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The Influence of B Concentration on the Structural Stability and Mechanical Properties of Nb-B Compounds Yong Pan, and Yuanhua Lin J. Phys. Chem. C, Just Accepted Manuscript • DOI: 10.1021/acs.jpcc.5b07877 • Publication Date (Web): 18 Sep 2015 Downloaded from http://pubs.acs.org on September 24, 2015
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The Journal of Physical Chemistry
The Influence of B Concentration on the Structural Stability and Mechanical Properties of Nb-B Compounds Yong Pan†, ‡*, Yuanhua Lin†,* †
School of Materials Science and Engineering, Southwest Petroleum University, Chengdu 610500,
China ‡
State Key Laboratory of Advanced Technologies for Comprehensive Utilization of Platinum Metals,
Kunming 650106, China ABSTRACT: Synthesizing and designing novel hard material is still a huge challenge to industrial applications. In this paper, the influence of B concentration on the structural stability, elastic
Nb 2.365Å B 2.340Å B 1.813Å Nb 1.790Å B
properties, hardness and chemical bonding of Nb-B compounds has been investigated by using first-principles approach. Two previously unreported crystal structures of Nb2B and Nb2B3 were predicted. In particular, the hard mechanism of TMBs has been explored in detail. The convex hull has indicated that the NbB with an orthorhombic structure is the most stable structure among those Nb-B compounds. The bulk modulus of Nb-B compounds is related to the B
concentration. However, Nb2B3 shows the highest shear deformation resistance and the strongest elastic stiffness. The calculated theoretical hardness of Nb2B3 is 33.5 GPa, can be considered as a potential superhard material. The high hardness and elastic properties are attributed not only to the B concentration and orientation of bonds, but also to the chemical bonding between layer-layer. Finally, we concluded that the bond strength at layer-layer plays a crucial role for hardness and elastic properties. and investigated intensively. However, metal Os
■ INTRODUCTION The search for novel superhard material is
is a toxic matter. In particular, the price of those
motivated by the need for the development of
5d- TMs is very expensive. Therefore, it is
industrial application. In recent years, transition
necessary to explore new TMBs materials with
metal
low cost and high hardness.
borides
(TMBs)
have
received
considerable attention due to the high hardness,
Recently, the CrB4 with a hardness of about
high elastic modulus, ultra-compressibility and
of 48 GPa is successfully synthesized by using
excellent thermal stability1-7. For those TMBs
arc-melting
materials, the important factor
indicating
that
the
design
potential superhard materials may be formed by
principle is that the transition metal (TM) has
the introduction of boron atom into TM (3d-)
high valence electron density (HVED) such as
with low valence electron density (LVED). This
Os, Re, Ir and Rh et al. It has been reported that
result provides a novel route for the search of
some potential superhard materials such as ReB2
new TMBs superhard material. According to the
8
of
method11,
9
(48 GPa by 0.49 N) , OsB2 (37 GPa) , IrB1.1 (43 GPa)
10
and RhB1.1(44 GPa)
10
have been found
design
principle,
Nb-based
borides
have
attracted attention because of low cost, high 1
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hardness, high elastic modulus and excellent 12-13
thermal stability
. For those Nb-B binary
Page 2 of 16
concluded that the chemical bonding and bonding force between layer-layer play a crucial
compounds, early studies have focused on the
role in hardness and elastic properties.
structure and mechanical properties of NbB2. For
■ THEORETICAL METHODS
example, the electronic structure and bonding
According to the Nb-B binary phase
state of NbB2 have been investigated by
diagram, the structures of Nb-B compounds with
Vajeeston and Ravindran14. It is found that the
various stoichiometries can be obtained: Nb3B2
calculated bulk modulus and shear modulus of
with a tetragonal structure (space group:
NbB2 is 299 GPa and 220 GPa, respectively15.
P4/mbm, No: 127)17, NbB with an orthorhombic
However, until the present works there have
structure (space group: Cmcm, No: 63)18, Nb5B6
been no investigations of the relationship
with an orthorhombic structure (space group:
between
mechanical
Cmcm, No: 65)19, Nb3B4 with an orthorhombic
properties. In particular, the trend of structural
structure (space group: Immm, No: 71)20 and
stability and mechanical properties varying with
NbB2 with a hexagonal structure (space group:
the B concentration are unknown.
P6/mmm, No: 191)21. However, other Nb-B
B
concentration
and
On the other hand, the nature of hardness
compounds such as Nb2B and Nb2B3, there are
for TMBs superhard materials remains a
not experimental structural parameters up to now.
challenge because the hardness of a solid is
Considering the elemental feature, the structures
attributed to the resistance to elastic and plastic
of Ta2B-type (space group: I4/mcm, No: 140) for
deformations. From the viewpoint of chemical
Nb2B and V2B3-type (space group: Cmcm, No:
bonding, the three-dimensional network covalent
63)22 for Nb2B3 are considered, respectively.
bonds (such as diamond) effectively resist the formation
and
propagation
of
The first-principles calculated total energy,
dislocation,
elastic properties and electronic structure were
resulting in high hardness. It is concluded that
carried out by using density functional theory
the hardness of TMBs is determined by B
(DFT), as implemented in the CASTEP code23.
concentration. However, the boron-poor borides
To describe the electronic function, ultrasoft
also have high hardness such as IrB1.1 (43 GPa),
pseudopotential24 was carried out and the
RuB1.1 (44 GPa) and Ru2B3 (49 GPa)16, which
electronic configurations of Nb and B atoms
are different from the previous point of view.
were 4p64d45s1 and 2s22p1, respectively. To
Obviously, the nature of hardness is related not
estimate
only to covalent bonding but also to other factors.
correlation functional was treated by the local
Unfortunately, the nature of hardness remains a
density
conundrum.
Ceperley-Alder (CA)25 and the generalized
In the present paper, the formation enthalpy,
the
calculated
approximation
gradient
results, (LDA)
approximation
exchange with
(GGA)
the with
26
elastic constants, elastic modulus, theoretical
Perdew-Burke-Ernzerhof (PBE) . To ensure the
hardness and chemical bonding of Nb-B
total energy at ground state to be converged, a
compounds are systematically investigated by
plane-wave basis set for electron wave function
first-principles density function theory (DFT).
with cutoff energy of 400 eV was used.
The relationship between B concentration and
Integrations
mechanical properties is discussed in detail.
performed by using special k-points generated
Moreover, the nature of hardness is explored. It
with 12×12×12, 8×8×15, 15×15×15, 15×15×15,
is found that the NbB is the most stable structure
15×15×15, 15×15×15 and 18×18×15 mesh grids
among those Nb-B compounds and the Nb2B3 is
for Nb2B, Nb3B2, NbB, Nb5B6, Nb3B4, Nb2B3
a potential superhard material. Finally, it is
and NbB2, respectively. During the structural
in
the
Brillouin
zone
were
2
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The Journal of Physical Chemistry
optimization, all atoms were fully relaxed using
of NbB is -0.833 eV/atom by LDA and -0.808
conjugate gradient method until the total energy,
eV/atom by GGA, respectively, which is lower
force and atomic displacement were less than
than that of other Nb-B compounds. The convex
1×10
-5
eV/Å, 0.03 eV/Å, and 0.001 Å,
hull indicates that NbB with an orthorhombic
respectively. Elastic constants of a solid were
structure is the most stable structure among
calculated by an efficient strain-stress method,
those
through a linear least square fit of first-principles
predicted
calculated stress vs strain.
possible exists because the calculated formation
■ RESULTS AND DISCUSSION
enthalpy of Nb2B3 is lower than that of NbB2.
Nb-B
compounds.
Nb2B3
with
Importantly,
V2B3-type
the
structure
Thermodynamic stability of a solid is
However, the obtained formation enthalpy of
evaluated by the knowledge of its ground state
Nb2B is much larger than that of other Nb-B
energy,
compounds,
which 27-29
is
defined
as
formation
implying
that
this
boride
is
. At the atomic level, the formation
energetically unstable compared with the other
enthalpy of a material is related to the atomic
Nb-B compounds. On the other hand, the
potential
obtained
enthalpy
between
atoms.
Therefore,
the
formation
enthalpy
of
Nb-B
structural stability is determined by atomic
compounds by LDA is slightly lower than GGA.
position and component in a material. The
It is suggest that this discrepancy is attributed to
negative
the choice of functional.
formation
enthalpy
indicates
the
thermodynamic stability at ground state. The general trend is, the lower the formation enthalpy, the more stability the material. To measure
the
compounds,
structural we
stability
calculated
the
of
Nb-B
formation
enthalpy of Nb-B compounds as a function of B concentration.
The
equation
of
formation
enthalpy is defined as: ∆H ( Nbx B y ) =
1 ( Etotal ( Nbx B y − xE Nb − yEB ) x+ y
(1)
where Etotal(NbxBy), ENb and EB are the total energy of NbxBy compounds, pure Nb atom and B atom at ground state; x and y are the number of Nb atom and B atom for a system, respectively. Figure calculated
1
shows
formation
the
first-principles
enthalpy
of
Nb-B
compounds as a function of B concentration. To measure the calculated results, the formation enthalpies within LDA and GGA are calculated and discussed. From Figure 1, the obtained formation enthalpy of Nb3B4 is -0.828 eV/atom by LDA and -0.806 eV/atom by GGA, respectively, which is in good agreement with the previous theoretical result30. It is worth noticing that the calculated formation enthalpy
Figure 1. The calculated formation enthalpy of Nb-B
compounds
as
a
function
of
B
concentration. It is obvious that the structural stability of a material is controlled by the structural type, chemical bonding and localized hybridization. Essentially, the crystal structure originated from the localized hybridization between atoms, which determines the strength, orientation and the number of chemical bonding. Therefore, we firstly discussed the structural information of Nb-B
compounds
as
a
function
of
B
concentration. The calculated lattice parameters, volume and density of Nb-B compounds within LDA and GGA are listed in Table 1. It can be
3
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Table 1. Calculated lattice parameters, a-axis, b-axis and c-axis (Å), volume, V (Å3) and density, ρ (g/cm3) of Nb-B compounds as a function of B concentration. Phase
Method
Prototype
Space group
a
Nb2B
LDA
Ta2B-type
I4/mcm
GGA Nb3B2
NbB
Nb5B6
Nb3B4
Nb2B3
LDA
ρ
5.707
4.866
158.5
8.24
5.790
4.924
165.1
7.91
6.130
3.251
122.2
8.16
3.297
127.2
7.84
Exp17
6.178
3.280
3.259
8.653
3.132
88.3
7.80
3.300
8.758
3.167
91.5
7.53
Exp18
3.298
8.724
3.166
LDA
Cmcm
8.00
GGA
22.564
3.118
3.266
229.7
7.65
22.816
3.154
3.308
238.1
7.39
Exp19
22.768
3.154
3.299
LDA
Ta5B6-type
3.265
13.946
3.108
141.5
7.56
GGA
3.306
14.106
3.144
146.6
7.29
Exp20
3.305
14.080
3.137
LDA
V3B4-type
Cmcm
7.56
GGA
V2B3-type
Immm
Cmcm
7.32
3.267
19.288
3.093
194.9
7.44
3.308
19.503
3.132
202.1
7.17
3.079
3.279
26.7
7.11
GGA
3.105
3.323
27.7
6.86
Exp21
3.100
3.300
GGA NbB2
V
6.212 CrB-type
P4/mbm
c
GGA LDA
Ta3B2-type
b
LDA
AlB2-type
P6/mmm
seen that the calculated lattice parameters of
calculated bond length of Nb-B and Nb-Nb
Nb3B2, NbB, Nb5B6, Nb3B4 and NbB2 are in
bonds is 2.449 Å and 2.696 Å, respectively,
excellent agreement with the experimental
which are in good agreement with the previous
. The calculated lattice parameter of
theoretical results31. According to the structural
NbB2 along the a-axis is lower than that of
feature, the Nb-Nb metallic bond plays a key
c-axis in contrast to the lattice parameter of other
role in mechanical properties. Therefore, the
data
17-21
Nb-B compounds along the a-axis is larger than
structural stability and mechanical properties of
that of c-axis. This difference gives rise to
Nb2B are mainly determined by Nb-Nb metallic
different degree of localized hybridization along
bonds and part of Nb-B bonds. With increasing
the axis direction, to reveal the origin of the
B concentration, the number of Nb-Nb metallic
hardness. On the other hand, the obtained
bond decreases in contrast to the number of
density of Nb-B compounds decreases with
Nb-B and B-B bonds increases in those Nb-B
increasing B concentration because the density
compounds. Obviously, those Nb-B bond and
of Nb atom is larger than that of B atom.
B-B covalent bond markedly enhance bonding
In order to estimate the structural stability, the optimized structures of Nb-B compounds are
force and deformation resistance, resulting in high elastic modulus and hardness.
represented in Figure 2. For Nb2B, each B atom
For NbB, Nb5B6, Nb3B4 and Nb2B3, the
is surrounded by twelve Nb atoms, which form
alternative stacking of Nb layer and B layer can
the 3D-network Nb-Nb metallic bonds. The
be viewed along the crystallographic axis. The 4
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The Journal of Physical Chemistry
(a)
(b)
(e)
(c)
(d)
(g)
(f)
Figure 2. Crystal structure of Nb-B compounds. (a) Nb2B, (b) Nb3B2, (c) NbB, (d) Nb5B6, (e) Nb3B4, (f) Nb2B3, (g) NbB2. The blue and pink spheres represent the Nb atom and B atom, respectively. layered structure is constructed by graphite-like
properties of a superhard material. After
Nb layer and B layer with a clear sliding
examining the structural stability, the mechanical
between
properties of Nb-B compounds are discussed and
two
adjacent
layers.
The
slight
discrepancy about layer-layer determines the
analyzed following.
bonding force and structural stability. It can be
knowledge, the mechanical properties such as
seen that the obtained interlayer distance (2.890
bulk modulus (B), shear modulus (G), Young′s
Å) of Nb3B4 is larger than that of other Nb-B
modulus (E) and Poisson′s ratio (δ) are obtained
compounds,
interlayer
by elastic constants (Cij), which are defined as
interaction. It is worth noticing that the B atoms
the stiffness of a crystal against an externally
(in Nb2B3) alternative stacked in a sub-boundary
applied strain32. In addition, the mechanical
layers, forming the strong B-B covalent bond
stability of a solid is measured by elastic
(1.790 Å). The bonding state can effectively
constants. For those Nb-B compounds, there are
improve the structural stability and mechanical
three different structures such as tetragonal
properties. Importantly, the orientation of bond
(Nb2B and Nb3B2), orthorhombic (NbB, Nb5B6,
also plays a key role in mechanical properties
Nb3B4 and Nb2B3) and hexagonal (NbB2)
such as Nb5B6 (Figure 2(d)) and Nb2B3 (Figure
structures. According to the structural feature,
2(f)), determining the variation of elastic
the tetragonal, orthorhombic and hexagonal
indicating
a
weak
To the
best
of
our
modulus and hardness. For NbB2 with AlB2-type
structures have six, nine and five elastic
structure, the structural stability and mechanical
constants,
properties are attributed to the 3D-network Nb-B
assessment of mechanical stability is obtained by
bonds (2.414 Å), which are consistent with the
Wu and Zhao33.
previous theoretical results.
respectively.
Therefore,
the
Table 2 lists the calculated elastic constants
There is no doubt that the high hardness and large compression strength are the unique
of Nb-B compounds within LDA and GGA. It is observed that those Nb-B compounds are 5
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Table 2. Calculated elastic constants, Cij (GPa) of Nb-B compounds as a function of B concentration. Phase
Method
C11
C12
C13
Nb2B
LDA
460
94
GGA
433
83
Nb3B2 NbB Nb5B6 Nb3B4
Nb2B3 NbB2
C22
C23
C33
C44
C55
C66
173
389
163
147
149
361
156
147
LDA
530
117
144
470
192
161
GGA
481
106
128
436
175
148
LDA
518
154
178
566
131
568
203
262
223
GGA
487
136
155
504
122
520
194
246
209
LDA
579
132
168
587
178
512
261
242
211
GGA
533
118
151
552
158
476
243
223
198
LDA
513
177
186
590
136
584
216
267
246
GGA
475
160
162
541
123
551
201
246
232
Theo30
473
157
168
546
126
544
201
242
236
LDA
523
178
177
601
127
624
239
271
256
GGA
480
159
160
536
129
553
221
245
233
LDA
647
117
199
491
245
GGA
587
109
190
428
210
Theo34
601
107
185
439
220
35
576
114
198
430
210
Theo
mechanical stability at ground state because the
main reason is that the large number of B-B
elastic constants of these systems obey the Born
covalent
36
bond
stability criteria . The obtained elastic constants
deformation
of Nb3B4 and NbB2 are in good agreement with
However,
the
reported
Furthermore,
results30,34-35.
theoretical
the
calculated
shear
elastic
effectively
resistance the
along
deformation
enhances the
the
a-axis.
resistance
is
determined not only by B-B covalent bond but also by other factors such as layered structure
constant C44 of Nb5B6 and Nb2B3 is 261 GPa and
and orientation of bonds. For Nb2B, Nb3B2,
239 GPa, respectively, which is larger than the
Nb5B6 and NbB2, the calculated elastic constant
corresponding elastic constant of WB2 (206
C11 is larger than that of elastic constant C33. On
GPa), and is close to the C44 of ReB2 (282
the contrary, the calculated elastic constant C11
GPa)37. Those results mean that those Nb-B
of NbB, Nb3B4 and Nb2B3 is lower than that of
compounds have strong shear deformation
elastic constant C33. Those results indicate that
resistance in comparison of WB2 and ReB2.
the incompressible of NbB, Nb3B4 and Nb2B3
Therefore, it is concluded that they are expected
along the c-axis is stronger than that of a-axis.
to have the high elastic modulus and hardness. It
This discrepancy derived from the structural
should be mentioned that this discrepancy is
feature (see Figure 2). It is suggested that the
attributed
atomic
deformation resistance of a solid is related to the
arrangement (see Figure 2(d) and Figure 2(f)).
applied load along the a-c plane. From Figure 2,
to
the
orientation
of
The discussion will be below in detail.
the chemical bonding in a-c plane for NbB,
As listed in Table 2, the elastic constant C11
Nb3B4 and Nb2B3 is different from the Nb5B6.
increases from 460 GPa to 647 GPa for Nb2B
Therefore, the strong chemical bonding indicates
and NbB2, with increasing B concentration. The
that the layered structure along the b-axis 6
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The Journal of Physical Chemistry
strengthens the deformation resistance along the
in high bulk modulus.
c-axis (the detailed discussion will be below).
However, the trend of shear modulus of
Although the structural feature of Nb5B6 is
Nb-B compounds is different from the bulk
similar to the NbB, Nb3B4 and Nb2B3, the
modulus. From Figure 3(b), the calculated shear
orientation of layered structure the former is
modulus of Nb-B compound increases with
different from the later. As a result, the above
increasing B concentration when B60.0 at%. The obtained
decreases
with
increasing
B
calculated elastic constant C33 of Nb2B3 is about
shear modulus of Nb2B3 is 235 GPa by LDA,
of 624 GPa, which is larger than that of other
which is larger than that of other Nb-B
Nb-B compounds. The convex hull indicates that
compounds. The convex hull implies that the
the Nb2B3 has the strongest incompressible
Nb2B3 has the strongest shear deformation
(c-axis) among those Nb-B compounds.
resistance in those Nb-B compounds. Therefore,
As mentioned above, the elastic modulus
it is suggested that the variation of shear
and hardness of Nb-B compounds should be
modulus
discussed. According to the structural symmetry,
concentration but also by the chemical bonding
the bulk modulus and shear modulus of Nb-B
such as bonding type and orientation of bond,
compounds are calculated by Voigt-Reuss-Hill
especially for bond strength between layer-layer.
38
is
determined
not
only
by
B
(VRH) approximation method . Therefore, the
According to the structural feature, the cohesive
Young′s modulus and Poisson′s ratio are
force for layered structure is crucial to
obtained through the relationship between bulk
understand the origin of elastic and plastic
39
modulus and shear modulus . Figure 3 shows the calculated bulk modulus and shear modulus of Nb-B compounds as a function of B concentration. It can be seen that the obtained bulk modulus and shear modulus of Nb3B4 and NbB2 are in good agreement with the previous theoretical results30,34. The calculated bulk modulus increases linearly with increasing B concentration. In going from Nb2B to NbB2, the increase in bulk modulus is about of 28.4 %. It is suggested that the increase in bulk modulus is related to the chemical bonding, especially for B-B covalent bond. As we known, the bond strength of B-B covalent bond is much stronger than that of Nb-B bond and Nb-Nb metallic bond. With increasing B concentration, a large number of B-B covalent bonds can be formed in those Nb-B compounds. On the other hand, the increased concentration of B decreases the
Figure 3. The calculated elastic modulus of
number of Nb-Nb metallic bond. Therefore, the
Nb-B
strong B-B covalent bonds obviously enhance
concentration, (a) bulk modulus, (b) shear
the resistance to volume deformation and result
modulus.
compounds
as
a
function
of
B
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deformations
in
comparison
with
the
2D-network chemical bonding.
covalent
bond.
However,
the
calculated hardness of Nb2B3 is larger than that
As shown in Figure 3, the calculated bulk modulus and shear modulus of Nb2B3 are larger than that of OsB2 and RuB2
3D-network
Page 8 of 16
40-41
of NbB2 with 3D-network Nb-B bonds. In particular,
the
ideal
diamond-structure
is
. Obviously, the
impossible to exist for all most of TMBs.
Nb2B3 may be expected to have high hardness
Therefore, the nature of hardness is related
among those Nb-B compounds. To evaluate the
determined not only by the 3D-network bonding
theoretical hardness, the hardness of Nb-B
state, but also by other factors.
compounds in this paper is calculated by 42
semi-empirical hard model :
To understand the hard discrepancy, we further calculated the Young′s modulus and Poisson′s ratio of Nb-B compounds as a function
H v = 2 ⋅ (k 2 ⋅ G ) 0.585 − 3
(2)
of B concentration. To our knowledge, the Young′s modulus of a solid indicates the degree
where k represents the B/G ratio and G is the
of elastic stiffness. The general trend is, the
shear modulus, respectively.
higher the Young′s modulus, the stronger the
Figure 4 depicts the calculated theoretical
elastic stiffness. On the other hand, the Poisson′s
hardness of Nb-B compounds as a function of B
ratio indicates the degree of covalent bonding.
concentration. It can be seen that the hard trend
The lower the Poisson′s ratio is, the stronger the
of Nb-B compounds is similar to the shear
covalent bonding is. Figure 5 shows the
modulus. The convex hull from Figure 4
calculated Young′s modulus and Poisson′s ratio
indicates that the Nb2B3 shows the highest
of Nb-B compounds as a function of B
hardness in those Nb-B compounds. It is
concentration. The trends of Young′s modulus
interesting to note that the calculated hardness of
and Poisson′s ratio are consistent with the shear
Nb2B3 is about of 33.5 GPa, which is close to the
modulus and hardness. The calculated Young′s
43
44
OsB2 (35.2 GPa) and WC (35.6 GPa) . That is
modulus of Nb2B3 is 559 GPa by LDA, which is
to say, the TMBs with low valence electronic
larger than that of OsB2 and RuB240. The convex
density also form the potential superhard
hull implies that the Nb2B3 has strongest elastic
materials. Obviously, this result is different from
stiffness in those Nb-B compounds.
45
design principle of TMBs superhard materials .
The calculated Poisson′s ratio of Nb2B3 is only about of 0.190, which is smaller than that of NbB2 (0.203), meaning that the Nb2B3 has strong covalent bonding. According to the structural feature (see Figure 2), the strong B-B covalent bond and Nb-B bond are observed in Nb2B3. However, the 3D-network Nb-B bonds play an important role in NbB2. It is explained why the elastic modulus and hardness of Nb2B3 are larger than that of NbB2. On the other hand, although
Figure 4. The calculated theoretical hardness of Nb-B
compounds
as
a
function
of
B
concentration.
the atomic arrangement of Nb5B6 is similar to the Nb2B3, the orientation of bonds the former is different from the latter. This result is very demonstrated by charge density distribution.
According the structural feature of diamond, the origin of high hardness comes from the
Moreover, the B/G ratio is used to describe the brittleness or ductility of a material within 8
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The Journal of Physical Chemistry
Figure 6. The calculated B/G ratio of Nb-B compounds as a function of B concentration. The solid line indicates the convex hull. chemical bonding are key factors to deeper understanding the origin of hardness and elastic properties. Following the density of states (DOS) and bond characteristic are calculated and analyzed, here. Considering the structural feature, Figure 5. The calculated Young′s modulus and
we select four typical structures such as Nb2B,
Poisson′s ratio of Nb-B compounds as a function
NbB, Nb2B3 and NbB2. Figure 7 represents the
of B concentration, (a) Young′s modulus, (b)
total and partial density of states of four different
Poisson′s.
Nb-B compounds, and the black vertical dashed of DOS indicates the Fermi level (EF). It is clear
1.75 as the critical value46. If B/G
