Bảng tuần hoàn hóa học là một bảng sắp xếp các nguyên tố hóa học theo thứ tự tăng dần của số nguyên tử. Nó được sử dụng để tổ chức, phân loại và hiển thị thông tin về các nguyên tố hóa học, bao gồm tên, ký hiệu hóa học, số nguyên tử, khối lượng nguyên tử, cấu trúc điện tử và tính chất hóa học của chúng. Show Hiện tại, bảng tuần hoàn hóa học chứa 118 nguyên tố hóa học. Tuy nhiên, hãy lưu ý rằng số lượng nguyên tố có thể thay đổi theo thời gian do khám phá và nghiên cứu mới.  Bảng tổng hợp đầy đủ tên tiếng Anh của các nguyên tố hóa họcSTT Tên nguyên tố Tên Tiếng Việt Kí hiệu Cách phát âm 1 Hydrogen Hiđrô H /ˈhaɪ.drə.dʒən/ 2 Helium Heli He /ˈhiː.li.əm/ 3 Lithium Liti Li /ˈlɪθ.i.əm/ 4 Beryllium Berili Be /bəˈrɪl.i.əm/ 5 Boron Bari B /ˈbɔːrɒn/ 6 Carbon Cacbon C /ˈkɑːr.bən/ 7 Nitrogen Nitơ N /ˈnaɪ.trə.dʒən/ 8 Oxygen Ôxy O /ˈɒk.sɪ.dʒən/ 9 Fluorine Flo F /ˈflʊər.iːn/ 10 Neon Neon Ne /ˈniː.ɒn/ 11 Sodium Natri Na /ˈsəʊ.di.əm/ 12 Magnesium Magiê Mg /mæɡˈniːziəm/ 13 Aluminum Nhôm Al /əˈluː.mɪ.ni.əm/ 14 Silicon Silic Si /ˈsɪl.ɪ.kən/ 15 Phosphorus Photpho P /ˈfɒs.fər.əs/ 16 Sulfur Lưu huỳnh S /ˈsʌl.fər/ 17 Chlorine Clorin Cl /ˈklɔːr.iːn/ 18 Argon A-go-ni Ar /ˈɑːɡɒn/ 19 Potassium Kali K /pəˈtæs.i.əm/ 20 Calcium Canxi Ca /ˈkæl.si.əm/ 21 Scandium Scanđi Sc /ˈskæn.di.əm/ 22 Titanium Titan Ti /tɪˈteɪ.ni.əm/ 23 Vanadium Vanađi V /vəˈneɪ.di.əm/ 24 Chromium Crôm Cr /ˈkroʊ.mi.əm/ 25 Manganese Mangan Mn /ˈmæŋ.ɡəniz/ 26 Iron Sắt Fe /ˈaɪ.ərn/ 27 Cobalt Coba Co /ˈkoʊ.bɒlt/ 28 Nickel Niken Ni /ˈnɪk.əl/ 29 Copper Đồng Cu /ˈkɑː.pɚ/ 30 Zinc Kẽm Zn /zɪŋk/ 31 Gallium Galli Ga /ˈɡæl.i.əm/ 32 Germanium Gecmani Ge /ˈdʒɜːr.meɪ.ni.əm/ 33 Arsenic Asen Á /ˈɑːr.sə.nɪk/ 34 Selenium Selen Se /sɪˈliː.ni.əm/ 35 Bromine Brom Br /ˈbroʊ.miːn/ 36 Krypton Kripton Kr /ˈkrɪp.tɒn/ 37 Rubidium Rubiđi Rb /ˈruː.bi.di.əm/ 38 Strontium Srotni Sr /ˈstrɒn.ti.əm/ 39 Yttrium Ytri Y /ˈɪtri.əm/ 40 Zirconium Zicroni Zr /zɜːrˈkoʊ.ni.əm/ 41 Niobium Niobi Nb /ˈnaɪ.oʊ.bi.əm/ 42 Molybdenum Molipđen Mo /məˈlɪb.də.nəm/ 43 Technetium Teken Tc /tɛkˈniː.ʃi.əm/ 44 Ruthenium Ruteni Ru /ruːˈθiː.ni.əm/ 45 Rhodium Rôdi Rh /ˈroʊ.di.əm/ 46 Palladium Paladi Pd /pəˈleɪ.di.əm/ 47 Silver Bạc Ag /ˈsɪl.vər/ 48 Cadmium Cadimi Cd /ˈkæd.mi.əm/ 49 Indium Inđi In /ˈɪn.di.əm/ 50 Tin Thiếc Sn /tɪn/ 51 Antimony Antimon Sb /ˈæn.təˌmoʊ.ni/ 52 Tellurium Tellu Te /tɛˈlʊər.i.əm/ 53 Iodine Iot I /ˈaɪ.əˌdiːn/ 54 Xenon Xênon Xe /ˈziː.nɒn/ 55 Cesium Xesi Cs /ˈsiːziəm/ 56 Barium Bari Ba /ˈbɛəriəm/ 57 Lanthanum Lantan La /ˈlæn.θə.nəm/ 58 Cerium Xeri Ce /ˈsɪəriəm/ 59 Praseodymium Praseodi Pr /ˌpreɪz.iˈoʊ.di.mi.əm/ 60 Neodymium Neođim Nd /ˌniː.oʊˈdɪ.mi.əm/ 61 Promethium Promeđi Pm /prəˈmiːθiəm/ 62 Samarium Samari Sm /səˈmɛəriəm/ 63 Europium U-rô-pi Eu /jʊˈroʊpiəm/ 64 Gadolinium Gado-lin Gd /ˌɡædəˈlɪniəm/ 65 Terbium Terbi Tb /ˈtɜrbiəm/ 66 Dysprosium Diprosi Dy /dɪˈsprɒziəm/ 67 Holmium Holmi Ho /ˈhoʊlmiəm/ 68 Erbium Eri Er /ˈɜrbiəm/ 69 Thulium Thu-li Tm /ˈθjuːliəm/ 70 Ytterbium Ytterbi Yb /ˈɪtərbiəm/ 71 Lutetium Lu-tê-xi Lu /luːˈtiːʃiəm/ 72 Hafnium Hafni Hf /ˈhæfniəm/ 73 Tantalum Tan-ta-lum Ta /ˈtæntələm/ 74 Tungsten Tung-xten W /ˈtʌŋstən/ 75 Rhenium Re-ni Re /ˈriːniəm/ 76 Osmium O-xi-um Os /ˈɒzmiəm/ 77 Iridium I-ri-đi-um Ir /ɪˈrɪdiəm/ 78 Platinum Ba-chi Pt /ˈplætɪnəm/ 79 Gold Vàng Au /ɡoʊld/ 0 Mercury Thuỷ ngân Hg /ˈmɜːrkjʊri/ 81 Thallium Talium Tl /ˈθæliəm/ 82 Lead Chì Pb /lɛd/ 83 Bismuth Bizmut Bi /ˈbɪzməθ/ 84 Polonium Poloni Po /pəˈloʊniəm/ 85 Astatine Astatin At /ˈæstətiːn/ 86 Radon Radon Rn /ˈreɪdɒn/ 87 Francium Franxi Fr /ˈfrænsiəm/ 88 Radium Radium Ra /ˈreɪdiəm/ 89 Actinium Actini Ac /ækˈtɪniəm/ 90 Thorium Tori Th /ˈθɔːriəm/ 91 Protactinium Pro-tac-ti-ni Pa /ˌproʊtækˈtɪniəm/ 92 Uranium U-ran U /jʊˈreɪniəm/ 93 Neptunium Nêp-tun Np /nɛpˈtjuːniəm/ 94 Plutonium Plu-toni Pu /pluːˈtoʊniəm/ 95 Americium A-me-ri-xi Am /ˌæməˈrɪsiəm/ 96 Curium Cu-ri-um Cm /ˈkjʊəriəm/ 97 Berkelium Ber-ke-li-um Bk /ˈbɜːrkliəm/ 98 Californium Cali-pho-ni Cf /ˌkælɪˈfɔːrniəm/ 99 Einsteinium A-in-x-tei-ni Es /aɪnˈstaɪniəm/ 100 Fermium Fê-mi Fm /ˈfɜːrmiəm/ 101 Mendelevium Menđelevi Md /ˌmɛndəˈliːviəm/ 102 Nobelium Nobelium No /noʊˈbiːliəm/ 103 Lawrencium Lawrenxi Lr /lɔːˈrɛnsiəm/ 104 Rutherfordium Rutherfordi Rf /ˌrʌðərˈfɔːrdiəm/ 105 Dubnium Đubni Db /ˈduːbniəm/ 106 Seaborgium Si-bor-gi Sg /ˈsiːbɔːrɡiəm/ 107 Bohrium Bo-ri Bh /ˈboʊriəm/ 108 Hassium Ha-xi Hs /ˈhæsiəm/ 109 Meitnerium Meitneri Mt /maɪtˈnɪəriəm/ 110 Darmstadtium Darmstadi Ds /dɑːrmˈʃtɑːtiəm/ 111 Roentgenium Rontgeni Rg /ˈrɛntɡəniəm/ 112 Copernicium Copernici Cn /ˌkoʊpərˈnɪsiəm/ 11 Nihonium Nihoni Nh /ˈniːhoʊniəm/ 114 Flerovium Flerovi Fl /flɛˈroʊviəm/ 115 Moscovium Moscovium Mc /ˈmɒskoʊviəm/ 116 Livermorium Livermorium Lv /ˌlɪvərˈmɔːriəm/ 117 Tennessine Tennessin Ts /tɛˈnɛsiːn/ 118 Oganesson Oganesson Og /ˈoʊɡənɛsən/ Tham khảo: Từ vựng tiếng Anh chuyên ngành hóa học và bài tập vận dụng cơ bản Bài đọc ứng dụng - Chủ đề “Tên tiếng Anh của các nguyên tố hóa học”The Histories Hidden in the Periodic Table From poisoned monks and nuclear bombs to the “transfermium wars,” mapping the atomic world hasn’t been easy. The story of the fifteenth element began in Hamburg, in 1669. The unsuccessful glassblower and alchemist Hennig Brandt was trying to find the philosopher’s stone, a mythical substance that could turn base metals into gold. Instead, he distilled something new. It was foamy and, depending on the preparation, yellow or black. He called it “cold fire,” because it glowed in the dark. Interested parties took a look; some felt that they were in the presence of a miracle. “If anyone had rubbed himself all over with it,” one observer noted, “his whole figure would have shone, as once did that of Moses when he came down from Mt. Sinai.” Robert Boyle, the father of modern chemistry, put some on his hand and noted how “mild and innocent” it seemed. Another scientist saw particles in it twinkling “like little stars.” At first, no one could figure out what the Prometheus of Hamburg had stolen. After one of Brandt’s confidants provided a hint—the main ingredient was “somewhat that belonged to the Body of Man”—Boyle deduced that he and his peers had been smearing themselves with processed urine. As the Cambridge chemist Peter Wothers explains in his new history of the elements, “Antimony, Gold, and Jupiter’s Wolf” (Oxford), Brandt’s recipe called for a ton of urine. It was left out in buckets long enough to attract maggots, then distilled in hot furnaces, creating a hundred and twenty grams of “cold fire.” Brandt believed that, if he could collect enough of this substance, he might be able to create the philosopher’s stone. In 1678, the Duke of Saxony asked him to collect a hundred tons of urine from a garrison of soldiers and render it into what Boyle and others soon started to call phosphorus—Latin for “light-bearer.” The soapy phosphorus that Brandt cooked up was a curiosity. But, in England, Boyle began producing it in a purer, more solid form, which turned out to be highly flammable. Another scientist toying with Boyle’s phosphorus found that “if the Privy Parts be therewith rubbed, they will be inflamed and burning for a good while after.” Boyle, for his part, wondered whether it could be harnessed as a starter for gunpowder. (His assistant, the apothecary Ambrose Godfrey, set his head on fire and burned “two or three great holes in his breeches” while investigating the substance.) The phosphorus industry grew throughout the eighteenth century, in part because physicians wrongly believed that it had medicinal value. In the eighteen-hundreds, match producers found that wood splints tipped with phosphorus were less dangerous than their sulfur-coated predecessors; not long afterward, the discovery that electric furnaces could extract phosphorus from ore at a large scale led to the development of explosives. In the Second World War, in what Wothers calls “a tragic twist of fate,” Hamburg, Brandt’s hometown, was destroyed by Allied bombers dropping phosphorus munitions. Wothers finds many such twists in the stories hidden behind the squares of the periodic table. Antimony (element No. 51) is a lustrous mineral; four thousand years ago, people carved vases out of it, and it appears in cosmetic regimes described in the Old Testament. According to an account given by the seventeenth-century apothecary and alchemist Pierre Pomet (offered up by Wothers as possibly apocryphal), antimony got its name from the story of a German monk who fed it to his fellow brethren. The monk had given some to a few pigs, who vomited at first but then grew healthy and fat. Unfortunately, every monk who ingested it died. “This therefore was the reason of this Mineral being called Antimony,” Pomet wrote, “as being destructive of the Monks.” (In a less fatal episode, a nineteenth-century doctor and his friends consumed fifteen milligrams of tellurium each: they had garlic breath for eight months.) The names of the elements have long been a source of contention and incomprehension. Hydrogen, Wothers points out, is Greek for “water-former,” while oxygen is Greek for “acid-former”; in fact, it’s hydrogen that bonds together with other elements to make acids and oxygen that bonds hydrogen to make water. “Aluminium,” Charles Dickens wrote, in 1856, is “a fossilized part of Latin speech, about as suited to the mouths of the populace as an ichthyosaurus cutlet or a dinornis marrow-bone.” (It has its root in the Latin for “bitter salt,” after the clay from which the once-precious metal was derived; Dickens’s suggestions—“loam-silver” and “glebe-gold”—weren’t much better.) The French chemist Marguerite Perey, a protégée of Marie Curie, discovered an element of her own, in 1939. She wanted to call it “catium,” to honor the particle’s strong attraction to cathodes, devices used to send electricity through a chemical substance; Curie’s daughter, Irène Joliot-Curie, worried that English speakers would associate the element with house cats. Perey, being French, decided to call it francium instead. Many historians date the invention of the periodic table to the publication, a hundred and fifty years ago, of a textbook by the Russian chemist Dmitri I. Mendeleev. But Eric Scerri, the author of “The Periodic Table: Its Story and Its Significance” (Oxford) and a philosopher of chemistry at U.C.L.A.—he studies the history of questions such as “What is an element, really?”—bristles at the notion that Mendeleev revolutionized science when he brought chemical periodicity into clear relief. Periodicity—the idea that larger atoms chime with smaller atoms in a regular way, like notes on a keyboard—didn’t emerge as a bolt from the blue, Scerri argues. It came into focus through the work of a host of scientists; as it did so, ideas that by then were long disdained, such as alchemy, turned out to be right in some respects, and essentially wrong ideas, such as the irreducibility of the elements, turned out to be productive ways of thinking, anyway. Some of the eighteenth- and nineteenth-century chemists who began to notice patterns among certain elements were actually retracing the paths of ancient Greek atomists such as Democritus and Leucippus, who, in the fifth century B.C., had argued that invisible and indivisible particles made up everything we could see and touch. The atomists believed that those particles were myriad in shape and size, and that their perceptible properties came from the structures they formed when they hooked together. By the Middle Ages, atomistic ideas had been mostly eclipsed by Aristotle’s theory that four principal elements—fire, earth, water, and air—combined to form the various objects in the universe. But atomism never went away completely. Renaissance scholars believed in a wide variety of elemental schemes. Wothers’s book reprints some of the diagrams that mixed these ideas in advance of the periodic table: a seventeenth-century engraving of the “seven metals” shows seven Roman gods brandishing ancient chemical symbols (the deities reminded viewers that iron was from Mars and copper from Venus); another shows the seven metals and Aristotle’s four elements in a triangular arrangement. Ringing the whole diagram is a Latin motto: “Although I am invisible, I am nonetheless the father and mother of all visible earthly bodies.” You didn’t have to be a scholar, of course, to believe in a world made up of more than four elements. Seventeenth-century miners, Wothers writes, distinguished between different kinds of air: they called the lighter air that swirled at the top of caves “fire-damp,” because it easily burst into flames, and the heavy clouds that hung near the ground “choke-damp,” because they made it hard to breathe. In the eighteenth century, locals dubbed a cave near Naples the Grotta del Cane: dogs who wandered into the cave, unable to raise their heads above the gas seeping out of the Earth, soon began to choke to death; once returned to the open air, the animals would revive. As these observations proliferated, so did the conviction that there must be many different elements. By the end of the eighteenth century, scientists, combining substances, began realizing that certain materials always reacted in the same proportions, which suggested that they had different underlying masses. (It always seemed to take a little more ammonia than it did magnesia to neutralize the same amount of sulfuric acid.) In 1803, the English scientist John Dalton proposed that atoms were at work in such reactions; he encouraged his peers to help him determine how much these invisible entities weighed. What Scerri calls a “craze for searching for numerical regularities” began. Chemists soon noticed patterns when they grouped elements into sets of three by atomic weight. (Lithium, sodium, and potassium, for example, all fizz or explode in water; it turned out that sodium’s atomic weight is the average of lithium’s and potassium’s.) Such experiments offered glimpses of an order within the elemental universe. But the work was frustrating. In 1836, the chemist Jean Baptiste André Dumas, a disciple of Dalton, threw up his hands in despair. “What remains of the ambitious excursion we allowed ourselves into the domain of atoms?” he wrote. “If I were master I would erase the word ‘atom’ from the science.” Other chemists pressed on. As atomic weights grew more accurate, more patterns emerged. In 1864, the German chemist Julius Lothar Meyer published a table of twenty-eight elements. Meyer’s elements, arranged mostly by increasing weight, were also lined up according to their common chemical properties, which repeated at regular intervals. Five years later, Mendeleev published his own periodic table, which steadily evolved into the version we use today. Like Meyer, Mendeleev had organized his particles into a rough grid, its rows containing elements with similar properties. But he also garnished his table with many tempting question marks and empty spaces, and made explicit elemental prophecies. Mendeleev accurately predicted the existence of then-undiscovered elements, such as gallium and germanium, and foretold their interactions with other elements. Mendeleev’s predictions were wrong as often as they were right. But, Scerri explains, the Russian chemist was a master storyteller and, compared to Meyer and other competitors, a more effective evangelist for the periodic system. Mendeleev took every opportunity to argue, at times heedlessly, that the characteristics of the elements repeat in an orderly and predictable way. He was both indefatigable and inflexible, at least until the tide of scientific opinion turned against him. In the late eighteen-fifties, scientists found that the elemental makeup of a given substance could be deduced from the light that it gave off when set ablaze; in 1868, a French astronomer, Jules Janssen, used the technique to discover helium (element No. 2) on the surface of the sun, during a total solar eclipse. At first, Mendeleev argued that helium could not exist; it had no place on the periodic table. But, around the turn of the twentieth century, after the other noble gases had been discovered and shown to share properties with helium, other scientists made a column just for them, and Mendeleev fell in line. (The column runs along the right, with helium poking out on top). Từ vựng tham khảo:
Tham khảo: Tổng hợp từ vựng tiếng Anh chuyên ngành Y cơ bản thường gặp Tổng kếtTrên đây, bài viết đã chia sẻ một cách đầy đủ và chính xác nhất, kèm theo đó là đoạn trích trong bài viết thú vị về lịch sử của bảng tuần hoàn hóa học. Với nguồn tài liệu này, tác giả bài viết hy vọng người đọc có thể nắm chắc kiến thức và vận dụng linh hoạt, hiệu quả trong công việc của mình. Tài liệu tham khảo: Jahromi, Neima. “The Histories Hidden in the Periodic Table.” The New Yorker, 27 Dec. 2019, www.newyorker.com/science/elements/the-histories-hidden-in-the-periodic-table |
