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VELIKANI LJUDSKE CIVILIZACIJE 12

Simo Jelača
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VELIKANI LjUDSKE CIVILIZACIJE 12

 

Dr SIMO JELAČA
 
MILEVA i ALBERT AJNŠTAJN: Mileva (1875-1948), Albert (1879-1955), švajcarski fizičari
Mileva Marić, Srpkinja, rođena je u Titelu, u Vojvodini, a njen suprug Albert Ajnštajn rođen je u Ulmu, u Nemačkoj. otkrića dvadesetog veka. Mileva je prva došla na ideju o mogućnosti pretvaranja materije u energiju, nakon otkrića rendgenskih zraka, Pupina i Marije Kiri. Ona je veoma uspešno matematički definisala sve svoje ideje. Ona je prva uvela u svet koncept četvorodimenzionalne geometrije (prostor – vreme), a zatim dala definiciju Fotoelektričnog efekta. Mileva i Albert su zajedno radili na elektromagnetnoj teoriji svetlosti, od 1897. i na Teoriji relativnosti od 1901. Po svoj prilici, Milevina disertacija je bila samo Teorija relativnosti (kasnije je nestala sa Univerziteta, verovatno zbog Albertove slave) . Albert Ajnštajn je 1905. objavio tri rada o teorijskoj fizici, uključujući teoriju relativnosti, ali samo pod svojim imenom. Zakon mase i energije izražava se poznatom formulom E=mc2  (energija je jednaka proizvodu mase i kvadrata brzine svetlosti), koja će postati osnova razvoja atomske energije. Oni su takođe potvrdili kvantnu teoriju svetlosti, koja je rezultirala stvaranjem fotoelektrične ćelije (i kao rezultat prenosa slike, televizije). Ovo je rodilo novu granu fizike, kvantnu fiziku. Sva ova dostignuća je Mileva, kao veliki matematičar, matematički definisala, a potpisao ih je samo Albert. Albert je proglašen za najvećeg naučnika dvadesetog veka, a Mileva je ostala anonimna. Albertu je dodeljena Nobelova nagrada za fiziku za 1921. godinu, za koju postoje podaci da je Albert sav novac od te nagrade dao Milevi, dok postoje i tvrdnje da je tim novcem kupio da ćuti. I dok je Marija Kiri radio sa suprugom Pjerom i delila s njim Nobelovu nagradu, Mileva nije dobila nikakvo priznanje od svog muža, čak ni za decu za koju se žrtvovala. Od 1933. do 1955. Albert je živeo i radio na Univerzitetu Prinston, u Sjedinjenim Državama, ali za sve to vreme nije dao nikakav doprinos nauci. Ovo je jedan od dokaza da je sve što je postigao, postigao samo sa Milevom zajedno.
 
FREDERIK SODI (1877-1956), engleski i kanadski hemičar
Rođen u Engleskoj, (Frederick Soddy) se preselio u Kanadu i radio na Univerzitetu McGill u Montrealu sa Ernestom Redfordom, sa kojim je otkrio fenomen atomske dezintegracije (raspada) radioaktivnih elemenata tokom 1901-1903. Radioaktivni elementi se tokom raspadanja transformišu u druge elemente. Sodi je radio na pronalaženju ovih novih elemenata. Primetio je da Periodični sistem elemenata nema dovoljno mesta za sve elemente, pa je 1913. godine došao do jedinstvenog rešenja, primetivši da iako elementi imaju različite atomske težine i periode poluraspada, imaju ista svojstva. To je značilo da je reč o različitim varijacijama istih elemenata. Sodi je ove varijacije nazvao izotopi i time otklonio prethodne nejasnoće. Kasnija otkrića neutrona Džejmsa Čedvika (1891-1974) pružila su mnogo potpunije objašnjenje ovih pojava.
Sodi je takođe dao objašnjenje za alfa čestice (jezgro helijuma), da kada se emituju iz elementa koji se raspada, njegov atomski broj se smanjuje za dva, a atomska težina za četiri. Slično, kada se emituje beta čestica (negativni elektron), atomski broj se povećava za jedan. Na osnovu rezultata rada na izotopima, Sodio je dobio Nobelovu nagradu za hemiju za 1921. godinu.
 
LISA MEITNER (1878-1968), austrijska fizičarka
Nakon doktorata na Univerzitetu Bek, Lise Meitner radi u Berlinu sa Otom Hanom u laboratoriji za nuklearnu fiziku. Zajedno sa njenim sestrićem Otom Frišom, razradili su proces nuklearne fisije (cepanje atoma), koji će kasnije postati veoma vredno otkriće u nuklearnoj fizici. Oto Han joj je pokrao te rezultate i dobio Nobelovu magradu,a da Lisino ime nije ni spomenuo.
 
MILUTIN MILANKOVIĆ (1879-1958), srpski astronom
Milutin Milanković je naučnik čija je Teorija ledenih doba prihvaćena u svetu i potvrđena najnovijim kosmičkim istraživanjima. Rođen je u Dalju, a studije tehnike završio je u Beču, kao jedan od najboljih studenata svoje generacije. Radio je kao inženjer u Austriji, istakao se svojim konstrukcijama i nekim inovacijama, a potom došao u Beograd, gde je postao univerzitetski profesor i radio do kraja života. Ostvario je dela trajne vrednosti i svoje ime upisao među zvezde. Tokom orbite oko Meseca, ruski naučnici dali su ime Milutina Milankovića krateru na nevidljivoj strani Meseca, što je usvojeno kao međunarodno priznanje. Tačnost Milankovićevih proračuna najveća je potvrda njegove teorije koju je nazvao Sunčevim kanonom. Bio je potpredsednik Srpske akademije nauka, ali u svojoj zemlji nedovoljno poznat, čime je inače postupao džentlmenski, tiho, dostojanstveno. Imao je briljantan stil pisanja. Njegova najznačajnija dela su: Kanon osunčavanja zemlje i njegova primena na problem ledenih doba, Nebeska mehanika, Istorija astronomske nauke, Kroz vasionu i vekove, Kroz oblast nauke, Spisi iz istorije nauke a takođe i članci, govori, prepiska, sećanja, iskustva i znanja. Po zanimanju je bio inženjer, a po poslovima astronom i matematičar izuzetnog kvaliteta. Ostao je upamćen i kao istoričar nauke i svedok razvoja srpske nauke u prvoj polovini dvadesetog veka. Milankovićevo delo Kroz vasionu i vekove prvi put je objavljeno na nemačkom jeziku u velikom izdanju, kojim se istakao kao naučnik. U tom delu on na veoma zanimljiv način vodi čitaoca kroz drevni Vavilon, staru Atinu, do poseta Aristotelu i Arhimedu, kroz Aleksandrijsku biblioteku i Kleopatri, a potom i kroz prostranstva vasione. Značajni Milankovićevi radovi su Matematička teorija klime, Astronomski kalendar ledenih doba i Vekovno pomeranje Zemljinih polova. Ako su Keplerov i Njutnov zakon kretanja nebeskih tela prvi zakon univerzuma, onda je Milankovićev zakon osunčavanja njegov drugi zakon. Milanković je prvi u svetu izračunao osunčanost zemlje i svih planeta Sunčevog sistema, što se potvrdilo kao besprekorno tačno. Milankovićeva matematička teorija insolacije je 1995. godine proslavljena u celom svetu kao jedno od najvećih dostignuća ljudskog stvaralaštva dvadesetog veka. Milanković nije učio nauku da bi živeo, već je živeo da bi učio nauke. Milutin Milanković na sebi svojstven način spaja astronomiju, matematiku, fiziku i geofiziku sa književnošću, istorijom i filozofijom. Napravio je i najtačniji kalendar na svetu do sada. On je objasnio Aristarhovo učenje o kretanju planeta Nekretnica, reprodukujući Apolonijevu teoremu o epicikličnim kretanjima planeta u Sunčevom sistemu. On je dokazao da su klimatske promene uzrokovane astronomskim uzrocima, pa se događaji na zemlji odvijaju po zakonima neba. On je prvi u svetu koji je primenio teoriju klime u svojim istraživanjima. Za njega je rečeno „Ako je vrednost planete zaista određena energijom sunca, onda vrednost Milankovićevog dela daje svetlost koju je prenosio na generacije. Ako i za trenutak ta svetlost osvetli naš životni put, Milanković je stigao do cilja svog puta”.
 
ALEKSANDAR FLEMING (1881-1955), škotski bakteriolog
Alexander Flemingg je otkrio penicilin i njime spasio milione ljudskih života. Otkriće penicilina je koliko slučajno toliko i naučno. Flemingovo otkriće plesni Penicillium datira iz 1928. godine, a proizvodnja penicilina počela je tek 1940. godine. Aleksadar Fleming je sin farmera, koji je, dobivši nasledstvo, odlučio da studira medicinu. Tokom svog rada najviše ga je zanimala bakteriologija, pokušavajući da otkrije prirodni lek protiv rasta bakterija, pa je isto tražio čak i u suzama, pljuvački i sluzi. Godine 1922. doživeo je svoj prvi uspeh, praveći prirodni enzim lizozim, a 1928. otkrio je bakteriju Staphilococcus na tanjiru. Slučajno ih je ostavio na vazduhu, pri čemu su se inficirali penicilijem. Tokom Flemingovog godišnjeg odmora, plesni su se razvile i on ih je odneo na ispitivanje. Primetio je da penicilin uništava stafilokoke, što je dovelo do otkrića penicilina koji spasava život. Zajedno sa svojim saradnicima Valterom Florijem i Ernstom Borisom Čejnom, dobio je Nobelovu nagradu za medicinu 1945. godine.
 
HANS GEIGER (1882-1945), nemački fizičar
Hans Geiger je svetu dao Gajgerov brojač, prvi uspešan detektor alfa čestica ili radioaktivnosti. Doktorirao je u Erlangenu u Nemačkoj, a radio je u Mančesteru u Engleskoj, gde je u saradnji sa Ernestom Radefordom 1908. godine konstruisao instrument za detekciju broja alfa čestica koje se emituju tokom radioaktivnog raspada elemenata. Godine 1912. Gajger se vratio u Nemačku, gde je postao šef laboratorije za radioaktivnost u Berlinu. Godine 1928. napravio je savršeniju verziju brojača zajedno sa Valterom Milerom, pa je ta verzija nazvana Gajger-Milerov brojač.
 
NILS BOHR (1885-1962), danski fizičar
Niels Bohr se smatra jednim od najboljih teoretičara atomske fizike. Godine 1913. objavio je rad o sastavu atoma i molekula, a od 1914. do 1916. radio je sa Ernestom Radefordom u Mančesteru. Po povratku u Dansku postavljen je za šefa novoosnovanog Instituta za teorijsku fiziku. Godine 1922. dobio je Nobelovu nagradu za fiziku, a 1943. otputovao je u Ameriku. Od tada je radio u Los Alamosu na projektu atomske bombe. 1955. organizovao je prvu konferenciju Atoms for Pis u Ženevi. Bor je primenio Plankovu kvantnu teoriju na Radefordov model atoma i utvrdio da elektroni postoje u fiksnim orbitama, iz kojih ne emituju energiju. Emisija energije nastaje samo kada elektroni promene svoje stanje, prelazeći sa nižeg na viši energetski nivo. Bor je izračunao energiju zračenja tokom promene energetskih nivoa elektrona u atomu, čime je potvrdio kvantnu teoriju.
Nils Bor je izneo sledeću misao o Nikoli Tesli: „Teslin genijalni pronalazak polifaznog sistema i njegovo istraživanje čudesnih visokofrekventnih električnih fenomena bili su osnova na kojoj su se razvili potpuno novi uslovi za industriju i radio komunikacije i imali su dalekosežne posledice. na čitavu našu civilizaciju“.
 
KLARENS BIRDSAJ (1886-1956), američki pronalazač
Radeći u Labradoru u Kanadi, Clarence Birdseye je uočio prednosti zamrzavanja hrane za njeno dugotrajno očuvanje, pa je napravio prvi uređaj za zamrzavanje, a zatim osnovao kompaniju General Sea Foods 1924. Time je započela proizvodnja rashladnih uređaja za živu hranu. Napravio je i uređaj za uklanjanje vode iz namirnica, takođe kako bi se što bolje sačuvale.
 
ERVIN ŠRODINGER (1887-1961), austrijski fizičar
Ervin Shredding  je, kao matematičar i teorijski fizičar, zastupao principe kvantne mehanike, a radio je na univerzitetu u Berlinu sa Albertom Ajnštajnom. Prema njegovom mišljenju, čestice se ponašaju kao talasi. Tvrdio je da je jednačina Luja de Brolja previše jednostavna i da ne nudi objašnjenje ponašanja materije na subatomskom nivou. Zato je odbacio ideju čestica i zagovarao ideju talasa. Između 1925. i 1926. Sredinger je izrazio talasnu jednačinu, koja je rodila kvantnu mehaniku. Međutim, ova teorija je imala i određene nedostatke, na koje Sredinger nije bio slep. Predložio je tzv Talasni paketi koji daju utisak čestica, ali se u stvarnosti ponašaju kao talasi. Nešto kasnije, Pol Adrijen Moris Dirak (1902-1984) podržao je Šredingerovu teoriju i matematički je tumačio. Za svoja dostignuća podelili su Nobelovu nagradu za fiziku za 1933.
 
HENRI MOZLI (1887-1915), engleski fizičar
Henry Mosley je postao profesor na Univerzitetu u Mančesteru sa 23 godine, a poginuo je u avionskoj nesreći u Turskoj sa 28 godina. Iako je bio mlad, kada se bavio ispitivanjem spektra rendgenskog zračenja na metalima, primetio je frekvenciju spektralnih linija, koje su bile u saglasnosti sa atomskim težinama elemenata. Na osnovu toga je zaključio da je frekvencija zračenja u odnosu na korene određenih celih brojeva, što je označavalo atomske brojeve elemenata, što znači prema njihovom mestu u periodnom sistemu. Zaključio je da su atomski brojevi elemenata jednaki pozitivnom naelektrisanju jezgra njihovih atoma, a to znači broju odgovarajućih negativno naelektrisanih elektrona. Mozli je time utvrdio vitalnu vezu između strukture atoma i njihovih hemijskih svojstava. Shodno tome, videlo se da su svojstva elemenata više u saglasnosti sa atomskim brojevima nego sa atomskim težinama. Uočena su i izvesna odstupanja u periodičnom sistemu Mendeljejeva, koji je prihvaćen kao „Mozlijev zakon”. Mozli je čak predvideo postojanje nekih elemenata sa njihovim atomskim brojevima, težinama i osnovnim svojstvima prema njihovim mestima u tabeli. Nekoliko godina kasnije, ovi elementi su otkriveni i uvršteni u tabelu prema predviđenim mestima.
 
JOHN LOGIE BAIRD (1888-1946), škotski inženjer
John Logie Baird se smatra ocem televizije, koji ju je prvi demonstrirao 1926. Radio je na njoj od 1912, ali tek 1924. lica na ekranu su se mogla prepoznati. Bavio se i radarom i primenom infracrvenog zračenja, na osnovu čega je inovirao video rekorder, prvo snimanje slike na magnetni disk. Demonstrirao je televiziju u boji 1928. godine, a od 1929. godine, formiranjem Britanske radiodifuzne korporacije (BBC), korišćena je i njegova oprema.
Florijem i Ernstom Borisom Čejnom, dobio je Nobelovu nagradu za medicinu 1945. godine.


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GIANTS OF HUMAN CIVILIZATION 12

 

Dr sci. SIMO JELAČA
 
MILEVA and ALBERT EINSTEIN: Mileva (1875-1948), Albert (1879-1955), Swiss physicists
Mileva Maric, a Serb, was born in Titel, Vojvodina, and her husband, Albert Einstein, was born in Ulm, Germany. They met at the Zurich Polytechnic, studied together and came to the discovery of the Theory of Relativity and other great scientific discoveries of the twentieth century. Mileva was the first to come up with the idea of ​​the possibility of converting matter into energy, after the discovery of X-rays, Pupin and Marie Curie. She very successfully defined all her ideas mathematically. She was the first to introduce the concept of four-dimensional geometry (space-time) to the world, and then gave the definition of the Photoelectric effect. Mileva and Albert worked together on the electromagnetic theory of light, from 1897, and on the Theory of Relativity from 1901. In all likelihood, Mileva's dissertation was just the Theory of Relativity (later it disappeared from the University, probably because of Albert's fame). In 1905, Albert Einstein published three papers on theoretical physics, including the theory of relativity, but only under his own name. The mass-energy law is expressed by the famous formula E = m x c″ (energy is equal to the product of mass and the square of the speed of light), which will become the basis of the development of atomic energy. They also confirmed the Quantum Theory of Light, which resulted in the creation of the photoelectric cell (and as a result image transmission, television). This gave birth to a new branch of physics, Quantum Physics. All these accomplishments were mathematically defined by Mileva, as a great mathematician, and only Albert signed them. Albert was declared the greatest scientist of the twentieth century, and Mileva remained anonymous. Albert was awarded the Nobel Prize in Physics for 1921, for which there is information that Albert gave all the money from that prize to Mileva, while there are also claims that he used that money to buy her to hear. And while Marija Kiri radioed with her husband Pjero and shared the Nobel Prize with him, Mileva did not receive any recognition from her husband, not even for the children for whom she sacrificed herself. From 1933 to 1955, Albert lived and worked at Princeton University, in the United States, but during all that time he did not contribute to science. This is one of the proofs that everything he achieved, he achieved only with Milev together.
 
FREDERICK SODDY (1877-1956), English and Canadian chemist
Born in England, Sodi moved to Canada and worked at McGill University in Montreal with Ernest Redford, with whom he discovered the phenomenon of atomic disintegration (decay) of radioactive elements during 1901-1903. Radioactive elements are transformed into other elements during decay. Sodi worked on finding these new elements. He noticed that the Periodic Table of Elements does not have enough places for all the elements, so in 1913 he came up with a unique solution, noticing that the elements, although they have different atomic weights and half-lives, have the same properties. This meant that it was about different variations of the same elements. Sodi called these variations Isotopes and thereby removed the previous ambiguities. The later discoveries of neutrons by James Chadwick (1891-1974) provided a much more complete explanation of these phenomena.
Sodi also gave an explanation for alpha particles (helium nucleus), that when they are emitted from an element that decays, its atomic number decreases by two, and its atomic weight by four. Similarly, when a beta particle (negative electron) is emitted, the atomic number increases by one. Based on the results of the work on isotopes, Sodio was awarded the Nobel Prize in Chemistry for 1921.
 
LISE MEITNER (1878-1968), Austrian physicist
After her doctorate at Beck University, Lisa Mitner works in Berlin with Otto Hahn in the nuclear physics laboratory. Together with his sister Otto Frisch, they worked out the process of nuclear fission (splitting of atoms), which would later become a very valuable discovery in nuclear physics.
 
MILUTIN MILANKOVIC (1879-1958), Serbian astronomer
Milutin Milankovic is a scientist whose Theory of Ice Ages is accepted in the world and confirmed by the latest cosmic research. He was born in Dalje, and completed his technical studies in Vienna, as one of the best students of his generation. He worked as an engineer in Austria, distinguished himself with his constructions and some innovations, and then came to Belgrade, where he became a university professor and worked until the end of his life. He accomplished works of lasting value and wrote his name among the stars. During the orbit around the moon, Russian scientists gave the name of Milutin Milankovic to a crater on the invisible side of the moon, which was adopted as an international recognition. The accuracy of Milankovicevic's calculations is the biggest confirmation of his theory, which he called the Sunning Canon. He was the vice-president of the Serbian Academy of Sciences, yet not well-known in his country, which he otherwise handled in a gentlemanly, quiet, and dignified manner. He had a brilliant writing style. His most significant works are: The canon of insolation of the earth and its application to the problem of ice ages, Celestial mechanics, History of astronomical science, Through the universe and the ages, Through the realm of science, Writings from the history of science and also Articles, Speeches, Correspondence, Memories, Experiences and Knowledge. He was an engineer by profession, and by works an astronomer and mathematician of extraordinary quality. He was also remembered as a historian of science and a witness to the development of Serbian science in the first half of the twentieth century. Milankovic's work Through the Universe and Centuries was first published in German in a large edition, with which he excelled as a scientist. In that part, he leads the reader in a very interesting way through ancient Babylon, old Athens, to visits to Aristotle and Archimedes, through the Alexandrian library and to Cleopatra, and then through the vastness of the universe. Milankovic's important works are the Mathematical Theory of Climate, the Astronomical Calendar of the Ice Ages, and the Centuries' Shift of the Earth's Poles. If Kepler's and Newton's laws of motion of celestial bodies are the first law of the universe, then Milankovic's Law of insolation is its second law. Milankovic was the first in the world to calculate the insolation of the earth and all the planets of the solar system, which was confirmed as impeccably accurate. Milankovic's mathematical theory of insolation was celebrated in 1995 throughout the world as one of the greatest achievements of human creativity of the twentieth century. Milankovic did not study science to make a living, he lived to study science. Milutin Milankovic combines astronomy, mathematics, physics and geophysics with literature, history and philosophy in his own unique way. He also created the most accurate calendar in the world so far. He explained Aristarchus' teaching about the movement of the planets Nekretnica, reproducing Apollonius' theorem of epicyclic movements of the planets in the solar system. He proved that climate changes are caused by astronomical causes, therefore events on earth take place according to the laws of heaven. He is the first in the world to apply climate theory in his research. It was said about him, "If the value of the planet is really determined by the energy of the sun, then the value of Milankovic's work is given by the light that he passed on to generations. If even for a moment that light illuminates our life path, Milankovic has reached the goal of his journey".
 
ALEXANDER FLEMING (1881-1955), Scottish bacteriologist
Fleming discovered Penicillin and saved millions of human lives with it. The discovery of penicillin was as accidental as it was scientific. Fleming's discovery of the mold Penicillium dates back to 1928, and the production of penicillin began only in 1940. Aleksadar Fleming is the son of a farmer, who, having received an inheritance, decided to study medicine. During his work, he was most interested in bacteriology, trying to discover a natural remedy against the growth of bacteria, so he looked for the same even in tears, saliva and mucus. In 1922, he experienced his first success, making the natural enzyme Lysozyme, and in 1928 he discovered Staphylococcus bacteria on a plate. He accidentally left them exposed to the air, on which occasion they became infected with penicillium. During Fleming's annual vacation, the molds developed and he took them for examination. He noticed that penicillium destroyed staphylococcus, which led to the discovery of life-saving Penicillin. Together with his collaborators Walter Florey and Ernst Boris Chain, he received the Nobel Prize for Medicine in 1945.
 
HANS GEIGER (1882-1945), German physicist
Hans Geiger gave the world the Geiger counter, the first successful detector of alpha particles or radioactivity. He received his doctorate in Erlangen, Germany, and worked in Manchester, England, where, working with Ernest Radeford, he constructed an instrument for detecting the number of alpha particles emitted during the radioactive decay of elements in 1908. In 1912, Geiger returned to Germany, where he became the head of the laboratory for radioactivity in Berlin. In 1928, he made a more perfect version of the counter together with Walter Miller, so that version was called the Geiger-Miller counter.
 
NIELS BOHR (1885-1962), Danish physicist
Nils Bohr is considered one of the best theorists of atomic physics. In 1913 he published a paper on the composition of atoms and molecules, and from 1914 to 1916 he worked with Ernest Radeford in Manchester. Upon his return to Denmark, he was appointed head of the newly founded Institute for Theoretical Physics. In 1922 he received the Nobel Prize in Physics, and in 1943 he traveled to America. Since then he worked at Los Alamos on the atomic bomb project. In 1955, he organized the first conference on Atoms for Peace in Geneva. Bohr applied Planck's quantum theory to Radeford's model of the atom and established that electrons exist in fixed orbits, from which they do not emit energy. Energy emission occurs only when electrons change their state, moving from a lower to a higher energy level. Bohr calculated the energy of radiation during the change of energy levels of electrons in an atom, thereby confirming the Quantum Theory.
Nils Bohr expressed the following thought about Nikola Tesla: "Tesla's ingenious invention of the polyphase system and his research into wondrous high-frequency electrical phenomena were the basis on which completely new conditions for industry and radio communications were developed and had a far-reaching impact on our entire civilization."
 
CLARENCE BIRDSEYE (1886-1956), American inventor
Working in Labrador, Canada, Clarence Birds noticed the advantages of freezing food for its long-term preservation, so he built the first freezing device and then founded the General Sea Foods Company in 1924. This started the production of refrigeration devices for live foods. He also made a device for removing water from foodstuffs, also in order to preserve them better.
 
ERWIN SCHRODINGER (1887-1961), Austrian physicist
Srödinger, as a mathematician and theoretical physicist, advocated the principles of quantum mechanics, and worked at the university in Berlin with Albert Einstein. According to his opinion, particles behave like waves. He claimed that Louis de Broglie's equation is too simple and does not offer an explanation of the behavior of matter at the subatomic level. That is why he rejected the idea of ​​particles and advocated the idea of ​​waves. Between 1925 and 1926, Srödinger expressed the wave equation, which gave birth to Quantum Mechanics. However, this theory also had certain shortcomings, to which Srödinger was not blind. He proposed the so-called Wave packets that give the impression of particles but in reality behave like waves. A little later, Paul Adrien Maurice Dirac (1902-1984) supported Srödinger's theory and interpreted it mathematically. For their achievements, they shared the Nobel Prize in Physics for 1933.
 
HENRY MOSELEY (1887-1915), English physicist
Henri Mosley became a professor at the University of Manchester at the age of 23, and died in a plane crash in Turkey at the age of 28. Although he was young, when he was engaged in X-radiation spectra tests on metals, he noted the frequency of spectral lines, which were in agreement with the atomic weights of the elements. On this basis, he concluded that the frequency of radiation is in relation to the roots of certain whole numbers, which indicated the atomic numbers of the elements, which means according to their place in the periodic table. He concluded that the atomic numbers of elements are equal to the positive charge of the nucleus of their atoms, and that means the number of corresponding negatively charged electrons. Mosli thereby determined the vital connection between the structure of atoms and their chemical properties. Accordingly, it was seen that the properties of the elements are more in agreement with the atomic numbers than with the atomic weights. Certain discrepancies in Mendeleev's periodic system were also noticed, which was accepted as "Moseley's Law". Mosley even predicted the existence of some elements with their atomic numbers, weights and basic properties according to their places in the table. A few years later, these elements were discovered and included in the table according to the predicted places.
 
JOHN LOGIE BAIRD (1888-1946), Scottish engineer
John Beard is considered the father of television, who first demonstrated it in 1926. He had been working on it since 1912, but it was not until 1924 that faces on the screen could be recognized. He also worked on radar and the application of infrared radiation, on the basis of which he innovated the video recorder, the first image recording on a magnetic disk. He demonstrated color television in 1928, and from 1929, with the formation of the British Broadcasting Corporation (BBC), his equipment was also used.


 To be continued...

 
 

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