STEPHEN HAWKING

Stephen William Hawking, CH, CBE, FRS, FRSA (born 8 January 1942)[1] is a British theoretical physicist and cosmologist, whose scientific books and public appearances have made him an academic celebrity. He is an Honorary Fellow of the Royal Society of Arts,[2] a lifetime member of the Pontifical Academy of Sciences,[3] and in 2009 was awarded the Presidential Medal of Freedom, the highest civilian award in the United States.[4]

Hawking was the Lucasian Professor of Mathematics at the University of Cambridge for 30 years, taking up the post in 1979 and retiring on 1 October 2009.[5][6] He is now Director of Research at the Centre for Theoretical Cosmology in the Department of Applied Mathematics and Theoretical Physics at the University of Cambridge. He is also a Fellow of Gonville and Caius College, Cambridge and a Distinguished Research Chair at the Perimeter Institute for Theoretical Physics in Waterloo, Ontario.[7] He is known for his contributions to the fields of cosmology and quantum gravity, especially in the context of black holes. He has also achieved success with works of popular science in which he discusses his own theories and cosmology in general; these include the runaway best seller A Brief History of Time, which stayed on the British Sunday Times best-sellers list for a record-breaking 237 weeks.[8][9]

Hawking's key scientific works to date have included providing, with Roger Penrose, theorems regarding gravitational singularities in the framework of general relativity, and the theoretical prediction that black holes should emit radiation, which is today known as Hawking radiation (or sometimes as Bekenstein–Hawking radiation).[10]

Hawking has a motor neurone disease that is related to amyotrophic lateral sclerosis, a condition that has progressed over the years and has left him almost completely.

EARLY LIFE
Stephen Hawking was born on 8 January 1942 to Dr. Frank Hawking, a research biologist, and Isobel Hawking. He had two younger sisters, Philippa and Mary, and an adopted brother, Edward.[11] Though Hawking's parents were living in North London, they moved to Oxford while his mother was pregnant with Stephen, desiring a safer location for the birth of their first child. (London was under attack at the time by the Luftwaffe.)[12] According to Hawking, a German V-2 missile struck only a few streets away.[13]

After Hawking was born, the family moved back to London, where his father headed the division of parasitology at the National Institute for Medical Research.[11] In 1950, Hawking and his family moved to St Albans, Hertfordshire, where he attended St Albans High School for Girls from 1950 to 1953. (At that time, boys could attend the Girls' school until the age of ten.)[14] From the age of eleven, he attended St Albans School, where he was a good, but not exceptional, student.[11] When asked later to name a teacher who had inspired him, Hawking named his mathematics teacher Dikran Tahta.[15] He maintains his connection with the school, giving his name to one of the four houses and to an extracurricular science lecture series. He has visited it to deliver one of the lectures and has also granted a lengthy interview to pupils working on the school magazine, The Albanian.

Hawking was always interested in science.[11] Inspired by his mathematics teacher, he originally wanted to study the subject at university. However, Hawking's father wanted him to apply to University College, Oxford, where his father had attended. As University College did not have a mathematics fellow at that time, it would not accept applications from students who wished to read that discipline. Hawking therefore applied to read natural sciences, in which he gained a scholarship. Once at University College, Hawking specialised in physics.[12] His interests during this time were in thermodynamics, relativity, and quantum mechanics. His physics tutor, Robert Berman, later said in The New York Times Magazine:

It was only necessary for him to know that something could be done, and he could do it without looking to see how other people did it. [...] He didn't have very many books, and he didn't take notes. Of course, his mind was completely different from all of his contemporaries.[11]

Hawking was passing, but his unimpressive study habits[16] resulted in a final examination score on the borderline between first and second class honours, making an "oral examination" necessary. Berman said of the oral examination:

And of course the examiners then were intelligent enough to realize they were talking to someone far more clever than most of themselves.[11]

After receiving his B.A. degree at Oxford in 1962, he stayed to study astronomy. He decided to leave when he found that studying sunspots, which was all the observatory was equipped for, did not appeal to him and that he was more interested in theory than in observation.[11] He left Oxford for Trinity Hall, Cambridge, where he engaged in the study of theoretical astronomy and cosmology.

CAREER 
Almost as soon as he arrived at Cambridge, he started developing symptoms of amyotrophic lateral sclerosis (ALS, known colloquially in the United States as Lou Gehrig's disease), a type of motor neurone disease which would cost him almost all neuromuscular control. During his first two years at Cambridge, he did not distinguish himself, but, after the disease had stabilised and with the help of his doctoral tutor, Dennis William Sciama, he returned to working on his PhD.[11]

Hawking was elected as one of the youngest Fellows of the Royal Society in 1974, was created a Commander of the Order of the British Empire in 1982, and became a Companion of Honour in 1989. Hawking is a member of the Board of Sponsors of the Bulletin of the Atomic Scientists.

In 1974, he accepted the Sherman Fairchild Distinguished Scholar visiting professorship at the California Institute of Technology (Caltech) to work with his friend, Kip Thorne, who was a faculty member there.[17] He continues to have ties with Caltech, spending a month each year there since 1992.[18]

Hawking's achievements were made despite the increasing paralysis caused by the ALS. By 1974, he was unable to feed himself or get out of bed. His speech became slurred so that he could be understood only by people who knew him well. In 1985, he caught pneumonia and had to have a tracheotomy, which made him unable to speak at all. A Cambridge scientist built a device that enables Hawking to write onto a computer with small movements of his body, and then have a voice synthesiser speak what he has typed.[19

RESEARCH 
Hawking's principal fields of research are theoretical cosmology and quantum gravity.

In the late 1960s, he and his Cambridge friend and colleague, Roger Penrose, applied a new, complex mathematical model they had created from Albert Einstein's theory of general relativity.[20] This led, in 1970, to Hawking proving the first of many singularity theorems; such theorems provide a set of sufficient conditions for the existence of a gravitational singularity in space-time. This work showed that, far from being mathematical curiosities which appear only in special cases, singularities are a fairly generic feature of general relativity.[21]

He supplied a mathematical proof, along with Brandon Carter, Werner Israel and D. Robinson, of John Wheeler's no-hair theorem – namely, that any black hole is fully described by the three properties of mass, angular momentum, and electric charge.

Hawking also suggested upon analysis of gamma ray emissions that after the Big Bang, primordial mini black holes were formed. With Bardeen and Carter, he proposed the four laws of black hole mechanics, drawing an analogy with thermodynamics. In 1974, he calculated that black holes should thermally create and emit subatomic particles, known today as Bekenstein-Hawking radiation, until they exhaust their energy and evaporate.[22]

In collaboration with Jim Hartle, Hawking developed a model in which the universe had no boundary in space-time, replacing the initial singularity of the classical Big Bang models with a region akin to the North Pole: one cannot travel north of the North Pole, as there is no boundary. While originally the no-boundary proposal predicted a closed universe, discussions with Neil Turok led to the realisation that the no-boundary proposal is also consistent with a universe which is not closed.

Along with Thomas Hertog at CERN, in 2006 Hawking proposed a theory of "top-down cosmology," which says that the universe had no unique initial state, and therefore it is inappropriate for physicists to attempt to formulate a theory that predicts the universe's current configuration from one particular initial state.[23] Top-down cosmology posits that in some sense, the present "selects" the past from a superposition of many possible histories. In doing so, the theory suggests a possible resolution of the fine-tuning question: It is inevitable that we find our universe's present physical constants, as the current universe "selects" only those past histories that led to the present conditions. In this way, top-down cosmology provides an anthropic explanation for why we find ourselves in a universe that allows matter and life, without invoking an ensemble of multiple universes.

Hawking's many other scientific investigations have included the study of quantum cosmology, cosmic inflation, helium production in anisotropic Big Bang universes, large N cosmology, the density matrix of the universe, topology and structure of the universe, baby universes, Yang-Mills instantons and the S matrix, anti de Sitter space, quantum entanglement and entropy, the nature of space and time, including the arrow of time, spacetime foam, string theory, supergravity, Euclidean quantum gravity, the gravitational Hamiltonian, Brans-Dicke and Hoyle-Narlikar theories of gravitation, gravitational radiation, and wormholes.

At a George Washington University lecture in honour of NASA's fiftieth anniversary, Hawking theorised on the existence of extraterrestrial life, believing that "primitive life is very common and intelligent life is fairly rare."[24]

 
 

LATEST INVENTIONS

                                                              1.  Lithium Batteries Lithium batteries have a lithium anode. They are available as both primary batteries and secondary batteries. Search by Specification | Learn More about Lithium Batteries
Voltage:
Less than 3 volts
3 to 4 volts
4 to 6 volts
6 to 10 volts
10 volts and up
Capacity, Amp Hours (AH):
At least 0.5 ampere-hr
At least 1 ampere-hr
At least 2 ampere-hr
At least 4 ampere-hr
Lithium Primary Batteries:
Lithium / Thionyl Chloride
Lithium / Manganese Dioxide
This article is about disposable primary batteries. For rechargeable batteries, see Lithium-ion battery. CR2032 lithium button cell battery

Lithium 9 volt, AA, & AAA sizes
Lithium batteries are disposable (primary) batteries that have lithium metal or lithium compounds as an anode. Depending on the design and chemical compounds used, lithium cells can produce voltages from 1.5 V to about 3.7 V, over twice the voltage of an ordinary zinc–carbon battery or alkaline battery.[1] Lithium batteries are widely used in products such as portable consumer electronic devices.

Lithium primary batteries account for 28% of all primary battery sales in Japan but only 1% of all battery sales in Switzerland. In the UK and EU only 0.5% of all battery sales including secondary types are lithium primaries.
DESCRIPTION
The term "lithium battery" refers to a family of different chemistries, comprising many types of cathodes and electrolytes.
The most common type of lithium cell used in consumer applications uses metallic lithium as anode and manganese dioxide as cathode, with a salt of lithium dissolved in an organic solvent.
 Disassembled CR2032 battery From left — negative cup from inner side with layer of lithium (oxidized in air), separator(porous material), cathode (manganese dioxide), metal grid — current collector, metal casing (+)(damaged during opening the cell), on the bottom is plastic sealing ring
Another type of lithium cell having a large energy density is the lithium-thionyl chloride cell. Lithium-thionyl chloride batteries are generally not sold to the consumer market, and find more use in commercial/industrial applications, or are installed into devices where no consumer replacement is performed. In this cell, a liquid mixture of thionyl chloride (SOCl2) and lithium tetrachloroaluminate (LiAlCl4) acts as the electrolyte and cathode respectively. A porous carbon material serves as a cathode current collector which receives electrons from the external circuit. Lithium-thionyl chloride batteries are well suited to extremely low-current applications where long life is necessary, such as wireless alarm systems.

                                                2.  SafeGard Water Based Rust Preventatives 
SafeGard water based rust preventatives prevent rust safely, effectively and economically for both indoor and outdoor storage conditions. These anti corrosion resistant coatings are stable, non-flammable, non-toxic, non-reversible emulsions are easy to apply, quick draining and quick drying. Although they normally dry to a clear or translucent brown film, these rust proofing products may be dyed if so desired. The corrosion resistant barrier coating can achive corrosion protection with varying film hardness from very soft to very hard. This product can be applied by brush, spray or dip coating. SafeGard reduces plant clean up, all you have to do is simply wash everything down with water. If spray equipment is used, run water through it until it is clear.
Stop rust and corrosion before it starts with SafeGard H water based coating. In just one coat, corrosion control is achieved by using a waterborne barrier coating that contains a balanced corrosion inhibitor system. This corrosion prevention product dries to a translucent light brown dry to the touch wax coating. Dyes may be added if color coding your supplier or customers parts is desired. 
This firm corrosion resistant coating will not transfer, abrade or run under normal handling. The floor of your packaging area, storage bins or packages sent to your customers will not be oil stained and messy. SafeGard's active corrosion inhibitor system neutralizes metal corrosion normally attributed to fingerprints from parts handling. This protective coating and its chemical system are compatible with lube oil so they need not need to be removed from internal engine parts before assembly.
This high performance corrosion resistant coating will give your parts over 2000 hours humidity performance and over 336 hours protection in the standard ASTM B-117 salt spray performance cabinet. SafeGard H meets the performance requirements of specification MIL-C-16173D grade II.

SafeGard H is OSHA & EPA friendly because it contains no toxic or harmful materials. This rust prevention coating should be allowed to cure for 1 day before being put into service. To remove the protective coating use a simple alkaline cleaner such as Safegard 11085A. This anti corrosion material can be easily applied by spray, brush, dip coating or roller. Spray equipment should be rinsed out with water at the end of the day. SafeGard H is rust proofing for long-term indoor or medium term outdoor storage. SafeGard H coverage is 650-700 sqft/gallon @ 1.5 mils thickness.

                                                        3.Building Human Organs 
Oganovo is a company based in San Diego, California.
Their latest science invention is a technology (novogen) which allows living tissue cells to be assembled into patterns and complex structures, such as organs.
Organovo has partnered with Invetech. a company based in Australia, to develop a bio-printer.

The device prints (places) human cells in a three-dimensional matrix to construct human tissue.

"Building human organs cell-by-cell was considered science fiction not that long ago," says Fred Davis of Invetech.

Currently, the bio-printer can grow blood vessels.
It is anticipated that within five years the device will construct arteries and by 2020 sophisticated organs will be built by the device.
 
                                                        4.   Batteries That Operate With Any Liquid 
Chungpin Liao, a professor at the Graduate School of Electro-Optic and Material Science of National Formosa University in Taiwan has invented an organic battery that creates electricity when wet.
The "organic" battery generates a charge within 10 seconds and will last anywhere from two days to a week depending on the liquid. It works with water, beverages or even urine.
Although it will only produce half the strength of traditional batteries, the organic battery has a storage capacity greater than water-powered fuel cells and is very cheap to manufacture.
"Plus it contains no toxic substances and does not pose an environmental hazard" says Chungpin.
Liao received his degree in nuclear engineering from National Tsing Hua University in Hsinchu, Taiwan. He earned his Masters and Ph.D degrees in plasma science and fusion technology from the Massachusetts Institute of Technology in Cambridge, United States.
 

 

 

 

HISTORY OF SCIENCE AND TECHNOLOGY

The history of science and technology (HST) is a field of history which examines how humanity's understanding of the natural world (science) and ability to manipulate it (technology) have changed over the centuries. This academic discipline also studies the cultural, economic, and political impacts of scientific innovation.
Histories of science were originally written by practicing and retired scientists, starting primarily with William Whewell, as a way to communicate the virtues of science to the public. In the early 1930s, after a famous paper given by the Soviet historian Boris Hessen,was focused into looking at the ways in which scientific practices were allied with the needs and motivations of their context. After World War II, extensive resources were put into teaching and researching the discipline, with the hopes that it would help the public better understand both science and technology as they came to play an exceedingly prominent role in the world. In the 1960s, especially in the wake of the work done by Thomas Kuhn, the discipline began to serve a very different function, and began to be used as a way to critically examine the scientific enterprise. At the present time it is often closely aligned with the field of Science studies.

Modern engineering as it is understood today took form during the scientific revolution, though much of the mathematics and science was built on the work of the Greeks, Egyptians, Mesopotamians, Chinese, Indians and Muslims. See the main articles History of science and History of technology for these respective topics.
India
Banaras Hindu University has programs: one in History of science and Technology at the Faculty of Science and one in Historical and Comparative Studies of the Sciences and the Humanities at the Faculty of Humanities.
 

SCIENCE UPDATES

1.New Research On Body Parts' Sensitivity to Environmental Changes
ScienceDaily (Nov. 21, 2011) — Research by a team of Michigan State University scientists has shed new light on why some body parts are more sensitive to environmental change than others, work that could someday lead to better ways of treating a variety of diseases, including type 2 diabetes.
2.Evidence Supports Ban On Growth Promotion Use of Antibiotics in Farming
ScienceDaily (Nov. 15, 2011) — In a review study, researchers from Tufts University School of Medicine zero in on the controversial, non-therapeutic use of antibiotics in food animals and fish farming as a cause of antibiotic resistance. They report that the preponderance of evidence argues for stricter regulation of the practice. Stuart Levy, an expert in antibiotic resistance, notes that a guiding tenet of public health, the precautionary principle, requires that steps be taken to avoid harm. 
3.Financial Incentives to Reduce Risky Health Behaviors?
ScienceDaily (Nov. 21, 2011) — Financial incentives work for doctors. Could they work for patients, too? Could they encourage them to change unhealthy behaviors and use preventive health services more? In some cases, yes, according to Dr. Marita Lynagh from the University of Newcastle in Australia, and colleagues. Their work, looking at why financial incentives for patients could be a good thing to change risky health behaviors, indicates that incentives are likely to be particularly effective at altering 'simple' behaviors e.g. take-up of immunizations, primarily among socially disadvantaged groups.
4.Regeneration After a Stroke Requires Intact Communication Channels Between Brain Hemispheres
ScienceDaily (Nov. 21, 2011) — The structure of the corpus callosum, a thick band of nerve fibres that connects the two halves of the brain with each other and in this way enables the rapid exchange of information between the left and right hemispheres, plays an important role in the regaining of motor skills following a stroke. A study currently published in the journal Human Brain Mapping has shown that in stroke patients with particularly severely impaired hand movement, this communication channel between the two brain hemispheres in particular was badly damaged.      

SCIENCE UPDATES

1.Producing Flexible CIGS Solar Cells With Record Efficiency
ScienceDaily (Sep. 23, 2011) — The technology yielding flexible solar cells with an 18.7% record efficiency developed by scientists at Empa, the Swiss Federal Laboratories for Materials Science and Technology, has now been published in Nature Materials. Key to the breakthrough is the control of the energy band gap grading in the copper indium gallium (di)selenide semiconductor, also known as CIGS, the layer that absorbs light and converts it into electricity. The Empa team achieved this by controlling the vapor flux of elements during different stages of the evaporation process for growing the CIGS layer. 
2. Novel Technique Reveals Both Gene Number and Protein Expression Simultaneously
ScienceDaily (Sep. 23, 2011) — Researchers have discovered a method for simultaneously visualizing gene number and protein expression in individual cells. The fluorescence microscopy technique could permit a detailed analysis of the relationship between gene status and expression of the corresponding protein in cells and tissues, and bring a clearer understanding of cancer and other complex diseases, according to researchers who led the study.
3.  Amazing Electrical Properties in Polymers Discovered
ScienceDaily (Sep. 25, 2011) — Crystals and ceramics pale when compared to a material researchers at Oak Ridge National Laboratory discovered that has 10 times their piezoelectric effect, making it suitable for perhaps hundreds of everyday uses. 
4.Reports of Mental Health Disability Increase in United States
 ScienceDaily (Sep. 23, 2011) — The prevalence of self-reported mental health disabilities increased in the U.S. among non-elderly adults during the last decade, according to a study by Ramin Mojtabai, MD, PhD, of the Johns Hopkins Bloomberg School of Public Health. At the same time, the study found the prevalence of disability attributed to other chronic conditions decreased, while the prevalence of significant mental distress remained unchanged.