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Article

Influence of Fatty Acid Alkyl Chain Length on Anisotropy of Copper Nitride Nano-Crystallites

Research Institute for Chemical Process Technology, National Institute of Advanced Industrial Science and Technology (AIST), Nigatake 4-2-1, Miyagino-ku, Sendai 983-8551, Japan
Inorganics 2017, 5(1), 6; https://doi.org/10.3390/inorganics5010006
Submission received: 30 September 2016 / Revised: 23 December 2016 / Accepted: 11 January 2017 / Published: 16 January 2017
(This article belongs to the Special Issue Novel Solid-State Nitride Materials)

Abstract

:
My group developed a simple method to prepare copper nitride fine particles from copper carboxylate in a solvent of long-chain alcohols without the use of high temperatures or high pressures. By selecting copper acetate or copper decanoate as the copper source, my group demonstrated that the morphology of the copper nitride fine particles varied between cubic and plate-like, respectively. Although a hypothesis was proposed to explain the influence of the length of the alkyl chain on the copper decanoate, it is uncertain how much the chain length influences the shape of the fine particles. In this work, I demonstrated the effect of the length of the alkyl chain on particle shape by preparing fine particles from a series of copper sources with different alky chain lengths and characterizing the particles with x-ray diffractometry (XRD), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). The main findings were as follows: (1) the fine particles were plate-like when the alkyl chain length exceeded 5; (2) the aspect ratio of the plate-like particles increased as the alkyl chain length increased; and (3) growth of the (110) and (111) planes of the copper nitride crystal were selectively inhibited.

Graphical Abstract

1. Introduction

To elicit high performance from inorganic crystals with respect to their catalytic [1,2,3] and photonic properties [4,5,6], it is important to understand the chemical conditions on the crystal surface and to control the crystal planes. Investigating the relationship between the crystal surface and crystal functionality is facilitated with the use of fine particles. One goal of catalyst research is to increase the proportion of chemically active atoms on the catalyst surface. Differences in catalytic efficiency due to variations of the crystal planes are therefore very important. In studies of the optical properties of inorganic crystals, quantum size effects are important when fine particles, especially nanoparticles, are being used. The relationship between crystal shape and light (electromagnetic waves) can be evaluated with knowledge of quantum chemistry.
In studies of the use of colloids and fine particles for inorganic crystals, the morphologies of crystallites and particles have often been controlled by using surface modifiers [7,8]. In such cases, the phenomenon of selective adsorption of the surface modifier to a specific crystal face is utilized. The reaction temperature used to prepare the particles is also an important regulator of particle size when modifiers are used. Changes in crystal shape arise from the balance between the thermodynamic stability of the crystal at a given temperature and the suppression of growth of the specific crystal plane by the surface modifier. At a high reaction temperature, the surface modifiers desorb from the crystal surface, because their kinetic energy exceeds the energy of adsorption. Under such conditions, it becomes advantageous for the inherent structure of the crystal to be thermodynamically stable. Moreover, surface modifiers that are organic molecules decompose at high reaction temperatures.
Although methods for controlling the morphology of fine particles such as metals [1,8,9] and metal-oxide inorganic [2,4,10] compounds have been studied widely, there have been few such studies of metal nitride compounds [11]. This study concerned control of the morphology of metal nitride compounds. Metal nitrides are generally synthesized at temperatures >350 °C [12,13]. Here my group reported a method that can be used to synthesize metal nitrides, especially copper nitride, at temperatures lower (<200 °C) than those used in conventional methods. My group hypothesized that control of the shape of metal nitride particles can be studied by using this new method. The following is a brief summary of relevant background information.
The focus of this study was the development of a method for preparing copper nitride fine particles and application of that method. Copper nitride has been synthesized using a variety of methods, including solid-phase [14,15,16,17] and liquid-phase [18,19,20] reactions. In the liquid phase, copper nitride fine particles have previously been prepared under harsh conditions: copper chloride and sodium azide in toluene as a solvent were heated in a closed vessel at 185 °C at 4.8 MPa [18], and copper nitrate was heated in 1-octadecylamine at 250 °C [19]. The method described here does not require high temperature and high pressure. For example, copper acetate and ammonia gas were heated in a long-chain alcohol solvent at 190 °C at 1 atm of pressure [21]. Furthermore, my group found that copper nitride fine particles could be prepared using the reaction between copper acetate and urea, without the use of toxic and corrosive gases such as ammonia [22].
The method described here is a facile and safe way to prepare copper nitride fine particles and is characterized by low-temperature (<200 °C) reaction conditions. Thermally mild conditions are advantageous for controlling crystal morphology. On the basis of this consideration, my group synthesized copper nitride fine particles by using different copper sources, such as copper acetate and copper decanoate [23]. The decanoate served as an organic surfactant. The crystallites (primal particles) of copper nitride obtained by preparation with copper acetate and copper decanoate were morphologically cubic and plate-like particles, respectively. The shape of the crystallite of copper nitride was basically anisotropic if a fatty acid copper salt was used as a reagent. In a previous study, my group hypothesized that the alkyl chain length of the fatty acid influences the crystal morphology [23]. However, the extent to which the length of the alkyl moiety influences anisotropy has been unclear. Furthermore, it was unclear why an anisotropic crystal of copper nitride was formed.
In this work, to address these uncertainties, fatty acid copper salts with slightly varying alkyl chain lengths were prepared based on my experience [24], and then the effect of the alkyl chain length on the anisotropy of the nanocrystallite of copper nitride was investigated. In particular, copper nitride was prepared by using fatty acid copper salts with a series of different alkyl chain lengths ranging from n = 0 to 12 at n intervals of 1–3 (Figure 1 and Table 1). Direct observations via electron microscopy and characterization by using powder X-ray diffraction with Scherrer analysis were then used to determine how much the length of the alkyl chain influenced the crystal structure of the copper nitride. Finally, the mechanism responsible for the anisotropy of the copper nitride is proposed.

2. Results

2.1. Observations of Particle and Crystallite Shape

The samples prepared from each fatty acid copper salt reagent were observed by scanning electron microscopy (SEM) and transmission electron microscopy (TEM) to determine the shape of the whole particles as well as the crystallite shape and internal structure of the particles, respectively (Figure 2).
For the sample prepared by using CuC2 as a reagent, round particles with diameters of approximately 200 nm were observed by SEM (Figure 2s1). Cubic particles were also observed in some places. The TEM observations (Figure 2t1) revealed round particles that consisted of cubic crystallites. For the sample prepared from CuC3 (Figure 2s2,t2), the particles and crystallites were the same as the particles prepared from CuC2. Namely, use of the CuC3 reagent produced round particles that consisted of cubic crystallites. The SEM image of the particles prepared from CuC3 revealed constituent particles that were clearly distinguishable from the main particle.
For the sample prepared from CuC6, the SEM image revealed constituent particles with plate-like shapes (Figure 2s3). The TEM image (Figure 2t3) revealed aggregate particles that consisted of primary particles with dimensions of approximately 10 and 30 nm in the directions of the short and long axes, respectively. For the sample prepared from CuC8 (Figure 2s4,t4), the morphologies of the secondary and primary particles were similar to those of particles prepared from CuC6.
For the sample prepared from CuC10 (Figure 2s5,t5), the morphology of the primary particles was plate-like but thinner than the particles prepared from CuC6. The dimensions of the primary particles prepared from CuC10 were approximately 5 and 40 nm in the direction of the short and long axes, respectively. Observations of the samples prepared from CuC12 (Figure 2s6,t6) and CuC14 (Figure 2s7,t7) revealed secondary particles that consisted of plate-like particles, similar to the particles prepared from CuC10.
The series of SEM and TEM observations described above revealed that the morphology of the copper nitride fine particles was plate-like when the fatty acid copper salt used to prepare the fine particles had an alkyl-chain length greater than 5. Moreover, the morphology of the plate-like crystallite became thinner when a fatty acid copper salt with an alkyl chain length >9 was used.

2.2. Powder XRD Measurement and Analysis of Crystallite Size

I used a powder x-ray diffractometry (XRD) to characterize the crystal phase of the samples and to analyze crystallite sizes (Figure 3). The XRD patterns were normalized to compare shape of peaks for each obtained pattern. Peaks of all the samples were assigned to copper nitride. The XRD pattern of the sample prepared from CuC2 is described here as a representative example. The XRD pattern showed peaks at 23.466°, 33.367°, 41.180°, 47.895° and 54.070°. These peaks were attributed to the (100), (110), (111), (200), and (210) planes of copper nitride (PDF2 No. 01-073-6209), respectively. No peaks were attributed to copper, copper oxide(I), or copper oxide(II) in the pattern.
Previously crystal structure and planes for (100), (110) and (111) of copper nitride are shown in Figure 4 for ease of imagination.
The peaks in the patterns for the (110), (111) and (210) planes became broader when the alkyl chain length of the fatty acid copper salts was increased. The width of the peak was due to a reduction of crystallite size and increase of the internal strain of the crystallite. My group has previously demonstrated that an increase of the width of the peaks for the nano-crystallite of copper nitride is due to a reduction of the crystallite size [23]. Based on that previous work, crystallite sizes were estimated from full width at half-maximum (FWHM) by using the Scherrer equation after peak fitting with a pseudo-Voigt function.
Table 2 shows estimated peak positions and FWHMs from the peak fitting and calculated lattice spacing and crystallite sizes. The values of the lattice spacing for the (100), (110), (111), (200) and (210) planes differed very little between reagents. The standard errors were less than 0.0002 nm. The crystallite sizes of the copper nitride fine particles prepared by using different reagents decreased when the alkyl chain length of the fatty acid copper salt increased. For each crystal plane, the difference between the largest and smallest crystallite size was less than approximately 18 nm.
I next compared the ratios of the (100), (110), (111), (200) and (210) crystallite sizes to the crystallite size of the (100) plane (Table 2 and Figure 5). These ratios were significantly less than 1 for the (110), (111) and (210) planes. For the (111) plane, the ratio decreased significantly with increasing alkyl chain length.

3. Discussion

Electron microscopic observations of crystallite morphologies and XRD analysis of crystallite sizes and their ratios for each crystal plane showed that the morphology of the copper nitride crystallite was anisotropic when the fine particles were prepared from a fatty acid copper salt with an alkyl chain length exceeding 5 (copper hexanoate). Furthermore, the aspect ratio of the anisotropic shape increased when the fine particles were prepared from a fatty acid copper salt with an alkyl chain length greater than 9 (copper decanoate).
My group hypothesizes that the phenomenon described above can be explained by the fact that crystal growth for a specific plane was inhibited by the surfactant characteristics of the fatty acid. The inhibition of crystal growth and the resultant crystal morphology have been discussed in the context of the copper nitride reaction mechanism previously described in our work [21].
My group has previously proposed the following mechanism (Scheme 1):
The nitridation of copper gave a clear color change as shown in Scheme 1, and the change could be also confirmed in UV-Vis absorption spectrum [21].
Copper acetate monohydrate, which is insoluble in a solvent consisting of a long-chain alcohol, dissolves in the solvent because of formation of an ammine complex due to bubbling of ammonia gas. When the solution is heated to over 120 °C, the copper in the acetate ammine complex is reduced from a bivalent copper ion to a monovalent copper ion by the long-chain alcohol. At the time of the reduction, the ammonia attacks the monovalent copper complex, and, as a result, a bond between the copper atom and nitrogen atom is formed. Copper nitride is formed by sequential progression of the reaction in the solvent.
During this process of nitride formation, the shape of the copper nitride crystal becomes anisotropic due to adsorption of fatty acids on the specific surface of the copper nitride and inhibition of approaching ammonia molecules by the alky chain of the fatty acids. Based on this conclusion, I consider that the following phenomena cause the crystallite of copper nitride to be anisotropic:
1. The accession of the ammonia molecule to the crystal surface is inhibited by steric repulsion of the alkyl chain of the fatty acid, which behaves like a surfactant.
2. The fatty acid strongly coordinates on the (110) and the (111) surfaces of copper atoms, for which the atomic length is 0.27 nm.
These two phenomena are discussed in detail below.
The steric barrier increases when the length of the alkyl chain increases. Elaboration of this point is unnecessary because it follows from a basic understanding of chemistry.
Figure 6 indicates the atomic distance between the copper atoms of the copper nitride crystal and the oxygen atoms of the carboxylate. For copper nitride, the atomic distances of 0.38 and 0.27 nm correspond to the lengths of the (100) direction and the (110) direction of the unit cell. For the carboxylate, the distance between the oxygen atoms is 0.226 nm. In comparison to the atomic distances of 0.38 with 0.27 nm for the copper nitride crystal, the carboxylate is strongly coordinated on the surface within a distance of 0.27 nm from the coppers because of the close similarity of the copper–copper and oxygen–oxygen distances.
The coupling between the copper nitride surface and the carboxylate group could be explained by several possible modes, including a unidentate, bidentate, and bridging complex [25]. The coupling form is assigned by using the Δ value of the wavenumber for FT-IR, which was estimated from the difference between the symmetric and asymmetric stretching modes. The Δ values for the unidentate, bidentate, and bridging complex were approximately 200, 50, and 150 cm−1, respectively. For the FT-IR spectrum of copper nitride fine particles in previous work, the wavenumbers attributed to the symmetric and asymmetric stretching modes were 1557 and 1403 cm−1, respectively (in the previous work [21], the wavenumber of 1403 cm−1 was misallocated as a deformation vibration of N–H). The Δ value of the carboxylate ion on the copper nitride surface was 154 cm−1. The carboxylate ion coordinates on the surface in the form of a bridge.
Figure 7 shows the relationships between the construction on the crystal surface and the copper and nitrogen atoms that form the next layer for different crystal planes of copper nitride.
For the (100) plane, there are two layers on which the copper atom distances (LCu–Cu) are 0.38 and 0.27 nm. These layers are designated as the (100)A and (100)B layers, respectively. To grow the next crystal layer, only copper atoms approach the (100)A surface, and the (100)B layer is formed. Copper and nitrogen (derived from ammonia) atoms then approach the (100)B layer, and the (100)A layer is formed.
For the (110) plane, there are two layers designated as (110)A and (110)B. In the case of the (110)A layer, the surface consists of copper atoms separated by a distance of 0.27 nm. The (110)B layer consists of copper atoms separated by two different distances, 0.38 and 0.27 nm. To form the next crystal layer, copper and nitrogen atoms approach the (110)A layer, and the (110)B layer is formed. Only copper atoms then approach the (110)B layer, and the (110)A layer is formed.
For the (111) plane, there are two layers designated as (111)A and (111)B. The (111)A and (111)B layers consist of only copper and only nitrogen atoms, respectively. For both layers, the copper atoms are 0.27 nm apart. To form the next crystal layer, only nitrogen atoms approach the (111)A layer, and the (111)B layer is formed. To form the next (111)A layer, only copper atoms approach the (111)B layer.
I compared this articulation of the crystal growth of copper nitride with the experimental results. The experimental results revealed that growth of the (110) and (111) planes of the copper nitride crystal were inhibited. For the (110)A and (111)A surfaces, the inhibition was caused by the strong adsorption of fatty acid on the (110) and (111) surfaces, for which the LCu–Cu distance was 0.27 nm before the nitride atoms derived from ammonia approached the surfaces.
The anisotropic growth of the copper nitride crystal was thus caused by selective adsorption of the fatty acid and the barrier of the alkyl chain against ammonia.
In future work, I will examine and reveal the adsorption energy between crystal surfaces of copper nitride and surfactants, not only fatty acids but also other surfactants, by means of first-principle calculations and synthetic experiments.

4. Materials and Methods

4.1. Materials

Copper(II) acetate monohydrate (Guaranteed Reagent) and copper(II) propionate monohydrate (>97.5%) were purchased from Kanto Chemical (Tokyo, Japan) and Mitsuwa Chemicals (Osaka, Japan), respectively. Sodium hexanoate (extra pure), sodium octanoate (extra pure), sodium decanoate (extra pure), sodium laurate (extra pure), sodium myristate (extra pure), and 1-nonanol (>97%) were purchased from the Tokyo Chemical Industry (Tokyo, Japan). Copper nitrate trihydrate (>99.5%) was purchased from the Kishida Chemical Company (Osaka, Japan). Ammonia gas (>99.999%) was purchased from Taiyo Nippon Sanso (Tokyo, Japan). These reagents were used without further purifications.

4.2. Synthesis and Characterization of the Fatty Acid Copper Salt as a Starting Reagent

The fatty acid copper salts used as starting reagents were synthesized in accord with previous works [23,24].
Here I describe the method of preparing copper hexyanoate (CuC6). When other starting reagents such as copper octanoate (CuC8), copper decanoate (CuC10), copper dodecanoate (CuC12), and copper tetradecanoate (CuC14) were synthesized, the fatty acid sodium salts were changed to the fatty acid sodium salts with the appropriate alkyl chain length.
Sodium hexanoate (51 mmol) was completely dissolved in deionized water (400 mL) at 80 °C. Copper(II) nitrate trihydrate (25 mmol) in deionized water (100 mL) was added to the solution. Green precipitates were immediately formed. The precipitates were collected by filtration, washed with deionized water, and then washed with methanol. A green powder was obtained after drying the precipitates by heating at 60 °C for 12 h under a vacuum.
The molecular weight of the product was measured by using matrix-assisted laser desorption/ionization time-of-flight mass spectroscopy (MALDI-TOF MS) with an autoflex speed MALDI-TOF/TOF mass spectrometer (Bruker Daltonics, Billerica, MA, USA) operated in a reflector mode. The matrix was 9-Nitroanthracene. The spectrum was recorded in a negative ion mode.
The Fourier transform infrared spectrum was measured with a Spectrum 1000 instrument (PerkinElmer Inc., Waltham, MA, USA) equipped with a Universal attenuated total reflection (ATR) sampling instrument (PerkinElmer). The spectrum was recorded at room temperature from 650 to 4000 cm−1 with a spectral resolution of 2 cm−1.
Elemental analysis was carried out with an EA 1110 instrument (CE Instruments, Wigan, UK) for carbon and hydrogen. Oxygen was measured using a Flash EA 1112 instrument (CE Instruments).
Copper hexanotate (CuC6). Analytical data. 50% yield; MALDI-TOF (m/z): [M] calculated for C12H22CuO4, 293.09; found, 293.10 FT-IR (ATR method): 2929 (CH3), 2859 (CH2), 1565 (COO), 1532, 1464, 1414, 1344, 1303, 1070, and 1035 cm−1. Theoretical composition of C12H22CuO4: C, 49.05; H, 7.55; O, 21.78%. Found: C, 46.37; H, 7.20; O, 22.47%.
Copper octanoate (CuC8). Analytical data. 56% yield; MALDI-TOF (m/z): [M] calculated for C16H30CuO4, 349.15; found, 349.25. FT-IR (ATR method): 2924 (CH3), 2854 (CH2), 1569 (COO), 1413, 1378, 1343, 1302, 1069, and 1033 cm−1. Theoretical composition of C16H30CuO4: C, 54.91; H, 8.64; O, 18.29%. Found: C, 45.70; H, 7.48; O, 20.54%.
Copper decanoate (CuC10). Analytical data. 92% yield; MALDI-TOF (m/z): [M] calculated for C20H38CuO4, 405.22; found, 405.29. FT-IR (ATR method): 2915 (CH3), 2849 (CH2), 1580 (COO), 1488–1384 (CH3, CH2), 1340, 1316, 1301, 1276, 1070, 1035, 1014, 888, and 877 cm−1. Theoretical composition of C20H38CuO4: C, 59.16; H, 9.43; O, 15.76%. Found: C, 58.64; H, 9.30; O, 15.81%.
Copper dodecanoate (CuC12). Analytical data. 95% yield; MALDI-TOF (m/z): [M] calculated for C24H46CuO4, 461.28; found, 461.33. FT-IR (ATR method): 2915 (CH3), 2849 (CH2), 1581 (COO), 1467, 1422, 1317, 1116, and 1069 cm−1. Theoretical composition of C24H46CuO4: C, 62.37; H, 10.03; O, 13.85%. Found: C, 61.86; H, 9.90; O, 13.88%.
Copper tetradecanoate (CuC14). Analytical data. 95% yield; MALDI-TOF (m/z): [M] calculated for C28H54CuO4, 517.34; found, 517.35. FT-IR (ATR method): 2913 (CH3), 2849 (CH2), 1582 (COO), 1513, 1467, 1436, 1422, 1317, and 1118 cm−1. Theoretical composition of C28H54CuO4: C, 64.89; H, 10.50; O, 12.35%. Found: C, 64.91; H, 10.43; O, 12.24%.

4.3. Preparation and Characterization of Copper Nitride Fine Particles

Copper nitride fine particles were prepared in accord with a previous report [21] with modifications. Specifically, the copper acetate starting reagent was changed to synthesized fatty acid copper salts.
A dispersion of copper acetate monodydrate (2 mmol) in 1-nonanol (400 mL) was bubbled with ammonia (100 mL/min) and heated at 190 °C for 40 min (ramp time, 10 min; hold time, 30 min) in a μReactor Ex microwave heater (2.45 GHz, Shikoku Instrumentation, Kagawa, Japan) equipped with a fiber-optic thermometer (AMOTH FL-2000, Anritsu Meter, Tokyo, Japan). The temperature of the solution was controlled by automatically changing the microwave power. The opaque brown liquid that was obtained from the reaction was super-centrifuged (30,000 g for 60 min) to yield a brown powder, which was washed three times with n-hexane.
The powders that were obtained were characterized by using XRD, SEM and TEM. The crystal structures were determined by using a SmartLab (Rigaku, Tokyo, Japan) with Cu Kα radiation at 40 kV and 30 mA at 2θ = 20°–90°. The morphology of the powder was observed by using an S-4800 microscope (Hitachi High-Technologies, Tokyo, Japan) with an acceleration voltage of 2 kV, an emission current of 10 μA, and a working distance of 3 mm. The morphology of the powder was also observed by using a TECNAI G20 microscope (FEI, Hillsboro, OR, USA) with an acceleration voltage of 200 kV.

5. Conclusions

A crystallite of copper nitride with an anisotropic shape was prepared by using a method to synthesize copper nitride fine particles under mild conditions. Changing the alkyl chain length of the fatty acid allowed me to examine the effect of the chain length on the anisotropy. The results showed that the anisotropic nature of the crystallite was expressed when the length of the fatty acid chain exceeded 5. Based on the experimental results, I considered when anisotropy occurred and concluded that formation of the anisotropic crystallite of copper nitride was caused by the following phenomena:
1. The accession of ammonia molecules to the crystal surface was inhibited by steric repulsion of the alkyl chain of the fatty acid, which functioned as a surfactant.
2. The fatty acid strongly coordinated on the (110) and the (111) surfaces of the copper atoms, the atomic length of which was 0.27 nm.

Acknowledgments

This work was financially supported by a grant from the A-STEP (Adaptable and Seamless Technology Transfer Program through Target-Driven R&D) program of the Japan Science and Technology Agency (feasibility study stage, No. AS232Z00276C).

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

The following abbreviations are used in this manuscript:
ATRattenuated total reflection
FWHMfull width at half-maximum
MALDI-TOF MSmatrix-assisted laser desorption/ionization time-of-flight mass spectroscopy
SEMscanning electron microscopy
TEMtransmission electron microscopy
XRDx-ray diffractometry

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Figure 1. Chemical structure of starting reagents with different alkyl chain lengths.
Figure 1. Chemical structure of starting reagents with different alkyl chain lengths.
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Figure 2. Scanning electron microscopy (SEM) (s) and transmission electron microscopy (TEM (t) images of the powders prepared from (1) CuC2; (2) CuC3; (3) CuC6; (4) CuC8; (5) CuC10; (6) CuC12; and (7) CuC14 as starting reagents.
Figure 2. Scanning electron microscopy (SEM) (s) and transmission electron microscopy (TEM (t) images of the powders prepared from (1) CuC2; (2) CuC3; (3) CuC6; (4) CuC8; (5) CuC10; (6) CuC12; and (7) CuC14 as starting reagents.
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Figure 3. X-ray diffractometry (XRD) patterns of samples prepared from different starting reagents.
Figure 3. X-ray diffractometry (XRD) patterns of samples prepared from different starting reagents.
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Figure 4. Images of (a) an original crystal structure of copper nitride; (b) a (100) plane; (c) a (110) plane; and (d) a (111) plane.
Figure 4. Images of (a) an original crystal structure of copper nitride; (b) a (100) plane; (c) a (110) plane; and (d) a (111) plane.
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Figure 5. Ratio of size of each crystal plane to the size of the (100) plane.
Figure 5. Ratio of size of each crystal plane to the size of the (100) plane.
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Scheme 1. A reaction mechanism to form copper nitride (Ac, acetyl; R, C8H17). Insert characters indicate solution colors.
Scheme 1. A reaction mechanism to form copper nitride (Ac, acetyl; R, C8H17). Insert characters indicate solution colors.
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Figure 6. Images of (a) the crystal structure of copper nitride and (b) the molecular structure of the acetate ion.
Figure 6. Images of (a) the crystal structure of copper nitride and (b) the molecular structure of the acetate ion.
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Figure 7. Images of atomic arrays on the (100), (110) and (111) surfaces of copper nitride and elements that form the next crystal layer.
Figure 7. Images of atomic arrays on the (100), (110) and (111) surfaces of copper nitride and elements that form the next crystal layer.
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Table 1. Abbreviations for starting reagents.
Table 1. Abbreviations for starting reagents.
IUPAC NameCommon NameLength of Alkyl ChainAbbreviation for Reagent
Copper ethanoateCopper acetate1CuC2
Copper propanoateCopper propionate2CuC3
Copper hexanoateCopper caproate5CuC6
Copper octanoateCopper caprylate7CuC8
Copper decanoateCopper caprinate9CuC10
Copper dodecanoateCopper laurate11CuC12
Copper tetradecanoateCopper myristate13CuC14
Table 2. Estimated values from peak fitting of XRD patterns.
Table 2. Estimated values from peak fitting of XRD patterns.
Starting Reagents2θ (°)Lattice Spacing (nm)
(100)(110)(111)(200)(210)(100)(110)(111)(200)(210)
CuC223.46633.36741.18047.89554.0700.37880.26830.21900.18980.1695
CuC323.38433.27741.08747.81053.8910.38010.26900.21950.19010.1700
CuC623.42733.33541.08347.81853.9300.37940.26860.21950.19010.1699
CuC823.43733.30641.08847.84153.9770.37930.26880.21950.19000.1697
CuC1023.50033.44641.11047.88553.9490.37830.26770.21940.18980.1698
CuC1223.38333.28841.05547.79553.7520.38010.26890.21970.19020.1704
CuC1423.41633.24441.06547.84053.7800.37960.26930.21960.19000.1703
FWHM (°)Crystallite Size (nm)
(100)(110)(111)(200)(210)(100)(110)(111)(200)(210)
CuC20.46730.49090.58890.48730.577113.4411.4510.6713.6411.84
CuC30.20500.27560.29570.25230.229527.0822.2219.8424.0922.87
CuC60.47170.66301.00920.57250.663011.457.875.9810.168.11
CuC80.46880.66070.88650.54180.629912.358.277.0711.3610.03
CuC100.56171.18001.72350.69041.13009.254.193.568.256.38
CuC120.53870.85531.26360.64721.04439.966.174.758.886.16
CuC140.53010.78671.31840.62500.919010.126.864.799.397.75
Ratio of the Crystallite Size of Each Crystal Plane to the Crystallite Size of the (100) Plane
(100)(110)(111)(200)(210)
CuC21.000.850.791.010.88
CuC31.000.820.730.890.84
CuC61.000.690.520.890.71
CuC81.000.670.570.920.81
CuC101.000.450.390.890.69
CuC121.000.620.480.890.62
CuC141.000.680.470.930.77
Note: FWHM = full width at half-maximum.

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Nakamura, T. Influence of Fatty Acid Alkyl Chain Length on Anisotropy of Copper Nitride Nano-Crystallites. Inorganics 2017, 5, 6. https://doi.org/10.3390/inorganics5010006

AMA Style

Nakamura T. Influence of Fatty Acid Alkyl Chain Length on Anisotropy of Copper Nitride Nano-Crystallites. Inorganics. 2017; 5(1):6. https://doi.org/10.3390/inorganics5010006

Chicago/Turabian Style

Nakamura, Takashi. 2017. "Influence of Fatty Acid Alkyl Chain Length on Anisotropy of Copper Nitride Nano-Crystallites" Inorganics 5, no. 1: 6. https://doi.org/10.3390/inorganics5010006

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