ test shall be as given below:-

v The MCQ test paper of each subject shall carry a maximum of 200 marks.
v The exam shall be for duration of three hours.
v The question paper shall be divided in three parts

Ø Part 'A' shall be common to all subjects. This part shall be a test containing a maximum of 20 questions of General Science and Research Aptitude test. The candidates shall be required to answer any 15 questions of two marks each. The total marks allocated to this section shall be 30 out of 200

Ø Part 'B' shall contain subject-related conventional MCQs. The total marks allocated to this section shall be 70 out of 200. The maximum number of questions to be attempted shall be in the range of 25-35.

Ø Part 'C' shall contain higher value questions that may test the candidate's knowledge of scientific concepts and/or application of the scientific concepts. The questions shall be of analytical nature where a candidate is expected to apply the scientific knowledge to arrive at the solution to the given scientific problem. The total marks allocated to this section shall be 100 out of 200.

Ø A negative marking for wrong answers, wherever required, shall be @ 25%

* The new pattern shall be implemented from June, 2011 exam
* Model Question Papers in the new format shall be made available along with Notification for the June, 2011 exam.



PHYSICAL SCIENCES
EXAM SCHEME

TIME: 3 HOURS MAXIMUM MARKS: 200

From June, 2011 CSIR-UGC (NET) Exam for Award of Junior Research Fellowship and Eligibility for Lecturership shall be a Single Paper Test having Multiple Choice Questions (MCQs). The question paper shall be divided in three parts.

Part 'A'
This part shall carry 20 questions pertaining to General Science, Quantitative Reasoning & Analysis and Research Aptitude. The candidates shall be required to answer any 15 questions. Each question shall be of two marks. The total marks allocated to this section shall be 30 out of 200.

Part 'B'
This part shall contain 20 Multiple Choice Questions (MCQs) generally covering the topics given in the Part ‘A’(CORE) of syllabus. All questions are compulsory. Each question shall be of 3.5 Marks. The total marks allocated to this section shall be 70 out of 200.

Part 'C'
This part shall contain 25 questions from Part ‘B’(Advanced) that are designed to test a candidate's knowledge of scientific concepts and/or application of the scientific concepts. The questions shall be of analytical nature where a candidate is expected to apply the scientific knowledge to arrive at the solution to the given scientific problem. There will be 10 compulsory questions. Out of remaining 15 questions, a candidate shall be required to answer any 10. Each question shall be of 5 Marks. The total marks allocated to this section shall be 100 out of 200.

• There will be negative marking @25% for each wrong answer.

• To enable the candidates to go through the questions, the question paper booklet shall be distributed 15 minutes before the scheduled time of the exam. The Answer sheet shall be distributed at the scheduled time of the exam.

• On completion of the exam i.e. at the scheduled closing time of the exam, the candidates shall be allowed to carry the Question Paper Booklet. No candidate is allowed to carry the Question Paper Booklet in case he/she chooses to leave the test before the scheduled closing time.

• Model Question Paper shall be released at the time of Notification for June 2011 exam

CSIR-UGC National Eligibility Test (NET) for Junior Research Fellowship and Lecturer-ship
PHYSICAL SCIENCES
PART ‘A’ CORE
I. Mathematical Methods of Physics
Dimensional analysis. Vector algebra and vector calculus. Linear algebra, matrices, Cayley-Hamilton Theorem. Eigenvalues and eigenvectors. Linear ordinary differential equations of first & second order, Special functions (Hermite, Bessel, Laguerre and Legendre functions). Fourier series, Fourier and Laplace transforms. Elements of complex analysis, analytic functions; Taylor & Laurent series; poles, residues and evaluation of integrals. Elementary probability theory, random variables, binomial, Poisson and normal distributions. Central limit theorem.
II. Classical Mechanics
Newton’s laws. Dynamical systems, Phase space dynamics, stability analysis. Central force motions. Two body Collisions - scattering in laboratory and Centre of mass frames. Rigid body dynamics- moment of inertia tensor. Non-inertial frames and pseudoforces. Variational principle. Generalized coordinates. Lagrangian and Hamiltonian formalism and equations of motion. Conservation laws and cyclic coordinates. Periodic motion: small oscillations, normal modes. Special theory of relativity- Lorentz transformations, relativistic kinematics and mass–energy equivalence.
III. Electromagnetic Theory
Electrostatics: Gauss’s law and its applications, Laplace and Poisson equations, boundary value problems. Magnetostatics: Biot-Savart law, Ampere's theorem. Electromagnetic induction. Maxwell's equations in free space and linear isotropic media; boundary conditions on the fields at interfaces. Scalar and vector potentials, gauge invariance. Electromagnetic waves in free space. Dielectrics and conductors. Reflection and refraction, polarization, Fresnel’s law, interference, coherence, and diffraction. Dynamics of charged particles in static and uniform electromagnetic fields.
IV. Quantum Mechanics
Wave-particle duality. Schrödinger equation (time-dependent and time-independent). Eigenvalue problems (particle in a box, harmonic oscillator, etc.). Tunneling through a barrier. Wave-function in coordinate and momentum representations. Commutators and Heisenberg uncertainty principle. Dirac notation for state vectors. Motion in a central potential: orbital angular momentum, angular momentum algebra, spin, addition of angular momenta; Hydrogen atom. Stern-Gerlach experiment. Time-independent perturbation theory and applications. Variational method. Time dependent perturbation theory and Fermi's golden rule, selection rules. Identical particles, Pauli exclusion principle, spin-statistics connection.
V. Thermodynamic and Statistical Physics
Laws of thermodynamics and their consequences. Thermodynamic potentials, Maxwell relations, chemical potential, phase equilibria. Phase space, micro- and macro-states. Micro-canonical, canonical
and grand-canonical ensembles and partition functions. Free energy and its connection with thermodynamic quantities. Classical and quantum statistics. Ideal Bose and Fermi gases. Principle of detailed balance. Blackbody radiation and Planck's distribution law.
VI. Electronics and Experimental Methods
Semiconductor devices (diodes, junctions, transistors, field effect devices, homo- and hetero-junction devices), device structure, device characteristics, frequency dependence and applications. Opto-electronic devices (solar cells, photo-detectors, LEDs). Operational amplifiers and their applications. Digital techniques and applications (registers, counters, comparators and similar circuits). A/D and D/A converters. Microprocessor and microcontroller basics.
Data interpretation and analysis. Precision and accuracy. Error analysis, propagation of errors. Least squares fitting,
PART ‘B’ ADVANCED
I. Mathematical Methods of Physics
Green’s function. Partial differential equations (Laplace, wave and heat equations in two and three dimensions). Elements of computational techniques: root of functions, interpolation, extrapolation, integration by trapezoid and Simpson’s rule, Solution of first order differential equation using Runge-Kutta method. Finite difference methods. Tensors. Introductory group theory: SU(2), O(3).
II. Classical Mechanics
Dynamical systems, Phase space dynamics, stability analysis. Poisson brackets and canonical transformations. Symmetry, invariance and Noether’s theorem. Hamilton-Jacobi theory.
III. Electromagnetic Theory
Dispersion relations in plasma. Lorentz invariance of Maxwell’s equation. Transmission lines and wave guides. Radiation- from moving charges and dipoles and retarded potentials.
IV. Quantum Mechanics
Spin-orbit coupling, fine structure. WKB approximation. Elementary theory of scattering: phase shifts, partial waves, Born approximation. Relativistic quantum mechanics: Klein-Gordon and Dirac equations. Semi-classical theory of radiation.
V. Thermodynamic and Statistical Physics
First- and second-order phase transitions. Diamagnetism, paramagnetism, and ferromagnetism. Ising model. Bose-Einstein condensation. Diffusion equation. Random walk and Brownian motion. Introduction to nonequilibrium processes.
VI. Electronics and Experimental Methods
Linear and nonlinear curve fitting, chi-square test. Transducers (temperature, pressure/vacuum, magnetic fields, vibration, optical, and particle detectors). Measurement and control. Signal conditioning and recovery. Impedance matching, amplification (Op-amp based, instrumentation amp, feedback), filtering
and noise reduction, shielding and grounding. Fourier transforms, lock-in detector, box-car integrator, modulation techniques.
High frequency devices (including generators and detectors).
VII. Atomic & Molecular Physics
Quantum states of an electron in an atom. Electron spin. Spectrum of helium and alkali atom. Relativistic corrections for energy levels of hydrogen atom, hyperfine structure and isotopic shift, width of spectrum lines, LS & JJ couplings. Zeeman, Paschen-Bach & Stark effects. Electron spin resonance. Nuclear magnetic resonance, chemical shift. Frank-Condon principle. Born-Oppenheimer approximation. Electronic, rotational, vibrational and Raman spectra of diatomic molecules, selection rules. Lasers: spontaneous and stimulated emission, Einstein A & B coefficients. Optical pumping, population inversion, rate equation. Modes of resonators and coherence length.
VIII. Condensed Matter Physics
Bravais lattices. Reciprocal lattice. Diffraction and the structure factor. Bonding of solids. Elastic properties, phonons, lattice specific heat. Free electron theory and electronic specific heat. Response and relaxation phenomena. Drude model of electrical and thermal conductivity. Hall effect and thermoelectric power. Electron motion in a periodic potential, band theory of solids: metals, insulators and semiconductors. Superconductivity: type-I and type-II superconductors. Josephson junctions. Superfluidity. Defects and dislocations. Ordered phases of matter: translational and orientational order, kinds of liquid crystalline order. Quasi crystals.
IX. Nuclear and Particle Physics
Basic nuclear properties: size, shape and charge distribution, spin and parity. Binding energy, semi-empirical mass formula, liquid drop model. Nature of the nuclear force, form of nucleon-nucleon potential, charge-independence and charge-symmetry of nuclear forces. Deuteron problem. Evidence of shell structure, single-particle shell model, its validity and limitations. Rotational spectra. Elementary ideas of alpha, beta and gamma decays and their selection rules. Fission and fusion. Nuclear reactions, reaction mechanism, compound nuclei and direct reactions.
Classification of fundamental forces. Elementary particles and their quantum numbers (charge, spin, parity, isospin, strangeness, etc.). Gellmann-Nishijima formula. Quark model, baryons and mesons. C, P, and T invariance. Application of symmetry arguments to particle reactions. Parity non-conservation in weak interaction. Relativistic kinematics.

Makaravilakku heals millions

Truth or myth-Makaravilakku and Sabarimala heal many. Let it carry on. Sabarimala pilgrimage is a saunter into the Nature.

Keep open Sabarimala shrine on all days.

The stampede at the Sabarimala shrine in which 104 pilgrims have died indicates that human life is a commodity for Rs 5-6lakh. The money that received by the family of ill-fated pilgrims says we do not value human life that much. Lack of proper schedule for the travel of people to Sabarimala is the root cause of the grave mishap.

To avoid the heavy rush at Makaravilaku season why can’t Devaswom Board make arrangement for keeping the Sabarimala temple opened all the days in a year instead limiting it to 41 days or less. Why the heap of camphor burned at Ponnambalamedu on Makaravilaku day alone? Can’t it be performed a dozen days in a year on other holy days so that pilgrims get more opportunity for a healing thought by viewing it? Again worshippers hating large crowd could also advantageously visit Sabarimala at their pace if the temple is kept opened on all days.

Sabarimala is small area and that is not meant for for huge crowd. It is located at a remote hilly place where easy accessibility is difficult. The government has not provided scientific traffic management despite the huge sum received from the pilgrims as donation and travel fare.

It is better to have an introspection for the people of Kerala than accusing one and the other.

K A Solaman

The sky is the limit

The success or failure of a space mission depends on many factors. The probability of successfully launching a satellite can't be predicted. That's the reason not too many people are criticising the recent failure of the GSLV satellite. The scientists must focus on rectifying technical snags. More than Chandrayaan, India needs more space projects that improve our communication network facility. Chandrayaan can only fetch data already available with Nasa or
similar agencies.
KA Solaman, via email
The Hindustan Times, Jan 2, 2011

Do we need more engineering seats?

May be a pleasant surprise for students but is quite unlikeable for the conventional arts and science colleges in the country, Human Resource Development Minister Kapil Sibal’s announcement of increase of 200,000 seats in engineering courses in India. Already some of the Engineering Colleges in TN and Karnataka are in the verge of collapse due to poor inflow of students and one wonders what prompted Sibal to sanction this much seats in Engineering sector. The huge infrastructure now available with Arts and Science Colleges are poorly utilised at present due to unattractiveness in pursuing conventional education and the present decision of the government would turn the issue worse.

The liberalised scheme now applied to Engineering colleges would not bring results as the minister expect. More focus on technical education would result in lack of interest in pure science study.

K A Solaman

Wishing all a happy 2011

Merry X-mas and Happy new year!

May all of your world be filled with warmth and good chear this Holy season,
and throughout the year.
Wish your Christmas be filled with peace and love.
Merry X-mas friends.

K A Solaman

Blog aministrator at a meeting at Hotel Arcadia, Alappuzha on 20-12-10

Abandon NCERT Physics text books for Plus 2

I am a retired Physics Professor (?) of an affiliated college under University of Kerala and lecturer for many years in graduate classes and erstwhile pre-degree course and still keep some interest in the subject physics. I had already shaped half a dozen First Ranks in B Sc Physics (main) of University of Kerala and hence I believe that I have a few credentials to speak about Physics. My present apprehension is about the prescription of NCERT text books for plus two classes in State Higher Secondary and CBSE schools. The present form of NCERT text books in Physcis would certainly bring hatred among students towards the much lively subject-the physics. Presumably the writers of the present text have no class room experience otherwise they have not presented the subject matter in form of ‘water flood’. What the students get from these text books is little and that is why most teachers use credible text books instead of referring the NCERT text book waste. The teachers ask students to buy NCERT books and never refer to these books while teaching. The teachers have little time to squander by reading all the rubbish in the NCERT books. I sincerely believe those writers of the text book never had been so if they had been asked to follow these text books in their school classes. Though the NCERT claim that their text books are written in conformity international standards, the presentation in foreign books are not so dreary.

The NCERT text book committee may also claim that their books would generate independent thinking among students. This sort of argument is applicable to elite classes. How can a low profile student from a poor family, unable to spell his name correctly in English even in Plus 2, without knowing the basics of Physics, think independently about new rules and ideas in Physics? The government should, therefore, reduce its control on what text book to be followed in schools and teachers and students should be given freedom in following text books.

My suggestion to the Union Human Resource Development Ministry is, ask NCERT to prescribe syllabus and not to write text books or rather compel students community to follow their text books. They can of course supply sample question paper packets and answers to students to augment their studies. The NCERT could, of course, recommend any other suitable text books to school children and if the contents are found to be prejudicial to the integrity of India or the security of the state, the books can be withdrawn. Though the present NCERT text book in Physics does not defame any community, it invites hatred to the subject Physics. Let the students learn Physics pleasantly and lively.

K A Solaman

All teachers’ appointments should be done by the P S C.

Good news to hear that PSC would now carry out the appointments of staff in Universities in Kerala. The decision by the Cabinet is presumably in the backdrop of discrepancies relating to the appointment of the assistants at the university level. Why, then wait for appointment of teachers in University Departments by the P S C. Is it now alright with the appointments in University departments? Are the P S C members appointed on political basis are not competent enough to recruit to the teachers to the Departments.
All appointments including teachers of private colleges where salary is paid from State Exchequer should be transferred to the P S C. The private college managements should not be permitted to sale these posts for a price.

K A Solaman

NET-Electronics qs-Descriptive and problem type

1 What are diode approximations?
A current of 2mA passes through a silicon diode of bulk resistance 25Ω. Find the voltage across the diode
2 Explain a Zener diode voltage regulator.
A 9V regulator power supply is required to run a car stereo system with a 12V battery. A zener diode with Vz= 9V and Pmax =0.25V is used as voltage regulator. Find the value of the series resistor
3 Currents I1 and I2 flow when large voltages V1 and V2 are applied to a semi-conductor diode. If V1 =2 V2 show that the value of the reverse saturation current is I0 = I22 /I1 .
4 Explain transistor as switch. With a diagram explain the voltage divider method of biasing and find the Q-point
5 A silicon transistor with β=55 is used in a voltage divider circuit. If Vcc=22.5V and VBE=0.6V, Rc =5.6K, RE=1K R1=90K, R2=10K find the Q=point and the stability factor.
6 Explain the UJT operation. What is intrinsic stand-off ratio? A UJT has a inter base resistance of 10K. It has RB =6K with IE=0. Find the UJT current if VBB=20V and VE is less that VP. Also find η, VA2 and VP2
7 The saturation drain current of JFET is 8.6mA when the gate voltage is zero. If the pinch-off voltage is -3V, calculate the drain current when the gate voltage is -1V.
8 With a suitable diagram explain the working of Hartley oscillator. Derive an expression for its frequency.
9 A certain radio receiver delivers and output of 3.6W. Find the power output required to produce a power gain of 10dB.
10 An inverting amplifier has Rf=2M and R1=2k. Find its scale factor.
11 What are combination logic gates. \give their logical equations and truth tables
12 How will you implement OR, AND, NOT, NAND using NORs.
13 How will you convert binary code into Gray code? Illustrate with example
14 Design a logic circuit to implement the operation specified in the truth table below
I------n--p-u --t o/p
A B C Y
0 0 0 0
0 0 1 0
0 1 0 0
0 1 1 1
1 0 0 0
1 0 1 1
1 1 0 1
1 1 1 0

Any takers? CSIR-JRF/NET-Physical Science Qs

Atomic and Molecular Physics test-10

Answer all questions Time 30 min
Max 20 marks

1 The maximum frequency of υ of continuous X-ray is related to the applied potential difference V as
a) υ α V1/2 b) υ α V c) υ α V3/2 d) υ α V2
2 Generation of X-ray is a
a) phenomenon of conversion of mass into energy
b) principle of conservation of momentum
c) phenomenon of conversion of kinetic energy into radiant energy
d) none of the above

3 X-rays can be used
a) to cure blood cancer
b) to detect defects in precious stones and diamonds
c) to detect gold under the earth
d) for cutting and welding metals
4 In the production of X-rays by Coolidge tube, intensity and quality of X-rays
a) can be controlled independently
b) cannot be controlled independently
c) are one and the same
d) none of the above
5 The intensity of X-rays mainly depends upon
a)nature of the target material b) nature of the gas in the tube
c) current in the tube d) accelerating voltage applied

6 The maximum frequency of limit of continuous X-rays depend on
a) KE of incident electron b) nature of the target
c) degree of vacuum in the tube
d) the shortest wavelength in the characteristic X-ray spectrum of target material
7 When fast moving electrons strike a metal of high atomic number, the percentage of energy converted with X-rays is
a) about 10% b) about 20% c) less than 10% d) less than 40%

8 In an X-ray tube
a) applied potential is 1000V b) applied potential is 106 V
c) cathode and anode emit electrons d) X-rays move from cathode to anticathode
9 The intensity of X-rays depends on
a) KE of electrons b) number of electrons striking
c) total momentum of electrons d) none of the above
10 X-ray absorption will be a maximum for sheets of
a) Ag b) Pb c) Cu d) Fe

CSIR-JRF/NET-Physical Science

Atomic and Molecular Physics test-7

Answer all questions Time 30 min
Max 20 marks

1 Energy levels A , B, C of a certain atom correspond to increasing values of energy, that is, EA a) λ3 =λ1 + λ2 b) λ3 =λ1. λ2/( λ1 + λ2 )
c) λ1 +λ2 + λ3 =0 d) λ3 =(λ1 + λ2)/2
2 For H-atom, in the lowest energy level, the angular momentum of the electron is
a) h/2π b) h/π c)2 h/π d) 2π/h

3 The angular momentum of the electron in the nth orbit is given by
a) nh b) h/2π n c) nh/2π d) 2π/nh
4 The energy required to remove an electron in a H-atom from n=10 state is
a) 13.6eV b) 1.36eV c) 0.136eV d) 0.0136eV

5 If EN and JN denote the total energy magnitude and angular momentum of an electron in the nth orbit of a Bohr atom, then
a) EN α JN b) EN α 1/JN c) EN α JN2 d) EN α JN2

6 Ionisation potential of hydrogen is 13.6eV. H-atom in the ground state are excited by monochromatic radiation of energy 12.1eV. The spectral lines emitted by hydrogen atom according to Bohr’s theory will be
a) one b) two c) three d) four

7 The ground state energy of H-atom is 13.6eV. The energy needed to ionise H-atom in its second excited state is
a) 1.51eV b) 0 c) -13.6eV d) 6.8eV

8 The total energy of the electron in the H-atom in the ground state is -13.6eV. The KE of this electron is
a) 13.6 b) 0 c) -13.6eV d) 3.4eV

9 The energy levels of a certain atom for first, second and third levels are E, 4E/3 and 2E respectively. A photon of wavelength λ is emitted for a transition 3 to 1. What will be the wavelength of emission for transition 2 to 1
a) λ/ 3 b) 4λ/ 3 c) 3λ/ 4 d) 3λ
10 The series limit of Balmer series is 640nm. The series limit of Paschen series will be
a) 1868nm b) 6400nm c) 240nm d) 1440nm

All Nobel Prizes in Physics

The Nobel Prize in Physics has been awarded 104 times to 189 Nobel Laureates between 1901 and 2010. John Bardeen is the only Nobel Laureate who has been awarded the Nobel Prize in Physics twice, in 1956 and 1972. This means that a total of 188 individuals have received the Nobel Prize in Physics.

2010
Andre Geim, Konstantin Novoselov
2009
Charles Kuen Kao, Willard S. Boyle, George E. Smith
2008
Yoichiro Nambu, Makoto Kobayashi, Toshihide Maskawa
2007
Albert Fert, Peter Grünberg
2006
John C. Mather, George F. Smoot
2005
Roy J. Glauber, John L. Hall, Theodor W. Hänsch
2004
David J. Gross, H. David Politzer, Frank Wilczek
2003
Alexei A. Abrikosov, Vitaly L. Ginzburg, Anthony J. Leggett
2002
Raymond Davis Jr., Masatoshi Koshiba, Riccardo Giacconi
2001
Eric A. Cornell, Wolfgang Ketterle, Carl E. Wieman
2000
Zhores I. Alferov, Herbert Kroemer, Jack S. Kilby
1999
Gerardus 't Hooft, Martinus J.G. Veltman
1998
Robert B. Laughlin, Horst L. Störmer, Daniel C. Tsui
1997
Steven Chu, Claude Cohen-Tannoudji, William D. Phillips
1996
David M. Lee, Douglas D. Osheroff, Robert C. Richardson
1995
Martin L. Perl, Frederick Reines
1994
Bertram N. Brockhouse, Clifford G. Shull
1993
Russell A. Hulse, Joseph H. Taylor Jr.
1992
Georges Charpak
1991
Pierre-Gilles de Gennes
1990
Jerome I. Friedman, Henry W. Kendall, Richard E. Taylor
1989
Norman F. Ramsey, Hans G. Dehmelt, Wolfgang Paul
1988
Leon M. Lederman, Melvin Schwartz, Jack Steinberger
1987
J. Georg Bednorz, K. Alexander Müller
1986
Ernst Ruska, Gerd Binnig, Heinrich Rohrer
1985
Klaus von Klitzing
1984
Carlo Rubbia, Simon van der Meer
1983
Subramanyan Chandrasekhar, William Alfred Fowler
1982
Kenneth G. Wilson
1981
Nicolaas Bloembergen, Arthur Leonard Schawlow, Kai M. Siegbahn
1980
James Watson Cronin, Val Logsdon Fitch
1979
Sheldon Lee Glashow, Abdus Salam, Steven Weinberg
1978
Pyotr Leonidovich Kapitsa, Arno Allan Penzias, Robert Woodrow Wilson
1977
Philip Warren Anderson, Sir Nevill Francis Mott, John Hasbrouck van Vleck
1976
Burton Richter, Samuel Chao Chung Ting
1975
Aage Niels Bohr, Ben Roy Mottelson, Leo James Rainwater
1974
Sir Martin Ryle, Antony Hewish
1973
Leo Esaki, Ivar Giaever, Brian David Josephson
1972
John Bardeen, Leon Neil Cooper, John Robert Schrieffer
1971
Dennis Gabor
1970
Hannes Olof Gösta Alfvén, Louis Eugène Félix Néel
1969
Murray Gell-Mann
1968
Luis Walter Alvarez
1967
Hans Albrecht Bethe
1966
Alfred Kastler
1965
Sin-Itiro Tomonaga, Julian Schwinger, Richard P. Feynman
1964
Charles Hard Townes, Nicolay Gennadiyevich Basov, Aleksandr Mikhailovich Prokhorov
1963
Eugene Paul Wigner, Maria Goeppert-Mayer, J. Hans D. Jensen
1962
Lev Davidovich Landau
1961
Robert Hofstadter, Rudolf Ludwig Mössbauer
1960
Donald Arthur Glaser
1959
Emilio Gino Segrè, Owen Chamberlain
1958
Pavel Alekseyevich Cherenkov, Il´ja Mikhailovich Frank, Igor Yevgenyevich Tamm
1957
Chen Ning Yang, Tsung-Dao (T.D.) Lee
1956
William Bradford Shockley, John Bardeen, Walter Houser Brattain
1955
Willis Eugene Lamb, Polykarp Kusch
1954
Max Born, Walther Bothe
1953
Frits (Frederik) Zernike
1952
Felix Bloch, Edward Mills Purcell
1951
Sir John Douglas Cockcroft, Ernest Thomas Sinton Walton
1950
Cecil Frank Powell
1949
Hideki Yukawa
1948
Patrick Maynard Stuart Blackett
1947
Sir Edward Victor Appleton
1946
Percy Williams Bridgman
1945
Wolfgang Pauli
1944
Isidor Isaac Rabi
1943
Otto Stern
1942
No Nobel Prize was awarded this year. The prize money was with 1/3 allocated to the Main Fund and with 2/3 to the Special Fund of this prize section.
1941
No Nobel Prize was awarded this year. The prize money was with 1/3 allocated to the Main Fund and with 2/3 to the Special Fund of this prize section.
1940
No Nobel Prize was awarded this year. The prize money was with 1/3 allocated to the Main Fund and with 2/3 to the Special Fund of this prize section.
1939
Ernest Orlando Lawrence
1938
Enrico Fermi
1937
Clinton Joseph Davisson, George Paget Thomson
1936
Victor Franz Hess, Carl David Anderson
1935
James Chadwick
1934
No Nobel Prize was awarded this year. The prize money was with 1/3 allocated to the Main Fund and with 2/3 to the Special Fund of this prize section.
1933
Erwin Schrödinger, Paul Adrien Maurice Dirac
1932
Werner Karl Heisenberg
1931
No Nobel Prize was awarded this year. The prize money was allocated to the Special Fund of this prize section.
1930
Sir Chandrasekhara Venkata Raman
1929
Prince Louis-Victor Pierre Raymond de Broglie
1928
Owen Willans Richardson
1927
Arthur Holly Compton, Charles Thomson Rees Wilson
1926
Jean Baptiste Perrin
1925
James Franck, Gustav Ludwig Hertz
1924
Karl Manne Georg Siegbahn
1923
Robert Andrews Millikan
1922
Niels Henrik David Bohr
1921
Albert Einstein
1920
Charles Edouard Guillaume
1919
Johannes Stark
1918
Max Karl Ernst Ludwig Planck
1917
Charles Glover Barkla
1916
No Nobel Prize was awarded this year. The prize money was allocated to the Special Fund of this prize section.
1915
Sir William Henry Bragg, William Lawrence Bragg
1914
Max von Laue
1913
Heike Kamerlingh Onnes
1912
Nils Gustaf Dalén
1911
Wilhelm Wien
1910
Johannes Diderik van der Waals
1909
Guglielmo Marconi, Karl Ferdinand Braun
1908
Gabriel Lippmann
1907
Albert Abraham Michelson
1906
Joseph John Thomson
1905
Philipp Eduard Anton von Lenard
1904
Lord Rayleigh (John William Strutt)
1903
Antoine Henri Becquerel, Pierre Curie, Marie Curie, née Sklodowska
1902
Hendrik Antoon Lorentz, Pieter Zeeman
1901
Wilhelm Conrad Röntgen

Verdict against caste politics.

How miserably the politicians read the public mind, is evident from outbursts of Lalu Prasad Yadav and Ram Vilas Paswan a day before the election results in Bihar.
They claimed a big leap for them in the Bihar Election but unfortunately it was a big blow. NDA leader and CM Nitish Kumar has driven to a remarkable electoral feat by securing 84 percent of the seats in the Bihar Assembly. Lalu, Paswan et al can go to hibernation for next five years and the National Congress leaders have nothing to cheer. Who said the Bihar people are illiterate and are guided by malicious propaganda?

Those who fought the election on the basis of caste in Bihar had been defeated and it is a direct warning to those who resort to caste politics in rest of the country.

K A Solaman

Quick bucks for private colleges!

Many of the affiliated colleges in Kerala are in killing spree in disguise for the appointment of teachers to their various faculties. One of the major handicaps the managements face with, is the lack of NET/JRF qualified candidates with liquid cash in tune with 20 or 30 lakhs. Then, came news from some flip-side doors of the UGC stating that candidates with M Phil can also apply for the posts. On hearing this there was a heavy rush for purchase of application forms from the office-counters of private colleges and it attracted some quick bucks to the managements. The managements were also happy of getting an immediate fortune without much hardships. If demand is high the auction amount is also high.

But unfortunately, soon arrived a clarification from the UGC that candidates should be NET qualified for appointment, sending the management to an immoderate despair. However, the Mundassery II of Kerala is contemplating to dilute the UGC stipulations in collusion with all gluttonous managements.

Will the Managements pay back the application money in tune with Rs 500 or 750 they collected from candidates for one-day clearance sale of application forms? Will the Government check up the rank lists of candidates waiting for appointment in these colleges? Is there any management in Kerala, still waiting to appoint from their lists because of non-compliance of candidates with adequate fund? Will the Government ask private college managements to publish the rank lists on their website, as PSC do, on the very next day after the interview? There should be some corroboration in the acts of private college managements in Kerala because salary to the privileged ones appointed in these colleges, are paid from State exchequer.

K A Solaman

Good news from Myanmar

Report from Myanmar is a matter of relief for the rest of the world. Aung San Suu Kyi has been released by the military rulers of Myanmar. Presumably she could lead her party for the imminent Myanmar general election if the military rulers do not impose further restrictions. Most probably Myanmar’s calming posture by releasing Aung San Suu Kyi was the outcome of U S President Barack Obama stance on the issue. Obama has personally supported for the release of Aung San Suu Kyi during his recent visit to India.

It is good for Myanmar if the rulers of that country so decide to demonstrate faith in Democracy and thereby to avoid further diplomatic isolation from all world countries.

K A Solaman

‘Poet from the gutters’ does not need ceremonial firing.

The ‘poet of the orphans’ has to wait one more day in cold storage for his last rites. Election to local bodies and the inconvenience of the cultural minister, are the reasons for the delay! Undoubtedly it is an insult to a dead man’s corpus. It is quite distressing to see that poet Ayyappan has to tranquilly wait to get opened his way to ‘ Santhikavadam’ and there from to eternal joy.

Hereinafter, celebrities who wish to die, die only after consultation with the cultural stalwarts of Kerala. Who said the ‘poet from the gutters’ need ceremonial firing from shot less guns?

K A Solaman

Will these children ever get through?

Thousands of tiny tots on Vidyarambham day were taken to the world of letters on all parts of Kerala by gurus extending from literary luminaries, cultural leaders and eminent teachers. Interestingly some of the gurus were hard core politicians with wicked Saraswathi on their tongue (name one?). Will these children ever get through in life?

K A Solaman

Chile mine rescue is unprecedented in the history of the world

The last of the 33 trapped Chilean miners was also rescued on Wednesday and that too after having stayed 700 metre underground for more than two months. All of them were elevated one-by-one in a capsule through a narrowly bored hole.
All world were watching the Chilean effort of rescuing their fellow men and everybody prayed from their heart for the success.

K A Solaman