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Updated on 21st August, 2023 , 6 min read
The arrangement of the chemical elements in rows and columns is known as the chemical periodic table or the periodic table of the (chemical) elements. It is frequently used in physics, chemistry, and other sciences and is frequently regarded as a symbol of chemistry. It is a visual representation of the periodic law, which states that the atomic numbers of chemical elements have a roughly periodic relationship with their properties. The table is divided into four blocks that are roughly rectangular in shape. The table's columns are referred to as groups, and its rows are known as periods.
The following periodic table of elements is sorted by atomic number-
Atomic Number | Symbol | Name | Atomic Mass |
1 | H | Hydrogen | 1.00797 |
2 | He | Helium | 4.00260 |
3 | Li | Lithium | 6.941 |
4 | Be | Beryllium | 9.01218 |
5 | B | Boron | 10.81 |
6 | C | Carbon | 12.011 |
7 | N | Nitrogen | 14.0067 |
8 | O | Oxygen | 15.9994 |
9 | F | Fluorine | 18.998403 |
10 | Ne | Neon | 20.179 |
11 | Na | Sodium | 22.98977 |
12 | Mg | Magnesium | 24.305 |
13 | Al | Aluminum | 26.98154 |
14 | Si | Silicon | 28.0855 |
15 | P | Phosphorus | 30.97376 |
16 | S | Sulfur | 32.06 |
17 | Cl | Chlorine | 35.453 |
18 | Ar | Argon | 39.948 |
19 | K | Potassium | 39.0983 |
20 | Ca | Calcium | 40.08 |
21 | Sc | Scandium | 44.9559 |
22 | Ti | Titanium | 47.90 |
23 | V | Vanadium | 50.9415 |
24 | Cr | Chromium | 51.996 |
25 | Mn | Manganese | 54.9380 |
26 | Fe | Iron | 55.847 |
27 | Co | Cobalt | 58.9332 |
28 | Ni | Nickel | 58.70 |
29 | Cu | Copper | 63.546 |
30 | Zn | Zinc | 65.38 |
31 | Ga | Gallium | 69.72 |
32 | Ge | Germanium | 72.59 |
33 | As | Arsenic | 74.9216 |
34 | Se | Selenium | 78.96 |
35 | Br | Bromine | 79.904 |
36 | Kr | Krypto | 83.80 |
37 | Rb | Rubidium | 85.4678 |
38 | Sr | Strontium | 87.62 |
39 | Y | Yttrium | 88.9059 |
40 | Zr | Zirconium | 91.22 |
41 | Nb | Niobium | 92.9064 |
42 | Mo | Molybdenum | 95.94 |
43 | Tc | Technetium | (98) |
44 | Ru | Ruthenium | 101.07 |
45 | Rh | Rhodium | 102.9055 |
46 | Pd | Palladium | 106.4 |
47 | Ag | Silver | 107.868 |
48 | Cd | Cadmium | 112.41 |
49 | In | Indium | 114.82 |
50 | Sn | Tin | 118.69 |
The elements in the periodic table are arranged according to their increasing atomic number and recurrent chemical properties. They are arranged in a tabular format, with rows representing periods and columns representing groups.
The order of the elements increasing atomic numbers is left to right and top to bottom. As a result, elements in the same group will have similar chemical properties and the same valence electron configuration. In contrast, valence electrons in the same period will be arranged in increasing order. As a result, there are more energy sub-levels per energy level as the atom's energy level rises. The first 94 elements of the periodic table are found naturally, but the remaining 95–118 elements have only been created artificially in labs or nuclear reactors. The periodic table we currently use is a more advanced version of some models proposed by scientists in the 19th and 20th centuries. Based on the discoveries of some scientists who came before him, including John Newlands and Antoine-Laurent de Lavoisier, Dimitri Mendeleev proposed the periodic table. However, Mendeleev is given sole credit for his development of the periodic table.
The art of differentiating between chemical substances underwent a rapid development in the early 19th century, which led to the accumulation of a vast body of knowledge about the chemical and physical characteristics of both elements and compounds. The systematized literature of chemistry as well as the laboratory arts by which chemistry is transmitted as a living science from one generation of chemists to another are based on the classification of chemical knowledge, which soon became necessary due to the rapid expansion of chemical knowledge. Since relationships could be determined between compounds more easily than between elements, it happened that the classification of elements lagged behind that of compounds by a significant amount of time. In fact, it took nearly 50 years for chemists to come to a consensus on the classification of elements after the systems for classifying compounds had become widely accepted.
The International Union of Pure and Applied Chemistry, or IUPAC (eye-you-pack), is in charge of maintaining the periodic table as we know it today.
The IUPAC organization is in charge of deciding what needs to be changed, even though much of the information in the periodic table is stable and unlikely to change. For what constitutes the discovery of a new element, they have developed standards. Any new element must also be given an official name after it has been validated, along with a temporary name and symbol. IUPAC recently reviewed elements 113, 115, 117, and 118 and decided to give them official names and symbols (hello, Tennessee! and goodbye, ununseptium!). This was the case when these elements were reviewed.
One might believe that the atomic weights listed in a periodic table are constant. The reality is that atomic weights have altered over time. Atomic weights and abundances have been evaluated by the IUPAC Commission on Isotopic Abundances and Atomic Weights (CIAAW) since 1899. For instance, carbon's atomic weight has changed from 12.00 in 1902 to [12.0096, 12.0116] today. The source of the sample will determine the value, so clearly, times have changed.
The first version of the periodic table, which is similar to the one we currently use, was proposed by Dimitri Mendeleev, who is often referred to as the father of the periodic table. Mendeleev's periodic law differs significantly from the current periodic law in one key way.
While the modern periodic law is based on the increasing order of atomic numbers, Mendeleev modeled his periodic table on the basis of increasing atomic mass. Mendeleev was able to foresee the discovery and characteristics of some elements despite the fact that his periodic table was based on atomic weight. Only about half of the elements that we now know existed during his time, and the majority of what was known about them was inaccurate. The German Journal of Chemistry first published Mendeleev's Periodic Table in 1869.
A longer version of the periodic table has been suggested. One of the earliest divides each of the shorter periods into two parts, one at either end of the table, over the elements in the longer periods that they most resemble. This method was first proposed by A. Werner in 1905. Thus, it is unnecessary to use the multiple tie lines that connect the periods in the Bayley-type table. The lanthanoid and actinoid components of this class of table can also be greatly simplified by being moved to a different area. This table's design had become the one that was most frequently used by the middle of the 20th century.
In the modern periodic table, chemical elements are arranged in a manner that is as familiar as looking at a map of the world, but this was not always the case.
Dmitri Mendeleev, the inventor of the periodic table, started gathering and organizing known properties of elements in 1869 while he was traveling by train. While he observed that certain groups of elements displayed similar characteristics, he also noted that there were many exceptions to the patterns that were beginning to emerge.
Amazingly, rather than giving up, he attempted to change the measured property values to better match the patterns! To help the patterns in his "game" work out, he also predicted that certain elements must exist that weren't there at the time.
Some of the elements in the Mendeleyev and Lothar Meyer periodic tables of 1871 still needed to be placed in positions somewhat outside the order of atomic weights due to their properties. This was true even after the corrections made by the redetermination of atomic weights. For instance, the first element in the pairs of argon and potassium, cobalt and nickel, and tellurium and iodine had a higher atomic weight but were in a later position in the periodic table. Only after a deeper understanding of atomic structure was achieved was this problem solved.
The precise atomic weight of an element is not particularly important because the existence of isotopes—atoms with the same atomic number but different atomic weights—of every element demonstrates its position in the periodic system. Despite having slightly different atomic weights, all of an element's isotopes share the same chemical properties and are located in the same location in the chemistry periodic table.
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By - Nikita Parmar 2024-09-06 10:59:22 , 6 min readAns. The International Union of Pure and Applied Chemistry, or IUPAC (eye-you-pack), is in charge of maintaining the periodic table as we know it today.
Ans. Oganesson, which has the chemical symbol Og and the atomic number 118, is a synthetic element. A team of scientists from Russia and the United States collaborated to create it for the first time in 2002 at the Joint Institute for Nuclear Research (JINR) in Dubna, a city close to Moscow.
Ans. The 118 chemical elements that have been discovered as of 2022 are listed below. A type of atom that has the same number of protons in its atomic nucleus—that is, the same atomic number, or Z—is known as a chemical element and is frequently referred to as simply an element.
Ans. Ninety of the 118 elements that have been discovered occur in nature in appreciable quantities. There are either 4 or 8 additional elements that naturally occur in nature as a result of the radioactive decay of heavier elements, depending on who you ask. The total number of natural elements is therefore 94 or 98.
Ans. The heaviest element with any discernible amount found in nature is uranium, which has the atomic number 92. (The atomic number refers to the number of protons in an atom’s nucleus.)
Ans. They are Nihonium, Moscovium, and Tennessine, respectively. The name of the fourth element is Oganesson. It was named after a Russian nuclear physicist named Yuri Oganessian.
Ans. The chemical element with atomic number 1, hydrogen, has the highest atomic mass of any known element at 1.00794 amu and is the most prevalent in the universe. It is present as the diatomic gas H2.
Ans. In terms of structural stability and nuclear stability, iron is the most stable element, but not in terms of chemical stability.
The periodic table helps us understand chemical properties by showing patterns in the behavior of elements based on their electronic configurations. Elements in the same group tend to have similar chemical properties, while elements in different groups have different properties.
Elements found on the periodic table are used in a wide variety of applications, including in electronics, construction, medicine, and agriculture. Some examples include the use of copper in wiring, iron in construction, iodine in medicine, and nitrogen in fertilizers.