Thermal, structural, optical and electrical properties of PVA/MAA:EA polymer blend filled with different concentrations of Lithium Perchlorate

The dTGA curves show three different steps of weight loss. This is due to the loss of water adsorbed, the elimination of the side chains, and the decomposition of the main chain. For LiClO4 filled PVA/MAA:EA, FTIR spectra showed disappearance of some bands with the change in their intensities as compared to pure PVA/MAA:EA film.

Original Article

Role of electronegativity on the bulk modulus, magnetic moment and

Department of Physics, Indian Institute of Technology Kharagpur, Kharagpur, 721302, India

a r t i c l e i n f o

Article history:

Received 5 January 2019

Received in revised form

2 February 2019

Accepted 3 February 2019

Available online 10 February 2019

Keywords:

Heusler alloy

Lattice parameter

Bulk modulus (BM)

Magnetic moment

Band gap

a b s t r a c t

In this paper, we have presented the comparative study of mechanical, electrical and magnetic properties

of Co2MnAl1
xZxHeusler alloy with Z¼ Si, Ge and Ga and x ¼ 0, 0.25, 0.75 and 1 using electronegativity (EN) model We employed density functional theory for numerical calculations It is found that Co2 M-nAl1
xZxwith Z¼ Ga, Ge follow the Vegard's law while Co2MnAl1
xSixdoes not follow the same trend Among all composition Co2MnAl.25Si.75alloy is found to be more compressible Electronic density dis-tribution depicts the ionic nature of Co2MnAl1
xZxalloy systems The Co2MnAl1
xZxwith Z¼ Si, Ge possess larger magnetic moment and band gap with respect to Co2MnAl1
xGaxsystem which results from the EN difference, degree of delocalization of valence electron, atomic size and atomic number, respectively

© 2019 The Authors Publishing services by Elsevier B.V on behalf of Vietnam National University, Hanoi This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/)

1 Introduction

In last few years, Heusler alloys have become the promising

material due to major applications in spintronics and memory

shape devices[1] In this system, the full Heusler compounds are

characterized by the formula X2YZ that crystallize in the L21

structure while half Heusler alloys are referred as XYZ which

crystallize in the cb1 structure [2,3] There are four

wyckoff-positions which is given by P (0, 0, 0), Q (0.25, 0.25, 0.25), R (0.5,

0.5, 0.5) and S (0.75, 0.75, 0.75) Here X and Y elements are

posi-tioned in P, Q and R sites while main group element Z takes always

place in S sites[4]

The electronic structure of these Heusler alloys are obtained to

range from metallic to semiconductor relying on their composition

Infact, full Heusler alloys are popular due to half-metallic nature

means these alloys possess 100% spin polarization at the Fermi

level In similar way, the full Heusler alloy shows many attractive

magnetic phenomena like localized and itinerant magnetism,

hel-imagnetism, antiferromagnetism, Pauli paramagnetism or heavy

fermionic behaviour [5] Therefore, understanding of electrical,

mechanical and magnetic behaviors of these alloys is very impor-tant for application point of view It is well established that me-chanical properties are defined in term of bulk modulus of compound The bulk modulus (B) is an parameter of materials that

defines the ability of a solid, within elastic region, to resist compression deformation In microscopic framework, valence electrons play an important role in the compression process and attractive interaction between atom and valence electrons results from the electronegativity (EN) of atoms which are not only affect mechanical properties but also influence electrical and magnetic properties of materials[6] Hence, magnetic moments and band gap are also considerably influenced by the delocalization degree of valence electrons Among the Heusler materials, Cobalt-based Heusler alloys are very popular because of their high Curie tem-perature that make them favorable for various applications, e.g tunneling magnetoresistance (TMR) Upto date, many Cobalt-based full Heusler alloys have been investigated as half metallic materials which is advantageous for spintronic devices In addition, disor-dered phase like A2, B2or DO3of Heusler alloys[7e9]also have a great influence on their physical properties Disorder can be found due to replacement of element in the parent alloys or the presence

of defects which lead the structural, mechanical and electrical properties of Heusler alloys

Keeping it mind, we aimed to study substitution effect of Ga, Ge and Si on mechanical, electrical and magnetic properties of

Co2MnAl1
xZx(where Z¼ Si, Ge and Ga) Heusler alloy using density

* Corresponding author.

** Corresponding author.

E-mail addresses: shivomiit@gmail.com (A.-S Om Kumar), vineeta@phy.iitkgp.

ernet.in (V Shukla), sanjeev@phy.iitkgp.ernet.in (S.K Srivastava).

Peer review under responsibility of Vietnam National University, Hanoi.

Contents lists available atScienceDirect Journal of Science: Advanced Materials and Devices

j o u r n a l h o m e p a g e : w w w e l s e v i e r c o m / l o c a t e / j s a m d

https://doi.org/10.1016/j.jsamd.2019.02.001

2468-2179/© 2019 The Authors Publishing services by Elsevier B.V on behalf of Vietnam National University, Hanoi This is an open access article under the CC BY license

functional theory based method to search the materials of potential

application

2 Calculation method

The numerical investigations were accomplished by using the

Density Functional Theory (DFT) based WIEN2k code[10] The

ex-change correlation potential was characterized by the generalized

gradient approximation (GGA) with the Perdew-Burke-Ernzerhof

(PBE) function[11] The plane wave basis set with an energy

cut-off of 300 eV is used for all cases The energy threshold between

the core and the valence states and k points were set to 6.0 Rydberg

(Ry) and 1000, respectively The primitive cell was taken for

Co2MnAl, Co2MnGa, Co2MnGe and Co2MnSi while 1 1  1 super

cells were made for Co2MnAl1
xZx(where Z¼ Ge, Si, Ga except

x¼ 0) alloy systems In case of Co2MnGa alloy Co, Mn and Ga take

place at wyckoff coordinates Mn (0, 0, 0), Co1(0.75, 0.75, 0.75), Co2

(0.25, 0.25, 0.25) and Ga (0.5, 0.5, 0.5), respectively, as shown in

Fig 1 All compounds were optimized by using Hellmann-Feynman

forces on atoms We used lattice parameter a¼ 5.749 Å as we

re-ported previously[12]

3 Results and discussion

In order to evaluate the mechanical properties of Co2MnAl1
xZx

(where Z¼ Si, Ge and Ga and x ¼ 0.0, 0.25, 0.75, and 1.0

compo-sitions) Heusler alloys, the volume optimization was performed by

minimizing the total energy for a number of volumes of Ga, Si and

Ge substituted alloys as shown inFig 2

We found the equilibrium lattice parameters (a0) and the bulk

modulus (B) from the Birch Murnaghan equation as given by[13]

B0ðB0
1Þ*

"

V0 V

B þ



1
V0 V


1#

(1)

where E0, B and B0refer to equilibrium energy, bulk modulus and its

first derivative at equilibrium volume V0, respectively Generally,

the bulk modulus B is defined by the following equation:

B¼
VvVvP¼ Vv2E

where P and V are the pressure and volume of the system, respectively

It can be seen fromFig 3 (a) that with increasing Ge and Ga content, the lattice constant increases linearly This higher value of the lattice parameter is a result of greater atomic radius of Ge and

Ga atoms in compare to Al atom However, Co2MnAl1
xSixfollow the opposite trend that is usual for Heusler alloys

In any system bulk modulus (B) represents the hardness of compounds Thus, bulk modulus variation for Co2MnAl1
xZx

(where Z¼ Si, Ge and Ga) alloys have been shown inFig 3(b) It is clear that all Ge, Si and Ga substituted composition upshot bigger modulus relative to parent Co2MnAl alloy except only Co2 M-nAl.25Si.75 composition Interestingly, all Co2MnAl1
xZx (where

Z¼ Si, Ge and Ga) alloys follow the same trend Initially on addition

of 25% of Ge, Si or Ga in place of Al site (for example Co2 M-nAl.75Ge.25 composition), bulk modulus increases However, bulk modulus decreases for 75% substitution of Ge, Si or Ga and again increases for pure Co2MnSi, Co2MnGa and Co2MnGe alloys Such kind of variation occurs according to the following order:

Co2MnAl1
xSix> Co2MnAl1
xGax> Co2MnAl1
xGex Above varia-tion in bulk modulus after the addivaria-tion of 25% Si, Ge and Ga sub-stitution might be the result of valence electrons difference (excluding core electrons), taking part in the compression process

or EN difference Al (1.61 eV1/2), Ga (1.81 eV1/2), Si (1.90 eV1/2) and

Ge (2.01 eV1/2) which controls the attractive and repulsive inter-action between atom and valence electrons[14,15]

Since EN value of Ga, Ge and Si are larger than that of Al atom, the average binding force of chemical bonds in the alloys increases when alloying Co2MnAl with Ga, Si and Ge, respectively It is noteworthy that bulk modulus of alloys is expected to increase with increasing of these p-element content in Co2MnAl alloy according

to simple chemical bonding formulation based on tight-binding model In contrast, substitution of 75% Ge, Si or Ga in Co2MnAl alloy, B decreases that might be the result of increasing number of p-p and p-d bonds, which make them more rigid than 25% sub-stitution of Ge, Si or Ga in parent alloys [16] Among all Fig 2 Calculated total energy as the function of volume of Co 2 MnGa/Al Heusler alloy A.-S Om Kumar et al / Journal of Science: Advanced Materials and Devices 4 (2019) 158e162 159

compositions, Co2MnAl.25Si.75 is found to be more compressible.

There may be two reasons: either sharp changes in B upon doping

of Si might be related to local Al magnetic moment contribution

(Fig 4a) or significant contraction of the lattice occurs on Si doping

due to less variation in atomic number of Si and Al elements

Another important parameter is electron density distribution

Basically, electronic charge density is useful entity for studying the

nature of bond character in any materials Moreover, it provides

information on the charge transfer, bonding nature (e.g the ionic,

metallic and covalent bonding) in alloys As we predicted earlier that

atomic number, EN etc plays an important role in above mentioned

properties For this purpose, we studied the electronic charge

den-sity distribution curve Here only curve for Co2MnAl and Co2

M-nAl.25Ge.75alloys have been shown inFig 5(a and b) The electronic

charges are mainly distributed in the vicinity of atoms, and decreases

away from the core region The formation of well-defined spherically

symmetric peaks centered on Co, Mn, Ge/Al atoms occurs due to the

difference of electron density The interstitial region between the Co,

Mn and Ge/Al atom has no electrons at all which shows CoGe/Al and

MnGe/Al bonds has a similar character with the ionic bond This

character is accompanied by a transfer of charge from the Co and Mn

atoms to Ge or Co to Al atom because of different EN of elements

except Mn to Al which possess almost same EN[8]

To analysis the magnetic properties, total magnetic moment

plots for Co2MnAl1
xZx(Z¼ Si, Ge and Ga) alloys have been depicted

in Fig 6(a) For Si and Ge substituents, total magnetic moment

shows the increasing trend while Ga does not follow any trend In

general, the total moment of the half-metallic full-Heusler alloys

follows the Slater-Pauling behavior:mtotal¼ Ztotal-24 where Ztotalis

the total number of valence electrons The total number of electrons

Ztotalis given by the sum of the number of spin-up (N[) and

spin-down (N[) electrons (Ztotal¼ N[þNY) and the total momentmtotal

is given by the difference of the number of spin-up and spin-down

electrons (mtotal¼ N[
NY)[17] It is found that total moment follow

the Slater-Pauling rule for Ge as well but shows a little deviation for

Co2MnAl.75Ge.251% and Co2MnAl.25Si.75almost 9% However, in case

of Ga replacement, particularly 25% composition of Ga, major de-viation occurred For more details,Fig 6(b, c) shows local magnetic moment plot of Co and Mn which have major contribution in total magnetic moment Co contribution for Ge substituent varies nearly linear similar to Si but for Ga substituent it deviates for linear relation[18] For more compressible composition Co2MnAl.25Ge.75,

Co contributes least Partial moment of Co is maximum for

Co2MnAl.25Ga.75alloy among all compositions On other hand, Mn contribution does not vary much for Si and Ge substituents, but changes occur for Ga substituent that might be due to the less variation of EN values of Al and Ga Moreover, Ga substituent shows muchfluctuation in total as well as in partial moments It is obvious fromFig 5(a) that for Co2MnAl.75Ga.25composition total moments decreases while total moment increases for 75% and 100% Ga substituted alloys On other hand, Co, Mn and Ga moment contri-butions were least rather Al for Co2MnAl.75Ga.25composition In case of Co2MnAl.25Ga.75, total and partial moments follow the reverse trend Firstly, it is anticipated that largefluctuation in Ga substituent can be outcome of the same number of valence electron

in Al and Ga shells Secondly, at 25% doping of Ga could not be enough for formation of number of p-d bonds that tends to reduce the Co, Mn moment In contrast 75% substitution of Ga increases Co and Mn moment offer the large expansion of the lattice caused by the p-p or p-d bonds It is found that the local moments of Si and Ge are negligibly small as inFig 4(a, b), but Ga substituent possess some partial moment The moments of Al are the negative and small values, while the Co and Mn moments are the positive values and most of the moment come from Mn This abnormal local moment of

Mn arises from a small d-d wave function overlapping and hence larger exchange interaction due to the decreasing MneMn dis-tances.Fig 4(c) depicts the band gap for each composition The band gap is also influenced by the EN term Additionally, it depends

on the distribution of valence electrons i.e degree of delocalization

of valence electrons In all substituents EN is in order Ge> Si > Ga Fig 3 (a) Lattice constant (b) Bulk modulus in Co 2 MnAl 1
x Z x (where Z ¼ Si, Ge and Ga) alloys.

Fig 4 Partial magnetic moment of Al, (b) magnetic moment of Ga, Ge, Si, (c) Band gap plot of Co MnAl Z (Z ¼ Si, Ge, Ga) Heusler alloys.

Thus Ge then Si is more electronegative than Ga so that it interacts

with the host atoms more strongly which offers large enough

bonding-anti-bonding splitting than Ga substitution Therefore,

band gap is found to be maximum for Co2MnAl.75Ge.25and

mini-mum Co2MnAl.25Ga.75composition[15] It is available in literature

that the semiconductor properties, band gap energy and lattice

constant are strongly related with EN and pseudopotential radii i.e

difference in the atomic size That means the variation in band gap

with increasing Ge and Si content for Co2MnAl1
xZx(Z¼ Si, Ge)

alloy might be the result of the competition between attractive and

repulsive forces due to EN difference Thus from application point of

view, EN and atomic radius play important role for making good

spintronics device

4 Conclusion

In brief, we performed the comparative study of mechanical,

electrical and magnetic properties of Co2MnAl1
xZxHeusler alloys

(Z¼ Si, Ge and Ga and x ¼ 0, 0.25, 0.75 and 1) using the EN model

and WEIN2K code for numerical calculations The electronic

den-sity distribution depicts the ionic nature of Co2MnAl
xZx alloy

systems The alloys with Z¼ Ga, Ge follow the Vegard's law while

Co2MnAl1
xSixdoes not follow the same trend The Co2MnAl.25Si.75

alloy is found to more compressible than others For the magnetic

moment and the band gap, however, a similar behaviour is found

for the alloys with Z¼ Si and Ge They possess larger magnetic

moment and band gap with respect to Co2MnAl1
xGaxsystem This

finding is attributed to the EN difference, degree of delocalization of

valence electron, atomic size and atomic number, respectively They

play an important role for making good spintronics devices

Author contributions

The equal work was performed by Shiv Om Kumar and Vineeta

Shukla in writing and reviewing the manuscript and above work

was done under the supervision of Sanjeev Kumar Srivastava

Acknowledgments Shiv Om Kumar and Vineeta Shukla are thankful to IIT Khar-agpur and MHRD, India for providing the necessary facilities and financial support, respectively

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