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Classification of Elements and Periodicity in Properties Chemistry - Classification of Elements and Periodicity in Properties

Rajasthan Board (RBSE) - STD 11 Science - Chemistry (Rajasthan - English Medium). 431 questions in this chapter.

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Classification of Elements and Periodicity in Properties questions

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Q 1M.C.Q (1 Marks)1 Mark
Beryllium shows diagonal relationship with aluminium. Which of the following similarity is incorrect?
  • A
    $\ce{Be_2​C}$ like $\ce{Al_4C_3}$ yields methane on hydrolysis.
  • B
    $\ce{Be},$ like $\ce{Al}$ is rendered passive by $\ce{HNO_3}$ .
  • $\ce{Be(OH)_2}$​ like $\ce{Al(OH)_3}$ is basic.
  • D
    $\ce{Be}$ forms beryllates and $\ce{Al}$ forms aluminate.

Answer: C.

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Q 3M.C.Q (1 Marks)1 Mark
Which of the following has maximum difference in $1^{st}$ and $2^{nd}$ ionisation enthalpy.
  • $ \ce{1 s^2, 2 s^2, 2 p^6, 3 s^1}$
  • B
    $\ce{1 s^2, 2 s^2, 2 p^6, 3 s^1 }$
  • C
    $ \ce{1 s^2, 2 s^2, 2 p^1} $
  • D
    $ \ce{1 s^2, 2 s^2, 2 p^6} $

Answer: A.

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Q 5M.C.Q (1 Marks)1 Mark
The ionisation energy of nitrogen is more than oxygen because of :
  • A
    More attraction of electrons by the nucleus.
  • The extra stability of half $-$ filled $p\ -$ orbitals.
  • C
    The ionic radius of nitrogen atom is smaller.
  • D
    All of the above are correct.

Answer: B.

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Q 6Assertion (A) & Reason (B) MCQ1 Mark
Note : In the following questions a statement of Assertion $(A)$ followed by a statement of reason $(R)$ is given. Choose the correct option out of the choices given below each question.
Assertion $(A)$ : Generally, ionisation enthalpy increases from left to right in a period.
Reason $(R)$ : When successive electrons are added to the orbitals in the same principal quantum level, the shielding effect of inner core of electrons does not increase very much to compensate for the increased attraction of the electron to the nucleus.
  • A
    Assertion is correct statement and reason is wrong statement.
  • Assertion and reason both are correct statements and reason is correct explanation of assertion.
  • C
    Assertion and reason both are wrong statements.
  • D
    Assertion is wrong statement and reason is correct statement.

Answer: B.

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Q 7Assertion (A) & Reason (B) MCQ1 Mark
Assertion $(A)$ : Electron gain enthalpy becomes less negative as we go down a group.
Reason $(R)$ : Size of the atom increases on going down the group and the added electron would be farther from the nucleus.
  • A
    Assertion and reason both are correct statements but reason is not correct explanation for assertion.
  • Assertion and reason both are correct statements and reason is correct explanation for assertion.
  • C
    Assertion and reason both are wrong statements.
  • D
    Assertion is wrong statement but reason is correct statement.

Answer: B.

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Q 8Assertion (A) & Reason (B) MCQ1 Mark
Note : In the following questions a statement of Assertion $(A)$ followed by a statement of reason $(R)$ is given. Choose the correct option out of the choices given below each question.
Assertion $(A)$ : Boron has a smaller first ionisation enthalpy than beryllium.
Reason $(R)$ : The penetration of a $2s$ electron to the nucleus is more than the $2p$ electron hence $2p$ electron is more shielded by the inner core of electrons than the $2s$ electrons.
  • A
    Assertion and reason both are correct statements but reason is not correct explanation for assertion.
  • B
    Assertion is correct statement but reason is wrong statement.
  • Assertion and reason both are correct statements and reason is correct explanation for assertion.
  • D
    Assertion and reason both are wrong statements.

Answer: C.

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Q 91 Marks Question1 Mark
In the modern periodic table, the period indicates the value of :
  • A
    Atomic number.
  • B
    Atomic mass.
  • Principal quantum number.
  • D
    Azimuthal quantum number.

Answer: C.

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Q 111 Marks Question1 Mark
The first $(\Delta_{1}\text{H}_{1})$ and the second $(\Delta_{1}\text{H}_{1})$ ionization enthalpies (in $\mathrm{kJ} \mathrm{~mol}^{-1}$ ) and the $(\Delta_{1}\text{H}_{1})$ electron gain enthalpy (in $\mathrm{kJ} \mathrm{~mol}^{-1}$ ) of a few elements are given below:
Elements $\Delta\text{H}_{1}$ $\Delta{\text{H}}_{2}$ $\Delta_{\text{eg}}\text{H}$
I 520 7300 -60
II 419 3051 -48
III 1681 3374 -328
IV 1008 1846 -295
V 2372 5251 +48
VI 738 1451 -40
Which of the above elements is likely to be:
The least reactive element.
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Q 131 Marks Question1 Mark
Considering the elements $\ce{B, C, N, F},$ and $\ce{Si},$ the correct order of their non $-$ metallic character is :
  • A
    $\ce{B > C > Si > N > F}$
  • B
    $\ce{Si > C > B > N > F}$
  • $\ce{F > N > C > B > Si}$
  • D
    $\ce{F > N > C > Si > B}$

Answer: C.

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Q 152 Marks Questions2 Marks
What do you understand by isoelectronic species? Name a species that will be isoelectronic with each of the following atoms or ions.
$\mathrm{Mg}^{2+}$
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Q 182 Marks Questions2 Marks
What do you understand by isoelectronic species? Name a species that will be isoelectronic with each of the following atoms or ions.
$\mathrm{Rb}^{+}$
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Q 213 Marks Question3 Marks
Predict the formulas of the stable binary compounds that would be formed by the combination of the following pairs of elements.
  1. Lithium and oxygen.
  2. Magnesium and nitrogen.
  3. Aluminium and iodine.
  4. Silicon and oxygen.
  5. Phosphorus and fluorine.
  6. Element 71 and fluorine.
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Q 24Case study (4 Marks)4 Marks
We must bear in mind that when Mendeleev developed his Periodic Table, chemists knew nothing about the internal structure of atom. However, the beginning of the 20th century witnessed profound developments in theories about sub-atomic particles. In 1913, the English physicist, Henry Moseley observed regularities in the characteristic X-ray spectra of the elements. A plot of ν (whereν is frequency of X-rays emitted) against atomic number (Z ) gave a straight line and not the plot of ν vs atomic mass. He thereby showed that the atomic number is a more fundamental property of an element than its atomic mass. Mendeleev’s Periodic Law was, therefore, accordingly modified. This is known as the Modern Periodic Law and can be stated as : The physical and chemical properties of the elements are periodic functions of their atomic numbers.Numerous forms of Periodic Table have been devised from time to time. Some forms emphasise chemical reactions and valence, whereas others stress the electronic configuration of elements. A modern version, the so-called “long form” of the Periodic Table of the elements , is the most convenient and widely used. The horizontal rows (which Mendeleev called series) are called periods and the vertical columns, groups. Elements having similar outer electronic configurations in their atoms are arranged in vertical columns, referred to as groups or families. According to the recommendation of International Union of Pure and Applied Chemistry (IUPAC), the groups are numbered from 1 to 18 replacing the older notation of groups IA … VIIA, VIII, IB … VIIB and 0. There are altogether seven periods. The period number corresponds to the highest principal quantum number (n) of the elements in the period. The first period contains 2 elements. The subsequent periods consists of 8, 8, 18, 18 and 32 elements, respectively. The seventh period is incomplete and like the sixth period would have a theoretical maximum (on the basis of quantum numbers) of 32 elements. In this form of the Periodic Table, 14 elements of both sixth and seventh periods (lanthanoids and actinoids, respectively) are placed in separate panels at the bottom. the IUPAC has made recommendation that until a new element’s discovery is proved, and its name is officially recognised, a systematic nomenclature be derived directly from the atomic number of the element using the numerical roots for 0 and numbers 1-9. The roots are put together in order of digits which make up the atomic number and “ium” is added at the end.Groupwise Electronic Configurations Elements in the same vertical column or group have similar valence shell electronic configurations, the same number of electrons in the outer orbitals, and similar properties. theoretical foundation for the periodic classification. The elements in a vertical column of the Periodic Table constitute a group or family and exhibit similar chemical behaviour. This similarity arises because these elements have the same number and same distribution of electrons in their outermost orbitals. We can classify the elements into four blocks viz., s-block, p-block, d-block and f-block depending on the type of atomic orbitals that are being filled with electrons. Two exceptions to this categorisation. Strictly, helium belongs to the s-block but its positioning in the p-block along with other group 18 elements is justified because it has a completely filled valence shell (1s) and as a result, exhibits properties characteristic of other noble gases. The other exception is hydrogen. It has only one s-electron and hence can be placed in group 1 (alkali metals). It can also gain an electron to achieve a noble gas arrangement and hence it can behave similar to a group 17 (halogen family) elements. Because it is a special case, we shall place hydrogen separately at the top of the Periodic Table.
  1. In 1913, the English physicist, ….observed regularities in the characteristic X-ray spectra of the elements.
  1. Johann Dobereiner
  2. John Alexander Newlands
  3. Demitri Mendeleev
  4. Henry Moseley
  1. Horizontal row in periodic table called:
  1. Group
  2. Period
  3. Triad
  4. Octave
  1. Vertical Column in periodic table called:
  1. Group
  2. Period
  3. Triad
  4. Octave
  1. According to Modern Periodic Law the physical and chemical properties of the elements are periodic functions of their ….
  1. Atomic mass
  2. Atomic numbers
  3. Atomic structure
  4. Atomic size
  1. What is IUPAC name of element having atomic number 107.
  1. Unnilpentium
  2. Unnilhexium
  3. Unnilseptium
  4. Unniloctium
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Q 25Case study (4 Marks)4 Marks
The s-Block Elements The elements of Group 1 (alkali metals) and Group 2 (alkaline earth metals) which have ns1and ns2 outermost electronic configuration belong to the s-Block Elements. They are all reactive metals with low ionization enthalpies. They lose the outermost electron(s) readily to form 1+ ion (in the case of alkali metals) or 2+ ion (in the case of alkaline earth metals). The metallic character and the reactivity increase as we go down the group. Because of high reactivity they are never found pure in nature. The compounds of the s-block elements, with the exception of those of lithium and beryllium are predominantly ionic. The p-Block Elements comprise those belonging to Group 13 to 18 and these together with the s-Block Elements are called the Representative Elements or Main Group Elements. The outermost electronic configuration varies from ns2np1 to ns2np6 in each period. At the end of each period is a noble gas element with a closed valence shell ns2np6 configuration. All the orbitals in the valence shell of the noble gases are completely filled by electrons and it is very difficult to alter this stable arrangement by the addition or removal of electrons. The noble gases thus exhibit very low chemical reactivity. Preceding the noble gas family are two chemically important groups of non-metals. They are the halogens (Group 17) and the chalcogens (Group 16).The non-metallic character increases as we move from left to right across a period and metallic character increases as we go down the group. These are the elements of Group 3 to 12 in the centre of the Periodic Table. These are characterised by the filling of inner d orbitals by electrons and are therefore referred to as d-Block Elements. These elements have the general outer electronic configuration (n-1)d1-10ns0-2 . They are all metals. They mostly form coloured ions, exhibit variable valence (oxidation states), paramagnetism and oftenly used as catalysts. However, Zn, Cd and Hg which have the electronic configuration, (n-1) d10ns2 do not show most of the properties of transition elements. In a way, transition metals form a bridge between the chemically active metals of s-block elements and the less active elements of Groups 13 and 14 and thus take their familiar name “Transition Elements”.The two rows of elements at the bottom of the Periodic Table, called the Lanthanoids, Ce(Z = 58) – Lu(Z = 71) and Actinoids, Th(Z = 90) – Lr (Z = 103) are characterised by the outer electronic configuration (n-2)f 1-14 (n-1)d 0–1ns2 . The last electron added to each element is filled in f- orbital. These two series of elements are hence called the Inner- Transition Elements (f-Block Elements). They are all metals. Within each series, the properties of the elements are quite similar. The chemistry of the early actinoids is more complicated than the corresponding lanthanoids, due to the large number of oxidation states possible for these actinoid elements. Actinoid elements are radioactive. Many of the actinoid elements have been made only in nanogram quantities or even less by nuclear reactions and their chemistry is not fully studied. The elements after uranium are called Transuranium Elements. The elements can be divided into Metals and Non-Metals. In contrast, non-metals are located at the top right hand side of the Periodic Table. The elements become more metallic as we go down a group; the non- metallic character increases as one goes from left to right across the Periodic Table. Periodic Table show properties that are characteristic of both metals and non- metals. These elements are called Semi-metals or Metalloids.
  1. Alkali metal and alkaline earth metal belongs to ..
  1. S – block
  2. P – block
  3. D – block
  4. F – block
  1. The metallic character and the reactivity … as we go down the group.
  1. Decreases
  2. Increases
  3. Remains Constant
  4. None of Above
  1. Group … Elements known as chalcogens.
  1. 12
  2. 14
  3. 16
  4. 18
  1. Elements Ce(Z = 58) to Lu(Z = 71) are known as:
  1. Halogens
  2. Chalcogens
  3. Actinoids
  4. Lanthenoids
  1. The elements after uranium are called … Elements.
  1. Halogens
  2. Chalcogens
  3. Actinoids
  4. Transuranium
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Q 26Case study (4 Marks)4 Marks
There are many observable patterns in thephysical and chemical properties of elementsas we descend in a group or move across aperiod in the Periodic Table.Atomic Radius the determination of the atomic sizecannot be precise. In other words, there is no practical way by which the size of an individualatom can be measured. However, an estimateof the atomic size can be made by knowing thedistance between the atoms in the combinedstate. One practical approach to estimate thesize of an atom of a non-metallic element is tomeasure the distance between two atoms whenthey are bound together by a single bond in acovalent molecule and from this value, the“Covalent Radius” For metals, we define theterm “Metallic Radius” which is taken as halfthe internuclear distance separating the metalcores in the metallic crystal. Atomic Radius to refer to both covalent ormetallic radius depending on whether theelement is a non-metal or a metal. Atomic radiican be measured by X-ray or otherspectroscopic methods. The atomic size generallydecreases across a period. It is because within the period the outerelectrons are in the same valence shell and theeffective nuclear charge increases as the atomicnumber increases resulting in the increasedattraction of electrons to the nucleus.Note that the atomic radii of noble gasesAre not considered here. Being monoatomic,Their (non-bonded radii) values are very large.In fact radii of noble gases should be comparednot with the covalent radii but with the van derWaals radii of other elements. The removal of an electron from an atom resultsin the formation of a cation, whereas gain ofan electron leads to an anion. The ionic radiican be estimated by measuring the distancesbetween cations and anions in ionic crystals.In general, the ionic radii of elements exhibitthe same trend as the atomic radii. A cation issmaller than its parent atom because it hasfewer electrons while its nuclear charge remainsthe same. The size of an anion will be largerthan that of the parent atom because theaddition of one or more electrons would resultin increased repulsion among the electronsand a decrease in effective nuclear charge. When we find some atoms and ions whichcontain the same number of electrons, we callthem isoelectronic species. For example,$O2–, F–, Na+$ and $Mg2+$ have the same number ofelectrons (10). Their radii would be differentbecause of their different nuclear charges.A quantitative measure of the tendency of anelement to lose electron is given by itsIonization Enthalpy. It represents the energyrequired to remove an electron from an isolatedgaseous atom (X) in its ground state. The ionization enthalpy is expressed inunits of kJ mol–1. We can define the secondionization enthalpy as the energy required toremove the second most loosely boundelectron The first ionization enthalpies of elementshaving atomic numbers up to 60 are plotted then The periodicity of the graph is quitestriking. You will find maxima at the noble gaseswhich have closed electron shells and verystable electron configurations. On the otherhand, minima occur at the alkali metals andtheir low ionization enthalpies can be correlated with their high reactivity. In addition, you willnotice two trends the first ionization enthalpygenerally increases as we go across a periodand decreases as we descend in a group. Electron Gain Enthalpy. when an electron is added to a neutral gaseousatom (x) to convert it into a negative ion, theenthalpy change accompanying the process isdefined as the electron gain enthalpy (∆egh).Electron gain enthalpy provides a measure ofthe ease with which an atom adds an electronto form anion. electron gain enthalpies have largenegative values toward the upper right of theperiodic table preceding the noble gases.The variation in electron gain enthalpies ofelements is less systematic than for ionizationenthalpies. As a general rule, electron gainenthalpy becomes more negative with increasein the atomic number across a period. Theeffective nuclear charge increases from left toright across a period and consequently it willbe easier to add an electron to a smaller atomsince the added electron on an average wouldbe closer to the positively charged nucleus. ElectronegativityA qualitative measure of the ability of an atomin a chemical compound to attract sharedelectrons to itself is called electronegativity.Unlike ionization enthalpy and electron gainenthalpy, it is not a measureable quantity.However, a number of numerical scales ofelectronegativity of elements viz., Pauling scale,Mulliken-Jaffe scale, Allred-Rochow scale havebeen developed. The one which is the most widely used is the Pauling scale. Electronegativity generallyincreases across a period from leftto right (say from lithium tofluorine) and decrease down a group(say from fluorine to astatine) inthe periodic table. Non-metallic elements have strong tendencyto gain electrons. Therefore, electronegativityis directly related to that non-metallicproperties of elements. It can be furtherextended to say that the electronegativity isinversely related to the metallic properties of elements. Thus, the increase inelectronegativities across a period isaccompanied by an increase in non-metallicproperties (or decrease in metallic properties)of elements. Similarly, the decrease inelectronegativity down a group is accompanied by a decrease in non-metallic properties (orincrease in metallic properties) of elements.
  1. The atomic size generally … across a period.
  1. Increases
  2. Decreases
  3. Remains Constant
  4. None of above
  1. The ionization enthalpy is expressed in units of ….
  1. $kJ mol^{–1}$
  2. $mole kJ^{-1}$
  3. $mole kJ$
  4. $-kJ mol^{-1}$
  1. Which of the following is/are numerical scales of electronegativity of elements.
  1. Pauling scale
  2. Mulliken-Jaffe scale
  3. Allred-Rochow scale
  4. All the above
  1. The … in electronegativity down a group is accompanied by a … in non-metallic properties.
  1. Increase, Decrease
  2. Decrease, Increase
  3. Decrease, Decrease
  4. Increase , Increase
  1. Electronegativity generally … across a period from left to right and … down a group in the periodic table.
  1. Increase, Decrease
  2. Decrease, Increase
  3. Decrease, Decrease
  4. Increase, Increase
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Q 275 Marks Questions5 Marks
Among the second period elements the actual ionization enthalpies are in the order $Li < B < Be < C < O < N < F < Ne$. Explain why,
  1. Be has higher $\Delta_{\text{t}}\text{H}$ than B
  2. O has lower $\Delta_{\text{t}}\text{H}$ than N and F?
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