Next Article in Journal
Critical Overview on Regenerative Medicine: New Insights into the Role of Stem Cells and Innovative Biomaterials
Next Article in Special Issue
Rational Design of Bifunctional Microporous Organic Polymers Containing Anthracene and Triphenylamine Units for Energy Storage and Biological Applications
Previous Article in Journal
Topical Alginate Protection against Pepsin-Mediated Esophageal Damage: E-Cadherin Proteolysis and Matrix Metalloproteinase Induction
Previous Article in Special Issue
Mechanistic Insights into the Biological Effects of Engineered Nanomaterials: A Focus on Gold Nanoparticles
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
IJMS
Volume 24
Issue 9
10.3390/ijms24097933
ijms-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Review on Generation and Characterization of Copper Particles and Copper Composites Prepared by Mechanical Milling on a Lab-Scale

by
Sebastián Salazar Sandoval
* and
Nataly Silva
*
Facultad de Diseño, Universidad del Desarrollo, Avenida Plaza 680, Las Condes, Santiago 7610658, Chile
*
Authors to whom correspondence should be addressed.
Int. J. Mol. Sci. 2023, 24(9), 7933; https://doi.org/10.3390/ijms24097933
Submission received: 24 March 2023 / Revised: 24 April 2023 / Accepted: 25 April 2023 / Published: 27 April 2023
(This article belongs to the Special Issue Recent Advances in Nanomaterials Science)
Browse Figures
Versions Notes

Abstract

:
This review aims to expose mechanical milling as an alternative method for generating copper-based particles (copper particles (CuP) and copper composites (CuC)); more specifically, via a top-down or bottom-up approach, on a lab-scale. This work will also highlight the different parameters that can affect the size distribution, the type, and the morphology of the obtained CuP or CuC, such as the type of mechanical mill, ball-to-powder ratios (BPR), the milling speed, milling time, and the milling environment, among others. This review analyzes various papers based on the Cu-based particle generation route, which begins with a pretreatment step, then mechanical milling, its approach (top-down or bottom-up), and the post-treatment. Finally, the characterization methods of the resulting CuP and CuC through mechanical milling are also discussed.

1. Introduction

There is a growing interest in Cu-based materials due to the metal’s intrinsic properties, such as high electrical and thermal conductivity, resistance to corrosion, malleability, and anti-microbial activity. Cu-based materials present promising prospects in optics, conductive films, medicine, and manufacturing of anti-microbial materials, among others [1,2,3]. Furthermore, Cu is abundant and much less expensive than other noble metals in research, namely gold or silver, making its studies more affordable. Under that premise, Cu plays a fundamental and universal role on a daily basis. For example, Cu has been used in piping for water distribution due to its durability and anti-microbial activity. Additionally, it is the main conductive component in electric wiring. Notably, Cu-based materials became more prominent with the emergence of SARS-CoV-2, acting as coating agents and assessing anti-microbial activity on surfaces, preventing fomite transmission [4,5,6]. Although the anti-microbial efficacy of Cu surfaces has been extensively studied, Cu-based materials usually cannot be used in the as-received state. Thus, their further processing is necessary [7]. This downside can be overcome by obtaining such materials in a different format, such as copper particles (CuP), in micro- and nano-metric sizes, and copper composites (CuC), thus allowing its incorporation in diverse applications while also being cost-effective.

2. Generation of Copper Particles and Composites

The generation of CuP and CuC with different sizes and morphologies has been extensively reported by different methods, displaying their respective advantages and disadvantages [8,9,10,11]. The difficulty generating CuP can be attributed to their tendency to oxidize when exposed to air, thus making it imperative to use an inert gas atmosphere and surfactants to prevent oxidation [2,12]. While CuP can be generated using physical and chemical methods, eco-friendly and greener approaches have gained much interest in recent years [13,14,15].
Some of the generation routes of CuP are summarized in Figure 1. The generation route will be a determinant in the physicochemical properties of the obtained CuP, such as size distribution, diameter, toxicity, stability, anti-microbial properties, and biological activity [15,16].
Among the physical methods for generating CuP or CuC, mechanical milling has been used to produce these materials as powders or grains [17,18,19]. The advantages of using mechanical milling as a generation route include forming finer particles without using hazardous solvents or high temperatures, controlling the degradation process, and the ability to homogenize otherwise immiscible materials. Furthermore, this method can also be used to treat waste and recycle materials to develop new composites or particles. Mechanical milling consists of reducing the metal precursor to a micro- or nano-metric size (top-down approach) or assembling larger structures due to the blending of the precursor salts (bottom-up approach) [20,21]. The mechanical mills can be grouped by their energy output, and the process can be carried out using conventional ball milling (CBM) or high-energy ball milling (HEBM). CBM is a powder-processing technique for reducing particle sizes and mixing different materials. This technique is widely used in mineral, pharmaceutical, and ceramic industries, as well as lab-scale synthesis. The HEBM technique is very different from CBM and was initially developed for producing new metastable materials, which cannot be made using thermal equilibrium processes [22]. In mechanical milling, kinetic energy is transferred to the precursor powder due to the collision between the former and the milling components (which can be a milling ball, for example), with the pressure and the impact generated by the milling media also playing a pivotal role in reducing or blending the starting material [21,23].
Mills used for CuP or CuC generation are diverse, ranging from ball mills to drum ball mills, planetary mills, vibratory mills, and attrition mills [23,24,25]. Furthermore, types of mills can be classified according to their scale of processing. Figure 2 illustrates the classification of the most common types of ball mills. For large-scale processing, the continuous operation of attrition or vibratory mills and twin-screw extrusion are the most suitable. In turn, for lab-scale processes, planetary ball mills, shaker/vibratory mills, and CBM are the most used [26]. The scope of this review will solely focus on the generation of CuP and CuC on a lab-scale.
Mechanical milling can be categorized according to the changes that the precursor powders undergo [27,28,29]. The first category is mechanical activation, which occurs when the precursor remains chemically unchanged [24,26,30]. The second corresponds to mechanochemical reactions, where chemical changes are observed due to the influence of mechanical energy. Mechanical alloying can be classified into this group of processes [26,31]. Although their milling mechanisms are different, the parameters that can be altered to determine the particle size distribution of the obtained powder are usually the same. Such parameters include the ball-to-powder ratio (BPR), the diameter of the milling balls, the materials, and the shape of the milling media, as well as milling speeds, milling environments, the size of the milling media, the milling atmosphere, and the temperature [32,33,34]. The main components of the mill are the milling chamber and the grinding media (which can be milling balls or a vibratory disc, for example). Those components can also be optimized to obtain the desired outcome. The parameters to be considered when selecting a milling chamber are its material, volume, and filling degree, whereas the milling media should be made of the same material as the chambers to prevent the more rigid material from milling the softer one [26].
The milling conditions and the preparation method impact the properties of the obtained CuP, such as their average diameter or degree of crystallinity. Furthermore, treating the Cu materials before and after the milling also impacts the morphology and size of the resulting CuP or CuC. However, these steps are only sometimes discussed or performed by authors synthesizing Cu materials through mechanical milling. Figure 3 summarizes the CuP and CuC generation route, starting with pretreatment, then mechanical milling and its individual approach (top-down or bottom-up), post-treatment, and finally, characterization.

3. Pretreatment of the Starting Materials

The starting materials for the generation of CuP or CuC might require pretreatment before being subjected to the mechanical mill, according to the requirements of the equipment. Pretreatment methods of the starting materials can improve the efficiency of mechanical milling when synthesizing CuC or CuP [35,36,37].
Depending on the dimensions of the precursors and the requirements needed to conduct the milling conditions, the pretreatment can consist of polishing, grinding, sieving, or purification processes. Polishing and purification are usually performed by ultrasonication or an abrasive material (such as SiC) [38], and further immersing the Cu precursors into a solvent to remove impurities on their surface (NaOH, acetone, and toluene have been used for that purpose) [39,40,41]. Grinding is attained to improve the adhesion between Cu and other precursors to form an alloy, followed by treatment with an acid. The Cu precursors can also be pretreated by sieving, in case some mechanical milling equipment works better with specific sizes of starting materials.
Mechanical milling has also been reported as a pretreatment method to further develop a composite with a different technique or to subject the obtained Cu powders to a second milling with different conditions than the former [42,43].
Process control agents (PCA) are added to the Cu starting powder. The role of PCA is to prevent the adhesion of the precursors or the resulting powders to the milling chamber and media, the agglomeration or coarsening of the particles during the milling process, and excessive cold welding [22,40,44,45].
While authors have mostly reported using organic PCA, namely stearic acid, ethanol, toluene, methanol, and dichlorobenzene [40,41,46], inorganic PCA such as NaCl, NaOH, or NaSO4 can also effectively act as agglomeration inhibitors [12,47]. Note that the potentially corrosive effects on the milling media must be considered when choosing the PCA for the synthesis [44].

4. Synthesis of CuP and CuC Using Mechanical Milling

The following sections will discuss the top-down and bottom-up approaches to fabricating CuP and CuC.

4.1. Top-Down Approach Using Mechanical Milling

The top-down approach produces CuP and CuC by progressively breaking down and diminishing the Cu precursor dimensions to a micro- or nano-metric scale. The Cu- based particles synthesized through top-down approaches using mechanical milling are usually produced from Cu powders of high purity as the starting material [31,48,49,50]. However, other precursors, such as Cu flakes, grains, sheets, or wires, have also been reported [51,52,53].
Yadav et al. reported the synthesis and characterization of copper nanoparticles (CuNPs) from Cu powder (initial size of 200 nm, 99% purity) by wet milling [34]. The system consisted of a planetary mill, toluene as the medium, and combining two balls of different sizes (3 and 5 mm). The effects of the milling time on the CuNPs’ resulting size distribution were also tested. The particle size decreased as the milling time increased, obtaining a final crystallite size of 21 nm upon 40 h of milling.
Reduction of Cu powder to CuNPs was performed at cryogenic temperature by ball milling. A cryomill operated at 150 K under an Ar atmosphere was used for the developed system. Upon 3 h of milling, the as-synthesized CuNPs were dispersed in methanol and sonicated [33].
Amal et al. synthesized CuO nanoparticles from Cu powder (2–5 µm) using dry high-energy ball milling [54]. Different milling times, ranging from 4 to 16 h, were used to determine their effects on the final size of the nanoparticles.
The effects of HEBM on the particle size, morphology, and hardness of spherical CuP were evaluated by Ansell et al., in terms of milling time and BPR [55]. The processing of Cu powder without significantly compromising its physicochemical integrity is essential in additive manufacturing applications. HEBM was confirmed to be an excellent tool for Cu powder processing, without affecting the spheroidicity. The optimal BPR and milling times were determined to prevent the formation of Cu flakes, which are undesirable for additive manufacturing applications.
Bor et al. studied the morphological evolution of Cu precursors under planetary ball milling, by varying parameters such as the rotation speeds, ball diameters, and BPR [35]. They concluded that the milling conditions allowed them to control the synthesized Cu powders’ final particle size and morphology. The conclusions were supported by a ball motion simulation, where the milling parameters, namely force, energy, ball sizes, and rotation speeds, were tested.
Most articles describe that generating CuNPs through mechanical milling requires a prolonged time to reduce the Cu starting powder to nanometric size. However, by adjusting the milling conditions and reducing the milling times, it is also possible to obtain copper microparticles (CuMPs). Although CuNPs are often obtained with spherical morphology and monodispersity, CuMPs might present diverse morphologies, including sheets, flakes, or agglomerates.
Cryomilling has also been employed by Han et al. to develop CuNPs reinforced with graphene (GNPs), in which the ball milling process promoted the formation of two sizes of graphene in the composite, thus enhancing the strength and fracture elongation of the Cu-graphene system [56].
Cu-based powders were developed as protective coating materials using HEBM [45]. The Cu powder precursor (99% of purity) ranged from 5 to 20 mm in diameter and was subsequently reduced to particles within a micrometric range (average size of 200 µm). The obtained CuMPs were also sieved to obtain even finer particles.
Finally, the CuMPs were alloyed with Zn and Ni after heat treatment to obtain a nanocomposite that could exhibit synergic effects, inhibiting biofilms formed by pathogens. Cu-Zn composites and their stability were also studied in the work of Gamboa et al., which was processed using low-energy ball milling. Low-energy conditions were chosen in this study to promote the formation of a metastable phase. Pure Cu and Zn were used as precursors (99%), without previous treatment. The obtained Cu-Zn composite was compared with a Cu-Zn beta-phase alloy milled afterward [57].
A Cu-Ni-Fe-based alloy was prepared as an alternative for carbon-consuming anodes. The composite was prepared by HEBM, starting from pure Cu, Ni, and Fe (each of 99% purity). The ball milling was performed under an Ar atmosphere and stearic acid was added to the mixture to prevent excessive cold welding and the precursors’ sticking on the milling tools [58].
The reduction of Cu powder (7 µm in size) for the development of a CuW composite was reported by Dong et al., which was prepared by ball milling [59]. A drum ball mill operating at 300 rpm for 5 h was used, promoting the reduction of the Cu powder and the subsequent adhesion of W onto the surface of the CuNPs. Lu et al. also proposed a Cu-W alloy to enhance the mechanical and electrical properties compared to native Cu particles [60]. The Cu-W system was prepared using high-energy ball milling, obtaining a composite with high stability and increased conductivity, elongation, tensile strength, and stability.
A spinel phase of the copper-ferrite composite was developed by Marinca et al. by combining heat treatment and ball milling. Tenorite (CuO) and hematite (α-Fe2O3) were used as precursors [52]. Further, a single Cu spinel phase was obtained using heat treatment in ranges from 600 to 1000 °C. The synthesized CuFe2O4 was milled a second time to refine the composite’s crystallite size and to induce superparamagnetic behavior. A similar composite consisting of a Cu-Ni alloy was synthesized by Bettge et al., by ball milling, where the Cu-Ni particles exhibited a superparamagnetic nature, for a potential application in magnetic hyperthermia [61].
Salvo et al. reported a reinforcement of Cu with graphene. However, mechanical milling, hot pressing, and sintering were used instead of low-temperature milling and extrusion to disperse the graphene nanosheets on the Cu matrix. The matrix’s electrical conductivity, mechanical, and physical properties were reported and improved in comparison to pristine GNPs or Cu [46]. It was also reported that, as the content of graphene increased, the mechanical properties of the composite were reduced due to agglomerations of the former in the Cu matrix.
The incorporation of Al in a Cu matrix was also described by Saberi et al. using ball milling and PEG as a space holder. Notably, the Cu-Al matrix exhibited a porous nature, for its potential application as a filter, heat exchanger, or as a fuel cell. The Cu-Al composite presented a porosity percentage of 88% and microporosity, with the pore sizes ranging from 50 to 200 µm [62]. Abu-Okail et al. also proposed a Cu-Al composite with apparent porosity; however, graphene nanoplatelets were added to the mixture to enhance the mechanical properties of the nanocomposite [63].
Zirconia powder was used as a precursor to develop a Cu-ZrO2 composite produced by high-energy ball milling. Upon deposition of ZrO2, the hardness increased up to three times compared to the Cu precursor. It was concluded that the refinement of the powders by ball milling also contributed to the strengthening of the nanocomposite [64].
On the other hand, yttrium nanoparticles (in the form of Y2O3) were incorporated into a Cu matrix using multi-step ball milling. The nanocomposite exhibited a microhardness three times higher than that of free Cu, while also increasing its compressive strength, ductility, and conductivity [65].
The reinforcement of Cu materials has also been reported using Ag and reduced graphene oxides to develop a Cu-Ag-GNPs composite through the combination of spark plasma sintering and ball milling. Adding such materials to the Cu matrix significantly increased the relevant parameters, such as hardness, bending strength, and fracture surface, of the samples [66].
Spark plasma sintering has also been employed in conjunction with mechanical milling to synthesize a Ti-C-Cu composite. The properties of the system in terms of compressive strength, hardness, deformation, and conductivity were improved compared to pure Cu powder [67]. The effect of the carbon source on the structure of the final composite was evaluated, with nanodiamonds and carbon black promoting the faster reduction of the precursors during ball milling, in comparison to graphite.
Güler et al. proposed Ag and Al2O3 to reinforce Cu powder. Electroless silver plating and hot pressing were used for the deposition of Ag in the Cu-Al2O3 matrix, whereas mechanical milling was performed to produce the powder consisting of the Cu-Al2O3 composite [38]. In another study, Güler et al. also investigated the effects of the milling time on the coating thickness and composite morphology of Ag-Cu. Optimal bonding between Ag and Cu was attained upon 120 min of milling, obtaining a silver coating of 2 µm [47].
Although Cu powders of high purity are the precursor of choice for the synthesis of CuP and CuC using mechanical milling, the use of Cu starting materials in the form of waste has also been reported. Waste Cu chips have been processed using high-energy ball milling to obtain CuNPs, as reported by Ramesh et al. [23]. A milling time of 75 h was carried out in a solid state and inert atmosphere to prevent the oxidation of the product. Aldham et al. developed a synthesis of CuP using waste Cu grains as the precursor, using a vibratory disc mill as the means of pretreatment of the Cu grains, and further milled with a planetary ball mill to obtain CuMPs [50].
Nasimul et al. evaluated the effects of milling time on the obtained CuMPs using a waste Cu pellet and a planetary ball mill. The Cu pellets were milled using toluene as the process control agent, where the particle size decreased as the milling time increased. However, after 20 h of milling, the obtained Cu powder started agglomerating to form larger Cu microparticles [67].
A summary of relevant data concerning the synthesis and characterization of Cu-based particles, namely CuP and CuC, using a top-down approach through mechanical milling is presented in detail in Table 1.

4.2. Bottom-Up Approach Using Mechanical Milling

The bottom-up approach employs mechanical milling to achieve an assembly or self-assembly starting from a molecular or atomic precursor. Due to its low cost, CuSO4 is a common precursor in the bottom-up approach to obtain CuP or CuC. However, using Cu (II) salts such as CuCl2, Cu(NO3)2, CuS, or Cu(COO)2 in mechanical milling has also been reported. The size distribution and anti-microbial activity of the obtained Cu-based particles after ball milling were found to depend on the salt precursor.
A catalyst consisting of a mesoporous polymer embedded with CuNPs was proposed as a novel system for solvent-free reactions by Wang et al. [13]. The polymer-CuNPs composite was prepared in the solid state by ball milling, using Cu(NO3)2 as the Cu precursor. After milling for 12 h at 298 K, and upon pyrolization in a nitrogen atmosphere at 600 K, the proposed system was obtained.
A method for developing disc-shaped Cu flakes was reported by Jo et al. The green synthesis involved synthesizing CuNPs through a solvothermal method [36]. The obtained CuNPs were subsequently transformed into Cu flakes using vibratory milling. The resulting Cu flakes were sieved, washed with toluene, and separated with centrifugation.
CuO powders synthesized from two different precursors, namely CuSO4 and CuCl2, were reported by Javadhesari et al. [12]. The CuO nanoparticles were obtained by HEBM using NaOH and NaCl as a medium. The antibacterial activity of the CuO nanoparticles was evaluated, where the CuO NPs obtained from CuCl2 exhibited more antibacterial activity than its CuSO4 counterpart [12].
Mechanical milling has also been applied to reduce Cu sulfides, namely CuS and Cu2S, using Fe and Mg as reducing agents.
Calka et al. obtained elemental CuMPs using electric discharge-assisted mechanical milling, which attained the reduction of the Cu2S precursor after only 5 min of processing [68]. Furthermore, the mechanochemical reduction of CuS and Cu2S was investigated by Balaz et al. [26], who demonstrated the complete reduction of Cu2S to elemental Cu using a planetary mill after 360 min.
However, under the same conditions, a large amount of unreacted Fe was identified in the case of the CuS precursor. Reducing CuS to elemental Cu required longer milling times, leading to sulfide byproducts.
A CuNPs-carbon nanotube (CNT) composite was synthesized and characterized by Singhal et al. The composite was fabricated to reinforce and improve the mechanical properties of the Cu matrix [43]. A CuSO4 solution was added to a CNT suspension and further mixed using HEBM.
TiO2 nano-powders were deposited on a Cu matrix using HEBM, while also studying the effects of milling time, BPR, and the amount of Cu on the structure morphology and its anti-microbial activity against E. coli and S. aureus [69].
The synthesis and characterization of Cu-based particles using bottom-up approaches through mechanical milling are summarized in Table 2.

5. Post-Treatment of the Obtained CuP and CuC

Following the mechanical milling, CuP and CuC materials can undergo further treatment to achieve a desired size distribution, remove impurities from unreacted precursors, or provide the obtained Cu powder with additional properties by incorporating another metal or material to generate an alloy or composite. Among the protocols described for treating synthesized CuP or CuC, washing with an organic solvent followed by centrifugation is extensively used, primarily to re-disperse the synthesized Cu materials or to remove the excess solvents and process control agents used in wet milling [34,37,42]. Sieving is performed when a determined size distribution or ranges are needed, as the resulting powder might be a mixture of larger and finer particles. When producing a CuP, the metal precursors are refined using mechanical milling and further consolidated and homogenized using hot extrusion methods [56].
Hot extrusion processes are conducted in a vacuum to prevent matrix oxidation while applying temperatures over 900 °C and pressures in the MPa range of 100 to 1500 MPa [56,71]. Hot extrusion can also improve the strength, density, and hardness of the Cu matrix when developing a composite, while also decreasing its coefficient of friction and wear rates [56,71,72,73].
The post-treatment of a CuC can also be performed through spark plasma sintering processes or electroless Ag plating [21,43,51,59]. The composition of the CuC, as well as the coating thickness and distribution of the deposited metal over the Cu matrix, can be controlled with these techniques. Further, the sintered parts of the alloy are evaluated in terms of their mechanical strength using compression machines in quasistatic conditions [60].

6. Characterization Techniques of the Synthesized CuP and CuC

Determining the oxidation state of the generated CuC or CuP, their morphology, size distribution, and their optical, mechanical, and biological properties are of utmost interest in most analyzed articles.

6.1. X-ray Powder Diffraction (XRPD)

XRPD is a non-destructive technique used to ascertain the crystal structure of the synthesized Cu powders. Furthermore, relevant information such as crystallite size, lattice parameters, oxidation states, and strains can be determined.
The diffraction peaks of the obtained Cu-based materials allow for the indexation and, therefore, the identification of metallic Cu (Cu0) [23] or common Cu oxides in the form of CuO and Cu2O, which correspond to the Cu2+ and Cu+ oxidation states of Cu, respectively [48,54], as well as the presence of peaks that can be attributed to impurities from the precursors or the reducing agents [12,13].
Metallic Cu exhibits characteristic diffraction peaks at (111), (200), and (220) planes, which can be indexed to the face-centered cubic structure of Cu [37,42,69,72].
The most prominent diffraction peaks of CuO composites were observed at (002), (−111), (111), and (200), which correspond to the characteristic crystal structure of CuO in the monoclinic space group [2,12,74].
Cu2O particles show pronounced diffraction peaks at (110), (111), (200), (220), and (311) spaces, thus confirming the formation of a single cubic phase [54]. CuSO4, a common precursor in synthesizing Cu-based particles, presents a triclinic structure in its hydrated state.

6.2. Scanning Electron Microscopy (SEM) and Energy-Dispersive Spectroscopy (EDS)

SEM is used to analyze the surface morphology of synthesized Cu materials. EDS is an analytical technique that provides the elemental composition and chemical characterization of the Cu-based composites. SEM analyses allowed researchers to demonstrate that the milling parameters, such as BPR, milling time, or rotation speed, had an impact on the morphology of the obtained CuP or CuC [37,46,69,75]. The most prominent structures were agglomerates or spheres. However, a second milling and further processing of the powders promoted the formation of flake-like particles [36,42,47]. EDS and elemental mapping analyses indicated the presence of Cu and O in the Cu-based particles. In the case of composites, EDS provided information about the elemental distribution and the dispersion of the added materials in the Cu matrix, with Al, C, GNPs, CNTs, Ti, Zr, and Y being among the most used [50,63,65,67,69].

6.3. Transmission Electron Microscopy (TEM) and Selected Area Electron Diffraction (SAED)

Characterization using TEM provides information on the size distribution, morphology, and average diameter of the synthesized Cu materials. It also allowed ascertaining the interface between Cu and the materials used to generate a Cu composite. The size distribution obtained from TEM can also be compared to those obtained from the crystallite sizes determined using XRPD [33,35,54]. As previously reported, the as-synthesized Cu-based particles are usually in the nanometric range. However, adjusting the milling parameters allows for obtaining micrometric materials.
If the analysis is carried out using an HR-TEM, the lattice fringes of the Cu material can be detected, thus obtaining information regarding its crystallographic structure [76].
Moreover, SAED is a technique used alongside TEM or HR-TEM to evaluate the crystallinity of the CuP or CuC, the phase composition, and regions of differing phases, by analyzing the diffraction pattern generated by the electron beam interacting with the material, as reported in previous studies [73,77]. This technique is complementary to the XRPD characterization, which allowed, for example, to confirm the presence of Cu-Ti or Cu-Al phases in a composite [62,76].

6.4. UV-Visible Spectrophotometry (UV-Vis)

UV-visible spectra can be used to study the presence of Cu’s characteristic surface plasmon resonance in its nanometric state. Metallic CuNPs usually display an absorption peak at 575 nm [53]. CuO and Cu2O nanoparticles, however, display a solid blue shift in their absorption peak compared to that of CuNPs, ranging between 290 and 360 nm [15]. UV-visible spectra also provide information regarding the deposition of NPs on a Cu matrix. For example, the association of Ag nanoparticles onto the surface of a CuP can be confirmed by analyzing the presence of their characteristic plasmon band, usually found at 420–450 nm [42,47].

7. Evaluation of the Properties and Performance of the Obtained CuP and CuC

7.1. Mechanical Properties

Cu-based particles can be reinforced with a volume fraction of another metal using mechanical milling to modify or improve the mechanical properties, such as tensile strength, hardness, dislocation density, toughness, and fractography. CuC generated through mechanical milling displayed significant enhancements compared to the Cu matrix.
Cu powder reinforced with TiO2, GNPs, Al2O3, or graphene presented changes in its mechanical properties, with microhardness, elongation, toughness, tensile strength, and ductile fracture presenting the most noticeable improvements, up to 10 times in some cases [65,66,67,75]. These properties were measured using Brinell hardness testing machines, pliers, tensile and torsion testing machines, micro-indentation testing, and Oliver–Pharr methods [28,46,55,62,67,78].

7.2. Anti-Microbial Activity Assays

Due to increasing microbial resistance against a broad spectrum of anti-microbial agents, the study of CuP and CuC and their anti-microbial properties has become of great interest as an alternative to combat these resistant microorganisms. The anti-microbial activity of metallic Cu, Cu oxides, and CuC generated through mechanical milling has been investigated against Gram-positive and Gram-negative bacteria.
CuP and CuC generated through mechanical milling approaches exhibited high antibacterial activities. Smaller particles presented higher anti-microbial activities, depending on their morphology and size distribution. Even the Cu precursor had an impact on the anti-microbial effects. As a starting material, the CuO particles obtained from CuCl2 displayed higher anti-microbial efficacy than its CuSO4 counterpart [12]. Furthermore, metallic Cu particles generated using mechanical milling have exhibited microbial reduction up to 99% against both E. coli and C. albicans [48,69]. Notably, CuS microparticles generated through mechanochemical approaches were effective in both Gram-positive and Gram-negative bacteria [79,80]. CuC also showed anti-microbial properties, where Cu-GNPs and Cu-Ti composites were shown to be biologically active against E. coli and S. aureus [46,67].

8. Conclusions and Final Remarks

Mechanical milling allows for versatility and novelty in developing Cu-based particles. The obtained materials’ average size, type, and morphology can be controlled by adjusting the milling conditions, such as BPR, rotation speeds, and ball diameter. While Cu has interesting properties on its own, it is worth noting that incorporating elements such as graphene, carbon-based materials, Ti, Ag, or Al enhances the physicochemical properties of the Cu powder, where a synergic effect might occur. Mechanical milling has its shortcomings. Contamination can be generated during the mechanochemical processing, often from the abrasion of the milling media as well as from the atmosphere during the milling. Additionally, specialized equipment is needed to perform the reduction of the Cu precursors.
However, as the amount of energy is usually lower in comparison to related techniques to reach nanocrystalline materials, mechanical milling is undoubtedly a promising approach to develop a scalable synthesis of Cu-based particles, with potential applications in relevant fields, such as electronics, water remediation, sensors, pharmaceutical sciences, packaging, anti-microbial materials, and agriculture.

Author Contributions

Conceptualization, S.S.S. and N.S.; writing—original draft preparation, S.S.S. and N.S.; writing—review and editing, S.S.S. and N.S.; illustrations, S.S.S. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by Facultad de Diseño, Universidad del Desarrollo, Santiago, Chile.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Din, M.I.; Rehan, R. Synthesis, Characterization, and Applications of Copper Nanoparticles. Anal. Lett. 2017, 50, 50–62. [Google Scholar] [CrossRef]
  2. Akintelu, S.A.; Folorunso, A.S.; Folorunso, F.A.; Oyebamiji, A.K. Green synthesis of copper oxide nanoparticles for biomedical application and environmental remediation. Heliyon 2020, 6, e04508. [Google Scholar] [CrossRef]
  3. Mohajerani, A.; Burnett, L.; Smith, J.V.; Kurmus, H.; Milas, J.; Arulrajah, A.; Horpibulsuk, S.; Abdul Kadir, A. Nanoparticles in Construction Materials and Other Applications, and Implications of Nanoparticle Use. Materials 2019, 12, 3052. [Google Scholar] [CrossRef] [Green Version]
  4. Singh, M.; Jagaran, K. Nanomedicine for COVID-19: Potential of Copper Nanoparticles. Biointerface Res. Appl. Chem. 2020, 11, 10716–10728. [Google Scholar] [CrossRef]
  5. Zuniga, J.M.; Cortes, A. The role of additive manufacturing and antimicrobial polymers in the COVID-19 pandemic. Expert Rev. Med. Devices 2020, 17, 477–481. [Google Scholar] [CrossRef]
  6. Govind, V.; Bharadwaj, S.; Ganesh, M.R.S.; Vishnu, J.; Shankar, K.V.; Shankar, B.; Rajesh, R. Antiviral properties of copper and its alloys to inactivate COVID-19 virus: A review. Biometals 2021, 34, 1217–1235. [Google Scholar] [CrossRef]
  7. Achimovičová, M.; Dutková, E.; Tóthová, E.; Bujňáková, Z.; Briančin, J.; Kitazono, S. Structural and optical properties of nanostructured copper sulfide semiconductor synthesized in an industrial mill. Front. Chem. Sci. Eng. 2019, 13, 164–170. [Google Scholar] [CrossRef]
  8. Silva, N.; Arellano, E.; Castro, C.; Yutronic, N.; Lang, E.; Chornik, B.; Jara, P. Cyclodextrin inclusion compound crystals for growth of Cu–Au core–shell nanoparticles. J. Incl. Phenom. Macrocycl. Chem. 2015, 82, 497–504. [Google Scholar] [CrossRef]
  9. Khodashenas, B.; Ghorbani, H.R. Synthesis of copper nanoparticles: An overview of the various methods. Korean J. Chem. Eng. 2014, 31, 1105–1109. [Google Scholar] [CrossRef]
  10. Hassan, S.E.-D.; Salem, S.S.; Fouda, A.; Awad, M.A.; El-Gamal, M.S.; Abdo, A.M. New approach for antimicrobial activity and bio-control of various pathogens by biosynthesized copper nanoparticles using endophytic actinomycetes. J. Radiat. Res. Appl. Sci. 2018, 11, 262–270. [Google Scholar] [CrossRef] [Green Version]
  11. El-Saadony, M.T.; El-Hack, M.E.A.; Taha, A.E.; Fouda, M.M.G.; Ajarem, J.S.; Maodaa, S.N.; Allam, A.A.; Elshaer, N. Ecofriendly Synthesis and Insecticidal Application of Copper Nanoparticles against the Storage Pest Tribolium castaneum. Nanomaterials 2020, 10, 587. [Google Scholar] [CrossRef] [Green Version]
  12. Javadhesari, S.M.; Alipour, S.; Mohammadnejad, S.; Akbarpour, M.R. Antibacterial activity of ultra-small copper oxide (II) nanoparticles synthesized by mechanochemical processing against S. aureus and E. coli. Mater. Sci. Eng. C-Mater. 2019, 105, 110011. [Google Scholar] [CrossRef]
  13. Wang, K.; Yang, L.; Zhao, W.; Cao, L.; Sun, Z.; Zhang, F. A facile synthesis of copper nanoparticles supported on an ordered mesoporous polymer as an efficient and stable catalyst for solvent-free sonogashira coupling Reactions. Green Chem. 2017, 19, 1949–1957. [Google Scholar] [CrossRef]
  14. Kamal, T.; Ahmad, I.; Khan, S.B.; Ul-Islam, M.; Asiri, A.M. Microwave Assisted Synthesis and Carboxymethyl Cellulose Stabilized Copper Nanoparticles on Bacterial Cellulose Nanofibers Support for Pollutants Degradation. J. Polym. Environ. 2019, 27, 2867–2877. [Google Scholar] [CrossRef]
  15. Waris, A.; Din, M.; Ali, A.; Ali, M.; Afridi, S.; Baset, A.; Khan, A.U. A comprehensive review of green synthesis of copper oxide nanoparticles and their diverse biomedical applications. Inorg. Chem. Commun. 2021, 123, 108369. [Google Scholar] [CrossRef]
  16. Crisan, M.C.; Teodora, M.; Lucian, M. Copper Nanoparticles: Synthesis and Characterization, Physiology, Toxicity and Antimicrobial Applications. Appl. Sci. 2022, 12, 141. [Google Scholar] [CrossRef]
  17. Priyadarshini, B.G. Mechanical Milling of Copper Oxide Nanoparticles. In Proceedings of the First International Conference on Combinatorial and Optimization, ICCAP 2021, Chennai, India, 7–8 December 2021. [Google Scholar] [CrossRef]
  18. El-Eskandarany, M.S.; Al-Hazza, A.; Al-Hajji, L.A.; Ali, N.; Al-Duweesh, A.A.; Banyan, M.; Al-Ajmi, F. Mechanical Milling: A Superior Nanotechnological Tool for Fabrication of Nanocrystalline and Nanocomposite Materials. Nanomaterials 2021, 11, 2484. [Google Scholar] [CrossRef]
  19. Yadav, T.P.; Yadav, R.M.; Singh, D. Mechanical Milling: A Top Down Approach for the Synthesis of Nanomaterials and Nanocomposites. Nanosci. Nanotechnol. 2012, 2, 22–48. [Google Scholar] [CrossRef] [Green Version]
  20. Balázs, B.Z.; Geier, N.; Takács, M.; Davim, J.P. A review on micro-milling: Recent advances and future trends. Int. J. Adv. Manuf. Technol. 2021, 112, 655–684. [Google Scholar] [CrossRef]
  21. Dudina, D.V.; Bokhonov, B.B. Materials Development Using High-Energy Ball Milling: A Review Dedicated to the Memory of M.A. Korchagin. J. Compos. Sci. 2022, 6, 188. [Google Scholar] [CrossRef]
  22. Chen, Y. Chapter 3 Solid-State Formation of Carbon Nanotubes; Elsevier Ltd.: Amsterdam, The Netherlands, 2006. [Google Scholar] [CrossRef]
  23. Wu, Z.; Liang, Y.; Fu, E.; Du, J.; Wang, P.; Fan, Y.; Zhao, Y. Effect of Ball Milling Parameters on the Refinement of Tungsten Powder. Metals 2018, 8, 281. [Google Scholar] [CrossRef] [Green Version]
  24. Ramesh, S.; Vetrivel, S.; Suresh, P.; Kaviarasan, V. Characterization techniques for nano particles: A practical top down approach to synthesize copper nano particles from copper chips and determination of its effect on planes. Mater. Today Proc. 2020, 33, 2626–2630. [Google Scholar] [CrossRef]
  25. Menapace, C.; Leonardi, M.; Perricone, G.; Bortolotti, M.; Straffelini, G.; Gialanella, S. Pin-on-disc study of brake friction materials with ball-milled nanostructured components. Mater. Des. 2017, 115, 287–298. [Google Scholar] [CrossRef]
  26. Baláž, M.; Tešinský, M.; Marquardt, J.; Škrobian, M.; Daneu, N.; Rajňák, M.; Baláž, P. Synthesis of copper nanoparticles from refractory sulfides using a semi-industrial mechanochemical approach. Adv. Powder Technol. 2020, 31, 782–791. [Google Scholar] [CrossRef]
  27. Yadav, S.K. Synthesis and Characterization of Copper Nanoparticles, Using Combination of Two Different Sizes of Balls in Wet Ball Milling. Int. J. Emerg. Trends Sci. Technol. 2016, 3, 3795–3799. [Google Scholar] [CrossRef]
  28. Shuai, C.; He, C.; Peng, S.; Qi, F.; Wang, G.; Min, A.; Yang, W.; Wang, W. Mechanical Alloying of Immiscible Metallic Systems: Process, Microstructure, and Mechanism. Adv. Eng. Mater. 2021, 23, 2001098. [Google Scholar] [CrossRef]
  29. Vaidya, M.; Muralikrishna, G.M.; Murty, B.S. High-entropy alloys by mechanical alloying: A review. J. Mater. Res. 2019, 34, 664–686. [Google Scholar] [CrossRef]
  30. Taha, M.A.; Youness, R.A.; Zawrah, M. Review on nanocomposites fabricated by mechanical alloying. Int. J. Miner. Met. Mater. 2019, 26, 1047–1058. [Google Scholar] [CrossRef]
  31. Bonomi, S.; Armenise, V.; Accorsi, G.; Colella, S.; Rizzo, A.; Fracassi, F.; Malavasi, L.; Listorti, A. The Effect of Extended Ball-Milling upon Three-Dimensional and Two-Dimensional Perovskite Crystals Properties. Appl. Sci. 2020, 10, 4775. [Google Scholar] [CrossRef]
  32. Baláž, M. Environmental Mechanochemistry; Springer International Publishing: Berlin/Heidelberg, Germany, 2021. [Google Scholar] [CrossRef]
  33. Mussapyrova, L.; Nadirov, R.; Baláž, P.; Rajňák, M.; Bureš, R.; Baláž, M. Selective room-temperature leaching of copper from mechanically activated copper smelter slag. J. Mater. Res. Technol. 2021, 12, 2011–2025. [Google Scholar] [CrossRef]
  34. Barai, K.; Tiwary, C.; Chattopadhyay, P.; Chattopadhyay, K. Synthesis of free standing nanocrystalline Cu by ball milling at cryogenic temperature. Mater. Sci. Eng. A 2012, 558, 52–58. [Google Scholar] [CrossRef]
  35. Joy, J.; Krishnamoorthy, A.; Tanna, A.; Kamathe, V.; Nagar, R.; Srinivasan, S. Recent Developments on the Synthesis of Nanocomposite Materials via Ball Milling Approach for Energy Storage Applications. Appl. Sci. 2022, 12, 9312. [Google Scholar] [CrossRef]
  36. Bor, A.; Jargalsaikhan, B.; Uranchimeg, K.; Lee, J.; Choi, H. Particle morphology control of metal powder with various experimental conditions using ball milling. Powder Technol. 2021, 394, 181–190. [Google Scholar] [CrossRef]
  37. Jo, Y.; Park, H.J.; Jeong, S. Synthesis of disc-shaped copper flakes by mechanical milling: Green laser-sintered, highly conductive printed Cu features. J. Alloys Compd. 2021, 886, 161093. [Google Scholar] [CrossRef]
  38. Musza, K.; Szabados, M.; Ádám, A.A.; Kónya, Z.; Kukovecz, Á.; Sipos, P.; Pálinkó, I. Ball Milling of Copper Powder Under Dry and Surfactant-Assisted Conditions—On the Way Towards Cu/Cu2O Nanocatalyst. J. Nanosci. Nanotechnol. 2019, 19, 389–394. [Google Scholar] [CrossRef] [PubMed]
  39. Güler, O.; Varol, T.; Alver, Ü.; Kaya, G.; Yıldız, F. Microstructure and wear characterization of Al2O3 reinforced silver coated copper matrix composites by electroless plating and hot pressing methods. Mater. Today Commun. 2021, 27, 102205. [Google Scholar] [CrossRef]
  40. Zhou, H.; Liu, G.; Zhou, C.; Arif, M.; Sun, M.; Chen, Y.; Liu, Y. Water-assisted-mechanical activation of copper pyrometallurgical tailings for molybdenum leaching and selective removal of environmentally-hazardous elements. Sep. Purif. Technol. 2023, 310, 123088. [Google Scholar] [CrossRef]
  41. Rahmanifard, R.; Javidan, S.M.; Asadabad, M.A. Effects of Process Control Agents on Characteristics of Cu-Ta Nanocomposite during Milling and Subsequent Sintering. J. Mater. Eng. Perform. 2019, 28, 4102–4110. [Google Scholar] [CrossRef]
  42. Jia, C.; Zhu, J.; Zhang, L. An Anti-Corrosion Superhydrophobic Copper Surface Fabricated by Milling and Chemical Deposition. Coatings 2022, 12, 442. [Google Scholar] [CrossRef]
  43. Rosen, Y.; Marrach, R.; Gutkin, V.; Magdassi, S. Thin Copper Flakes for Conductive Inks Prepared by Decomposition of Copper Formate and Ultrafine Wet Milling. Adv. Mater. Technol. 2019, 4, 1800426. [Google Scholar] [CrossRef]
  44. Singhal, S.K.; Lal, M.; Sharma, I.; Mathur, R.B. Fabrication of copper matrix composites reinforced with carbon nanotubes using a combination of molecular-level-mixing and high energy ball milling. J. Compos. Mater. 2013, 47, 613–621. [Google Scholar] [CrossRef]
  45. Pattison, T.G.; Hess, A.E.; Arellano, N.; Lanzillo, N.; Nguyen, S.; Bui, H.; Rettner, C.; Truong, H.; Friz, A.; Topuria, T.; et al. Surface Initiated Polymer Thin Films for the Area Selective Deposition and Etching of Metal Oxides. ACS Nano 2020, 14, 4276–4288. [Google Scholar] [CrossRef] [PubMed]
  46. Drozda, M.; Miszczyk, A. Selection of Organic Coating Systems for Corrosion Protection of Industrial Equipment. Coatings 2022, 12, 523. [Google Scholar] [CrossRef]
  47. Salvo, C.; Mangalaraja, R.; Udayabashkar, R.; Lopez, M.; Aguilar, C. Enhanced mechanical and electrical properties of novel graphene reinforced copper matrix composites. J. Alloys Compd. 2019, 777, 309–316. [Google Scholar] [CrossRef]
  48. Güler, O.; Varol, T.; Alver, Ü.; Çanakçı, A. The effect of flake-like morphology on the coating properties of silver coated copper particles fabricated by electroless plating. J. Alloys Compd. 2019, 782, 679–688. [Google Scholar] [CrossRef]
  49. Zhang, D.-W.; Chen, C.-H.; Zhang, J.; Ren, F. Fabrication of nanosized metallic copper by electrochemical milling process. J. Mater. Sci. 2008, 43, 1492–1496. [Google Scholar] [CrossRef]
  50. Jamkhande, P.G.; Ghule, N.W.; Bamer, A.H.; Kalaskar, M.G. Metal nanoparticles synthesis: An overview on methods of preparation, advantages and disadvantages, and applications. J. Drug Deliv. Sci. Technol. 2019, 53, 101174. [Google Scholar] [CrossRef]
  51. Aldhameer, A. Synthesizing and characterizations of one-dimensional Cu-based antibiofilm surface protective coating. J. Nanopart. Res. 2020, 22, 120. [Google Scholar] [CrossRef]
  52. Park, H.J.; Jo, Y.; Lee, S.Y.; Choi, Y.; Jeong, S. One-pot synthesis of surface oxidation-suppressed multidimensional copper particles for photonically sintered, directly printed conductive features. J. Alloys Compd. 2021, 867, 159152. [Google Scholar] [CrossRef]
  53. Marinca, T.; Chicinaş, I.; Isnard, O. Synthesis, structural and magnetic characterization of nanocrystalline CuFe2O4 as obtained by a combined method reactive milling, heat treatment and ball milling. Ceram. Int. 2012, 38, 1951–1957. [Google Scholar] [CrossRef]
  54. Sayyad, R.; Ghambari, M.; Ebadzadeh, T.; Pakseresht, A.H.; Ghasali, E. Preparation of Ag/reduced graphene oxide reinforced copper matrix composites through spark plasma sintering: An investigation of microstructure and mechanical properties. Ceram. Int. 2020, 46, 13569–13579. [Google Scholar] [CrossRef]
  55. Amal, M.I.; Wibowo, J.T.; Nuraini, L.; Senopati, G.; Hasbi, M.Y.; Priyotomo, G. Antibacterial activity of copper oxide nanoparticles prepared by mechanical milling. IOP Conf. Ser. Mater. Sci. Eng. 2019, 578, 012039. [Google Scholar] [CrossRef]
  56. Ansell, T.Y.; Hanneman, T.; Gonzalez-Perez, A.; Park, C.; Nieto, A. Effect of high energy ball milling on spherical metallic powder particulates for additive manufacturing. Part. Sci. Technol. 2021, 39, 981–989. [Google Scholar] [CrossRef]
  57. Han, T.; Li, J.; Zhao, N.; He, C. Microstructure and properties of copper coated graphene nanoplates reinforced Al matrix composites developed by low temperature ball milling. Carbon 2020, 159, 311–323. [Google Scholar] [CrossRef]
  58. Andrade-Gamboa, J.; Gennari, F.; Larochette, P.A.; Neyertz, C.; Ahlers, M.; Pelegrina, J. Stability of Cu–Zn phases under low energy ball milling. Mater. Sci. Eng. A 2007, 447, 324–331. [Google Scholar] [CrossRef]
  59. Helle, S.; Pedron, M.; Assouli, B.; Davis, B.; Guay, D.; Roué, L. Structure and high-temperature oxidation behaviour of Cu–Ni–Fe alloys prepared by high-energy ball milling for application as inert anodes in aluminium electrolysis. Corros. Sci. 2010, 52, 3348–3355. [Google Scholar] [CrossRef]
  60. Dong, L.; Li, L.; Li, X.; Zhang, W.; Fu, Y.; Elmarakbi, A.; Zhang, Y. Enhancing mechanisms of arc-erosion resistance for copper tungsten electrical contact using reduced graphene oxides in situ modified by copper nanoparticles. Int. J. Refract. Met. Hard Mater. 2022, 108, 105934. [Google Scholar] [CrossRef]
  61. Lu, T.; Chen, C.; Li, P.; Zhang, C.; Han, W.; Zhou, Y.; Suryanarayana, C.; Guo, Z. Enhanced mechanical and electrical properties of in situ synthesized nano-tungsten dispersion-strengthened copper alloy. Mater. Sci. Eng. A 2021, 799, 140161. [Google Scholar] [CrossRef]
  62. Bettge, M.; Chatterjee, J.; Haik, Y. Physically synthesized Ni-Cu nanoparticles for magnetic hyperthermia. Biomagn. Res. Technol. 2004, 2, 1. [Google Scholar] [CrossRef] [Green Version]
  63. Saberi, Y.; Oveisi, H. Development of novel cellular copper–aluminum composite materials: The advantage of powder metallurgy and mechanical milling approach for lighter heat exchanger. Mater. Chem. Phys. 2022, 279, 125742. [Google Scholar] [CrossRef]
  64. Abu-Okail, M.; Shewakh, W.; Brisha, A.M.; Abdelraouf, Y.A.; Abu-Oqail, A. Effect of GNPs content at various compaction pressures and sintering temperatures on the mechanical and electrical properties of hybrid Cu/Al2O3/xGNPs nanocomposites synthesized by high energy ball milling. Ceram. Int. 2020, 46, 18037–18045. [Google Scholar] [CrossRef]
  65. Abd-Elwahed, M.; Wagih, A.; Najjar, I. Correlation between micro/nano-structure, mechanical and tribological properties of copper-zirconia nanocomposites. Ceram. Int. 2020, 46, 56–65. [Google Scholar] [CrossRef]
  66. Huang, F.; Wang, H.; Yang, B.; Liao, T.; Wang, Z. Uniformly dispersed Y2O3 nanoparticles in nanocrystalline copper matrix via multi-step ball milling and reduction process. Mater. Lett. 2019, 242, 119–122. [Google Scholar] [CrossRef]
  67. Tong, W.; Fang, D.; Bao, C.; Tan, S.; Liu, Y.; Li, F.; You, X.; Tao, J.; Bao, R.; Li, C.; et al. Enhancing mechanical properties of copper matrix composite by adding SiO2 quantum dots reinforcement. Vacuum 2022, 195, 110682. [Google Scholar] [CrossRef]
  68. Alam, S.N.; Singh, H. Development of copper-based metal matrix composites: An analysis by SEM, EDS and XRD. Microsc. Anal. 2014, 28, S8–S13. Available online: https://www.researchgate.net/publication/271707140_metal_matrix_COMPOSITES_S8_Development_of_copper-based_metal_matrix_composites_An_analysis_by_SEM_EDS_and_XRD (accessed on 5 April 2023).
  69. Calka, A.; Wexler, D.; Monaghan, B.; Mosbah, A.; Balaz, P. Rapid reduction of copper sulfide (Cu2S) with elemental Fe and Mg using electrical discharge assisted mechanical milling (EDAMM). J. Alloys Compd. 2009, 486, 492–496. [Google Scholar] [CrossRef]
  70. Wang, M.; Zhao, Q.; Yang, H.; Shi, D.; Qian, J. Photocatalytic antibacterial properties of copper doped TiO2 prepared by high-energy ball milling. Ceram. Int. 2020, 46, 16716–16724. [Google Scholar] [CrossRef]
  71. Kalajahi, S.T.; Rasekh, B.; Yazdian, F.; Neshati, J.; Taghavi, L. Green mitigation of microbial corrosion by copper nanoparticles doped carbon quantum dots nanohybrid. Environ. Sci. Pollut. Res. 2020, 27, 40537–40551. [Google Scholar] [CrossRef]
  72. Bahador, A.; Umeda, J.; Hamzah, E.; Yusof, F.; Li, X.; Kondoh, K. Synergistic strengthening mechanisms of copper matrix composites with TiO2 nanoparticles. Mater. Sci. Eng. A 2020, 772, 138797. [Google Scholar] [CrossRef]
  73. Ďurišinová, K.; Ďurišin, J.; Orolínová, M.; Ďurišin, M.; Szabó, J. Effect of mechanical milling on nanocrystalline grain stability and properties of Cu–Al2O3 composite prepared by thermo-chemical technique and hot extrusion. J. Alloys Compd. 2015, 618, 204–209. [Google Scholar] [CrossRef]
  74. Majzoobi, G.; Jafari, S.; Rahmani, K. A study on damage evolution in Cu-TiO2 composite fabricated using powder metallurgy followed by hot extrusion. Mater. Chem. Phys. 2022, 290, 126140. [Google Scholar] [CrossRef]
  75. Chesnokov, A.E.; Smirnov, A.V.; Batraev, I.S.; Vidyuk, T.M. Detonation Spraying of Copper Pretreated with High-Energy Impacts. J. Appl. Mech. Technol. Phys. 2020, 61, 1042–1047. [Google Scholar] [CrossRef]
  76. Sadoun, A.M.; Najjar, I.M.R.; Abd-Elwahed, M.S.; Meselhy, A. Experimental study on properties of Al-Al2O3 nanocomposite hybridized by graphene nanosheets. J. Mater. Res. Technol. 2020, 9, 14708–14717. [Google Scholar] [CrossRef]
  77. Oanh, N.T.H.; Viet, N.H.; Kim, J.-S.; Junior, A.M.J. Characterization of In-Situ Cu-TiH2-C and Cu-Ti-C Nanocomposites Produced by Mechanical Milling and Spark Plasma Sintering. Metals 2017, 7, 117. [Google Scholar] [CrossRef] [Green Version]
  78. Vidyuk, T.M.; Dudina, D.V.; Korchagin, M.A.; Gavrilov, A.I.; Ukhina, A.V.; Bulanova, U.E.; Legan, M.A.; Novoselov, A.N.; Esikov, M.A.; Anisimov, A.G. Manufacturing of TiC-Cu composites by mechanical milling and spark plasma sintering using different carbon sources. Surf. Interfaces 2021, 27, 101445. [Google Scholar] [CrossRef]
  79. Kumari, R.M.; Sharma, N.; Gupta, N.; Chandra, R.; Nimesh, S. Synthesis and Evolution of Polymeric Nanoparticles; Elsevier Inc.: Amsterdam, The Netherlands, 2018. [Google Scholar] [CrossRef]
  80. Wang, K. Synthesis and Optical Properties of CuS Nanocrystals by Mechanical Alloying Process. Curr. Nanosci. 2010, 6, 163–168. [Google Scholar] [CrossRef]
Ijms 24 07933 g001 550
Figure 1. Generation routes of copper particle preparation [15]. Created with Biorender.com, accesed on 18 March 2023.
Figure 1. Generation routes of copper particle preparation [15]. Created with Biorender.com, accesed on 18 March 2023.
Ijms 24 07933 g001
Ijms 24 07933 g002 550
Figure 2. Classification of the most common types of ball mills according to their processing scales [26]. Created with Biorender.com.
Figure 2. Classification of the most common types of ball mills according to their processing scales [26]. Created with Biorender.com.
Ijms 24 07933 g002
Ijms 24 07933 g003 550
Figure 3. Generation route for the manufacturing of Cu-based particles through mechanical milling. Created with Biorender.com.
Figure 3. Generation route for the manufacturing of Cu-based particles through mechanical milling. Created with Biorender.com.
Ijms 24 07933 g003
Table
Table 1. Summary of the top-down approach through mechanical milling methods for synthesizing Cu-based particles.
Table 1. Summary of the top-down approach through mechanical milling methods for synthesizing Cu-based particles.
PretreatmentPrecursorsType of MillingMilling ConditionsPost-Treatment
of the Obtained CuP or CuC		Morphology, Average SizeReferences
Toluene used as PCA to prevent oxidation and agglomerationCu powder (99% purity), initial size of 200 nmWet ball mill40 h, 250 rpm. Ball size of 5 and 3 mm. Ball weight of 540 g. BPR 8:1-Agglomerates, 21 nm[34]
The milling media cooled with liquid nitrogenCu powder (99% purity)Cryogenic ball millAr atmosphere, 3 h, 150 K. BPR 100:1Washing with methanol, ultra-sonication for 15 minSpherical, 30 nm[33]
The waste Cu chips cleaned through ultrasonicationCu chips (30 g) obtained from machining areasPlanetary millAr atmosphere, 75 h, 400 rpm-Agglomerates, 50 nm[23]
-Cu powder (99% purity, initial size of 2–5 µm)HEBM4 to 16 h. Al2O3 balls of 1 mm. BPR 1:1 -Spherical with some agglomerates, 100 nm[54]
The precursors polished with SiC abrasive and further washed with acetoneElemental Cu spheres (99% purity), 25 mm in diameterVibratory disc mill and planetary millDisc mill: 30 s, 1500 rpm. Planetary mill: 50 h, 300 rpm-Spherical, 0.25–1 µm[38]
The precursors mixed in sealed quartz tubes under Ar atmosphere in a resistance furnaceCu powder (99% purity) CBMAr atmosphere, 177 rpm, 0.5 MPa. Rotating cylindrical steel cell: 200 mm/diameter; 29 mm/height. Seven balls of 25 mm, each of 67 g. BPR of 47.-Spherical, crystallite size of 5 nm[57]
Stearic acid (0.5 wt.%) added as PCACu powder (99.5% purity). Ni and Fe powders of similar purity added to the mixture to prepare a Cu-Ni-Fe compositeHEBMAr atmosphere, 40 h. Hardened steel vial of 55 mL, two balls of 14 and 11 mm, BPR of 2:1.-Spherical, 10–30 nm[58]
The precursor powders washed with NaOH and submerged in acetone. Ethanol added as PCACu powder (99% purity, 50 nm).
Graphene nanoplatelets and Al2O3 added as reinforcement.		Planetary mill2 h, 100 rpm. BPR 8:1The obtained composite consolidated at 850 °C, under pressure of 850 MPaAgglomerates, over 600 nm[63]
-Cu powder, initial size ranging between 4 and 7 µmBall millingDrum mill, 5 h, 300 rpm. BPR 3:1The CuNPs densified and mixed with W particles to generate a CuW compositeSpherical, 100 nm[59]
-Cu powder and stainless-steel powder of high purity (99%)HEBM2–60 min. 40 g of starting powder. Steel balls of 1.0 g each., BPR: 1:10, 1:5, 2:1, 1:1.The milled powders cold-mounted and further polishedAgglomerates or flakes, depending on the milling times and BPR[55]
Stearic acid (0.5 wt.%) added as PCACu powder (99% purity, <75 µm average diameter). Graphene was also added to reinforce the Cu matrixPlanetary millAr atmosphere, 4 h, 150 rpm, ZrO2 as grinding media, BPR 10:1The consolidation of the powders by hot-pressing techniquesAgglomerates, flattened particles or flakes, depending on the milling time[46]
The precursors physically mixed in a desired composition (71% Ni, 29% Cu w/w)Cu powder (99% purity). Ni powder of similar purity was added to obtain a Cu-Ni compositeHEBM2 hThe mixture placed in an Al2O3 crucible and heated at 1465 °C for 3 hSpherical, 200 nm[61]
-CuO and α-Fe2O3 of 99% purity to obtain a CuO-Fe2O3 compositeHEBM20 h. Agate balls, BPR of 11:1. Two milling processes under the same conditions were performed-Irregular shapes with some agglomerates, 30–50 nm[52]
Stearic acid (2 wt.%) added as PCACuMPs (99%, <45 µm) and Al microparticles (99% purity, <45 µm) to develop a Cu-Al compositePlanetary mill10 h, 300 rpm. BPR 10:1The milled Cu-Al composite was further mixed with PEG, compacted (749 MPa), and sintered at 950 °CFrom spherical to flake upon addition of Al to the Cu powder, microporosity[62]
Stearic acid (3 wt.%) added as PCACu powder (99% purity, 40 µm) and ZrO2 (99% purity) were used as raw materials to develop a Cu-ZrO2 compositeHEBM250 rpm. Vertical milling machine, BPR 10:1The composites mixed with paraffin to reduce the friction during compaction. Cold compaction at 700 MPa and further sintered at 950 °C for 2 hSpherical large composites and flake-shaped particles[64]
Methanol added as PCACu powder (99% purity, oxygen-free)Planetary millAr atmosphere. A chamber of 250 mLThe Cu powder reinforced with Al2O3 by electroless Ag platerFlake-like Cu clusters or Cu grains[38]
Ethanol used as PCACuO (99% purity, <20 µm) mixed with Y2O3 particles (50 nm, 99% purity) to obtain Cu-Y2O3 compositesPlanetary mill1. Ethanol medium, 2 h, 200 rpm, BPR 15:1.
2. Ar atmosphere, 8 h, 250 rpm, BPR 15:1		The first obtained powder was reduced at 120 °C, the second milled powder was compacted and annealed by spark plasma sinteringAgglomerates, spherical upon second milling under the same conditions as the first[65]
Methanol (0.25 wt. %) used as PCACu particles (99%, average size of 61 µm)Planetary millAr atmosphere, methanol medium, room temperature, 300 min, 300 rpm. BPR 5:1,A plating process was applied to obtain a uniform Ag layer on the CuPSpherical after 60 min of milling; flake-like after 300 min[47]
Stearic acid (1 wt.%) added as PCACu powder (D50 = 10 µm) and WO3 (D50 = 50 nm) to obtain a Cu-W compositeHEBMAr atmosphere, 16 h, 650 rpm. BPR 10:1The CuC was submitted to hydrogen atmosphere at 800 °C, then consolidated by hot pressing and sintered at 1000 °C for 2 h under 50 MPaMostly spheres or small agglomerates, 50–100 nm[60]
The powder precursors annealed at 850 °C for 30 min to remove impuritiesCu powder (99% purity, average size of 40 µm) and Ti powder (98.5%, 15 µm) were used as precursors to obtain a Cu-Ti compositeHEBMAr atmosphere, stainless-steel balls of 8 mm, acceleration of 400 m/s2. BPR 18:1.The CuC were sintered using spark plasma to obtain a Cu-Ti-C alloy. Graphite, nanodiamonds, and carbon black tested as carbon sourcesAgglomerates, with black dots in the structure that represent the C source[67]
The ball milling process modeled through discrete element model (DEM) simulationsCu powder (99% purity, average size of 45 µm)Planetary mill48 h. CEBM (10, 50, 100 rpm) HEBM (300, 500, 700 rpm). Balls of 1 and 10 mm in diameter. BPR 10:1-The morphology changed from spherical to flake-like CuP as the milling time increased. The average size decreased upon increasing the rotation speeds (27 to 9 nm).[35]
Table
Table 2. Summary of the bottom-up approach methods for the synthesis of Cu-based particles.
Table 2. Summary of the bottom-up approach methods for the synthesis of Cu-based particles.
PretreatmentPrecursorsType of MillingMilling ConditionsPost-Treatment of CuP or CuCMorphology, Average SizeReferences
-CuSO4
NaBH4/NaOH/reducing medium, EDTA was added as PCA		Planetary mill3 h, 250 rpm. BPR 10:1The CuNPs were mixed with CNTs, then dried at 60 °C for 2 h under vacuumSpherical, 20–50 nm as CuNPs. Agglomerated as Cu-CNTs composites[43]
The precursor was decomposed under inert atmosphereCu(HCOO)2 Ultrafine wet mill240 minThe CuNPs milled in dipropylene glycol monomethyl ether (DMP) and dispersed in oleic acidSpherical, 200–500 nm. Flakes, 2–5 µm[42]
Dichlorobenzene added as PCACu(COO)2Vibratory disc mill60 min. 45 g of 0.5 mm and 1 mm Zr balls.The Cu flakes were sieved and further separated with toluene and centrifugationFlakes and agglomerates, 100 nm[36]
Quantum dots (QDs) were added to the copper solution, sonicated, atomized, and sinteredCu(COO)2Planetary millFirst ball milling (low): 6 h, 150 rpm. Stainless-steel jar. Second ball milling (high): 1 h, 300 rpm. BPR 10:1The obtained QDs-Cu composite reduced at 300 °C for 5 h under Ar atmosphereSpherical, 4 nm[70]
Stearic acid added as PCACu(NO3)2, glucose/reducing agent. Graphene added to form a reinforced Cu-GNPs matrixCryogenic planetary mill4 h, 500 rpm, 193 K Steel milling balls of 6 and 10 mm, BPR 10:1The mixed powders were cold-compacted, sintered in a tubular furnace, and further heated and extruded at 823 KCu-GNPs bars, 5 mm diameter[13]
-CuSO4
Formaldehyde/reducing agent. Al2O3 and GNPs added to obtain a Cu-Al2O3-GNPs composite		HEBM20 h, 300 rpm. Al2O3 balls of 10 mm, BPR 50:1The composite was compacted at 1200 MPa and further sintered at 1000 °C for 2 hSpherical CuNPs, 50 nm. CuC, 700 nm[53]
The precursors CuS and Cu2S were co-milled in a stochiometric ratioCuS and Cu2S, Fe added as a reducing agentPlanetary mill15–480 min, powder charge of 5 g, 250 mL tungsten carbide grinding chamber, 50 balls of 10 mm diameter, 500 rpm. Ar atmosphere-Grains, below 5 µm[25]
NaOH or NaCl used as diluent phasesCuSO4 and CuCl2HEBMAir atmosphere, 1 h, 300 rpm. Stainless-steel balls of 10 and 7 mm. BPR 10:1The obtained Cu powders were dispersed in an ultrasonic bath, washed with distilled water, centrifuged, and dried at 60 °CCuONP synthesized with CuSO4: 14 nm; with CuCl2: 7 nm.[12]
The precursors were mechanically pre-mixed in a conventional ball mill Cu2S. Fe and Mg as reducing agentsElectric discharge assisted ball milling5 min, Ar atmosphere. During milling, pulsed discharges travelled through the milling atmosphere and the precursor powders-Agglomerates, 5–100 µm[68]
The precursors were mixed, and ethanol was added as PCACuSO4 (99%) and TiO2 (98%) were used to obtain CuNPs doped with TiO2HEBM10 h, 450 rpm, Zr balls of 3, 5, and 10 mm, BPR 10:1The CuC was cooled, then dried, ultrasonicated, and groundAverage size of 65 nm. The average size of the Cu-Ti composite was proportional to BPR.[69]
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Sandoval, S.S.; Silva, N. Review on Generation and Characterization of Copper Particles and Copper Composites Prepared by Mechanical Milling on a Lab-Scale. Int. J. Mol. Sci. 2023, 24, 7933. https://doi.org/10.3390/ijms24097933

AMA Style

Sandoval SS, Silva N. Review on Generation and Characterization of Copper Particles and Copper Composites Prepared by Mechanical Milling on a Lab-Scale. International Journal of Molecular Sciences. 2023; 24(9):7933. https://doi.org/10.3390/ijms24097933

Chicago/Turabian Style

Sandoval, Sebastián Salazar, and Nataly Silva. 2023. "Review on Generation and Characterization of Copper Particles and Copper Composites Prepared by Mechanical Milling on a Lab-Scale" International Journal of Molecular Sciences 24, no. 9: 7933. https://doi.org/10.3390/ijms24097933

APA Style

Sandoval, S. S., & Silva, N. (2023). Review on Generation and Characterization of Copper Particles and Copper Composites Prepared by Mechanical Milling on a Lab-Scale. International Journal of Molecular Sciences, 24(9), 7933. https://doi.org/10.3390/ijms24097933

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop