Al Nanoparticles Research Articles

Enhancement of Light Extraction Efficiency in AlGaN‐Based Deep Ultraviolet Light‐Emitting Diodes Using Cooperative Scattering Structures on the n‐AlGaN Layer

AbstractThe efficiency of AlGaN based deep ultraviolet light‐emitting diode (DUV LEDs) are mainly hindered by the light extraction issue. In this work, an innovative cooperative scattering structure is introduced that combines a nanopore configuration with an aluminum (Al) nanoparticle array on the n‐AlGaN layer of the DUV LEDs. The integration of these two scattering arrays can enhance light extraction by mitigating total internal reflection at the device interface. The nanopores are formed on the n‐AlGaN surface by electrochemical etching and optimized by varying the etching voltage, while the Al particles are formed by thermal annealing. With the help of the cooperative scattering structure, the light output power (LOP) of the optimized DUV LEDs is significantly increased by 77.6% and a notable 2.2 times is achieved in its light extraction efficiency (LEE) enhancement factor. Moreover, Finite‐Difference Time‐Domain (FDTD) simulations have validated that the cooperative scattering structure considerably enhances the LEE for both Transverse Electric (TE) and Transverse Magnetic (TM) modes, respectively. This work paves the way to fabricate high efficiency DUV LEDs via novel scattering structure designs.

Enhancement of mechanical and thermal properties of porous alkaline cements using silica and alumina nanoparticles

This study explores incorporation of silica- and alumina-bearing nanoparticles on the mechanical and physical properties of porous alkaline cements derived from industrial by-products. The aim was to determine if nanoparticles could enhance thermal performance, increasing porosity while maintaining compressive strengthSi nanoparticles enhanced strength, up to 100%, attributed to the combination of Si nanoparticles with the aluminosilicate gel. Al nanoparticles did not enhance mechanical performance, but led to density reduction, resulting in decreased strength. Thermal conductivity showed no significant variations due to nanoparticles, with all formulations classified as T2 thermal mortars. The best-performing formulation balanced density, thermal, and mechanical properties effectively, proving suitable for insulating core. Hygric properties within acceptable ranges, with water vapor permeability resistance <15 and capillary water absorption <0.4 kg/m2.min0.5. The findings highlight the potential of Si nanoparticles to improve mechanical performance of porous alkaline cements, offering valuable insights for application in thermal insulation.

Superconducting diode effect in Weyl semimetal Td-MoTe2 surface modulated by Al nanoparticles

Superconducting diode effect in Weyl semimetal Td-MoTe2 surface modulated by Al nanoparticles

The Modelling of Light Absorption and Reflection in a SiOx/Si Structure with Al Nanoparticles for Solar Cells

In this study, the light propagation in a structure consisting of SiOx on Si substrate with Al nanoparticles regularly placed in the SiOx layer is considered. Numerical modelling is performed by solving the Maxwell equations for the electromagnetic waves. In distinction from the well-known finite-difference time-domain (FDTD) simulation technique, we do not solve time-dependent wave equations here; rather, we propose a new numerical technique. This technique allows us to determine the stationary amplitudes of the electromagnetic oscillations directly from the linear algebraic equation system. The obtained results apply to silicon solar cells with an SiOx + Al top layer to maximise their efficiency. We found that 26 nm and 39 nm diameters of spherical Al nanoparticles are nearly optimal for a λ = 435.8 nm wavelength of the incident light. In addition, we evaluated the (nearly) optimal parameters of their placement in the SiOx layer. The results show the possibility of increasing the efficiency of solar cells by increasing the light absorption inside the active Si layer from ≈60% to ≈80%. Future perspectives on the proposed method and its possible applications are discussed.

Al@Al2O3 core-shell plasmonic design for the dilemma between high responsivity and low dark current of MoS2 photodetector

The localized surface plasmon resonance (LSPR) effect induced by metal nanoparticles (NPs) can solve the problem of low light absorption in two-dimensional (2D) materials limited by atomic scale. However, the accompanying problem is the rise in dark current due to plenty of electrons from metal NPs injecting into the 2D materials, which decreases the performance of plasmonic photodetectors. Here, we designed the structure of Al NPs coated with Al2O3 by low temperature oxidation treatment method to balance the dilemma between high photoresponse and low dark current. Raman spectrum and finite-difference time-domain simulations were used to verify that Al2O3 does not affect the LSPR effect of Al NPs. Compared to that of the pristine MoS2/Al photodetector, the MoS2/Al@Al2O3 plasmonic photodetector achieved a fourfold decrease in dark current, threefold increase in detectivity, and 1.5-fold increase in responsivity. As a result, the optimized plasmonic device achieves a high responsivity of ∼1719 A/W, an excellent detectivity of ∼6.0 × 1011 Jones, and an ultra-fast response speed of ∼15 ns. Our work reveals that constructing metal NPs covered by ultra-thin oxide layer is a feasible strategy for plasmonic photodetectors to decrease dark current and achieve high performance index.

Curcumin ameliorates aluminum oxide nanoparticle-induced memory deficit by regulating the hippocampal p38 signaling pathway in mice

ABSTRACT Objectives: Exposure to aluminum (Al) has been shown to be strongly associated with the pathogenesis of Alzheimer’s disease (AD). Recent evidence indicates that the toxicity of Al nanoparticle (Al-NP) is far greater than Al itself due to its particle size. Epidemiological studies suggest that curcumin lower the prevalence of AD. MAPKs (ERK, p38 and JNK) were suggested to be involved in AD pathology and memory impairment. The present study aimed to evaluate if curcumin has the ability to protect against behavioral deficits induced by subcutaneously administered Al-NP in mice. Furthermore, the levels of phosphorylated and total hippocampal MAPKs were assessed using western blottechnique. Methods: Al-NP (10 mg/kg/s.c.) was administered to adult male NMRI mice for 10 days with or without curcumin in doses of 2.5 or 25 mg/kg/oral gavage). Memory was assessed using passive avoidance apparatus and anxiety-like behavior was evaluated using elevated plus maze. Following the behavioral tasks, western blot analysis was performed on the hippocampal tissues to detect the levels of phosphorylated and total MAPKs. Results: The results revealed that Al-NP deteriorated memory with no significant effect on anxiety-like behaviors. Additionally, it activated hippocampal p38 signaling pathway with no effect on ERK and JNK. Curcumin treatment at the dose of 25 mg/kg restored memory and p38 activation. Discussion: This study suggests that subcutaneous Al-NP administration impairs memory and hippocampal p38 signaling with no effect on ERK and JNK. Co-administration of curcumin restored Al-NP induced memory impairment and hippocampal p38 phosphorylation.

Exploration of the reactivities of homemade binary pyrotechnics

Understanding the properties of explosives is the basis for investigating and analyzing explosion cases. To date, due to the strict legal control of standard explosives and initiators, homemade pyrotechnics composed of oxidizers and fuels have become popular explosive sources of improvised explosive devices (IEDs) threatening greatly social stability and personal safety. The reactivity of pyrotechnics strongly depends on their intrinsic characteristics and operating conditions, which determine the efficiencies of heat and mass transfer between the reaction zone and the unreacted zone. Herein, the tests of thermodynamics, pressurization characteristics, and combustion propagation behaviors are conducted to explore the effects of oxidizer species, particle size, and loading density on the reactivity of homemade binary aluminum-based pyrotechnics. The results show that the pyrotechnics with potassium chlorate (KClO3) have the strongest reactivity with the highest pressurization rate (dp/dt) and the shortest combustion duration. Compared with their counterparts based on aluminum microparticles(mAl), pyrotechnics consisting of Al nanoparticles (nAl) possess superior reactivity as expected, which results from the relatively short heat and mass transfer distances. The nAl-based pyrotechnics have a low reaction exothermic peak temperature, great heat release, great aluminothermic reaction completeness, and high produced peak pressure with several orders of magnitude higher pressurization rate. Increasing the loading density of the pyrotechnics over a certain value can change the dominant mode of heat transfer from convective to conduction, sharply decreasing the pressurization characteristics and combustion front propagation velocities (vp). The results of theoretical calculations using the NASA-CEA codes show that loading density can alter the reaction process of the pyrotechnics, leading to a decrease in the predicted pressure per unit mass for Al/KNO3 or Al/AP, and an increase for Al/KClO3. For nAl/potassium nitrate (KNO3), the density is between 1.0 and 1.25 g cm−3, across which dp/dt decreases by one order of magnitude from 0.148 to 0.014 MPa ms−1. In addition, vp decreases by three orders of magnitude from 0.040 to 0.078 m s−1. Distinct pressurization behaviors of nAl/AP are observed at a density of 1.5 g cm−3, while the variation in nAl/KClO3 reactivity fluctuates. These results are beneficial for the damage assessment of scenes caused by an explosion and for inversely calculating charge parameters.

Core/Shell Metal Oxides@MIL-53(Al) Nanoparticles as Catalyst for the Selective Hydrogenation of Cinnamaldehyde

Core/Shell Metal Oxides@MIL-53(Al) Nanoparticles as Catalyst for the Selective Hydrogenation of Cinnamaldehyde

Intuitive understanding of extinction of small particles in absorbing and active host media within the MLWA

In an absorbing or an active host medium characterized by a complex refractive index n2=n2′+in2′′, our previously developed modified dipole long-wave approximation (MLWA) is shown to essentially overlie with the exact Mie theory results for localized surface plasmon resonance of spherical nanoparticles with radius a≲25nm (a≲20nm) in the case of Ag and Au (Al and Mg) nanoparticles. The agreement for Au and Ag (Al and Mg) nanoparticles, slightly better in the case of Au than Ag, continues to be acceptable up to a∼50nm (a∼40nm), and can be used, at least qualitatively, up to a∼70nm (a∼50nm) correspondingly. A first order analytic perturbation theory (PT) in a normalized extinction coefficient, κ¯=n2′′/n2′, around a nonabsorbing host is developed within the dipole MLWA and its properties are investigated. It is shown that, in a suitable parameter range, the PT can reliably isolate and capture the effect of host absorption or host gain on the overall extinction efficiency of various plasmonic nanoparticles.

Fluorocarbon-Capped Aluminum Nanoparticles: Synthesis, Characterization, Combustion, and Comparison to Hydrocarbon-Capped Aluminum Nanoparticles

ABSTRACT Aluminum nanoparticles (NPs) are attractive as fuel additives in propulsion or pyrotechnic applications, but their combustion is inhibited by native oxide layer formation, which also reduces the energy content. Capping Al NPs with fluorocarbon ligands may inhibit native oxide formation and create an intimate mixture of fuel with an oxidizer capable of reacting exothermically with both Al and the passivating oxide layer. We present an approach to producing Al NPs capped by perfluorotetradecanoic acid (PFTDA), based on rapid mechanical attrition of NPs followed by PFTDA capping under mild conditions. The materials were characterized by dynamic light scattering, electron microscopy with energy dispersive spectroscopy, elemental analysis, X-ray photoelectron spectroscopy, X-ray diffraction, and infrared spectroscopy. Ignition and combustion properties were studied using bomb calorimetry, thermogravimetric analysis with differential scanning calorimetry, and photographic analysis of both flame and laser ignition of particle samples. For comparison, Al NPs were produced identically but capped with a hydrocarbon (oleic acid). PFTDA-capped NPs were found to ignite at lower laser power and burn far more vigorously than oleic acid-capped NPs, despite the observation that oleic acid capping resulted in a thinner native oxide layer on the air-exposed NPs. PFTDA-capped NPs were also found to have shorter ignition delay and lower ignition energy compared to commercially available Al NPs. XPS and XRD were used to probe the combustion products for the PFTDA-capped NPs, confirming formation of AlF3 and other products. Density functional theory was used to calculate the heat of formation of PFTDA, which was then used to calculate reaction enthalpies for reactions in both inert and oxidizing environments.

A Comparative Study of Congo Red Textile Dye Photodegradation Using ZnO Al and ZnO Al+Mn Nanoparticles

Photodegradation of Congo Red textile dye was successfully carried out using ZnO Al and ZnO Al+Mn nanoparticles synthesized using the bottom-up coprecipitation method. Powder X-ray diffraction provides information that Al and Mn doping successfully inserted in the host crystal structure while maintaining the Hexagonal Wurtzite crystal structure. However, a shift in the diffraction peak caused by the lattice distance changes with the addition of doping. FE-SEM EDS provides information that both nanoparticles are nonuniform sphere-like due to the addition of dopping, and each dopping is detected through EDS spectra. There is a decrease in the gap energy in each sample. ZnO Al nanoparticles have a gap energy of 3.29 eV, and ZnO Al+Mn nanoparticles have a gap energy of 3.28 eV. However, the decrease in the gap energy is not directly related to the percentage and kinetic rate of Congo Red photodegradation. Adding 5 mg of ZnO Al Nanoparticles powder could degrade Congo Red up to 97.9 % within 120 min using UV A radiation or 0.03504/min. At the same time, adding ZnO Al+Mn Nanoparticles powder with the same parameters could only degrade 67.6 % or 0.00759/min. HIGHLIGHTS Energy Bandgap Modification of ZnO Nanoparticles The incorporation of Al single dopants and Al, Mn co-dopants into ZnO nanoparticles synthesized via a bottom-up coprecipitation method significantly alters the energy bandgap. Al single doping resulted in a bandgap of 3.29 eV, while Al, Mn double doping yielded a bandgap of 3.28 eV. Enhanced Photocatalytic Activity of Al-Doped ZnO Al-doped ZnO nanoparticles exhibited superior photocatalytic activity toward the degradation of Congo Red textile dye. With a photodegradation rate constant of 0.03504 min⁻¹, these nanoparticles achieved 97.9 % degradation of Congo Red within 120 minutes. Comparative Photocatalytic Performance of Al, Mn Co-Doped ZnO While Al, Mn co-doped ZnO nanoparticles were synthesized using the same method, their photocatalytic performance for Congo Red degradation was notably lower than that of Al-doped ZnO. The calculated photodegradation rate constant was 0.00759 min⁻¹, resulting in 67.6 % degradation within the same timeframe. GRAPHICAL ABSTRACT

Atomistic insights into the reaction mechanism during the collision between Ni and Al nanoparticles in an oxygen environment

The chemical reaction between Ni and Al serves as a typical subject for the impact energy release of active metals. In fact, oxygen in the air will inevitably participate in the reaction process. This study systematically explores the various reaction mechanisms during the collision between Ni and Al nanoparticles in an oxygen environment through molecular dynamics simulations with reactive force fields. After elastic-plastic deformation, both Al and Ni nanoparticles can experience successive melting and micro-explosion triggered by exothermic reaction. Then, Al and Ni clusters are ejected into oxygen, resulting in a higher degree of oxidation reaction than intermetallic reaction. Moreover, the coupled development of intermetallic reaction and oxidation reaction is analyzed. Part of Al and Ni will form Al-O clusters and Ni-O clusters, respectively. The Al-Ni-O clusters are also observed via two pathways: (1) Al and Ni nanoparticles collide to induce intermetallic reactions forming Ni-Al compounds, followed by oxidation reactions; (2) Al-O clusters and Ni-O clusters react separately with Ni or Al. The oxidation clusters mainly exhibit approximately spherical and short-chain shapes with their size distribution conforming to the modified power-law distribution formula. Finally, the Al-Ni-O clusters are the low-coordination structure and account for about 70 % of the oxidation products in our simulation conditions. Enhancing velocity will cause the fragmentation of Al nanoparticles and accelerate the micro-explosion of Ni nanoparticles, consequently raising the reaction rate, and increasing the size of the nanoparticles raises the final number of Ni-Al intermetallic bonds, oxidative bonds, and the size of oxidation clusters. This study provides new insights into the potential reaction mechanisms of the active metal materials in the air environments.

Freeze-Cast MIL-53(Al) Porous Materials with High Thermal Insulation and Flame Retardant Properties.

The development of materials with superior thermal insulation and flame retardancy is critical for industrial applications and daily life. Metal-organic framework (MOF)@poly(vinyl alcohol) (PVA) (MOF@PVA) aerogel composites have demonstrated remarkable thermal insulation and flame retardancy properties. In this work, MIL-53(Al) was directly mixed with PVA and formed by freeze-drying, and the influence of the pore structure on the thermal insulation and flame retardancy properties of the materials was investigated. The incorporated MIL-53(Al) nanoparticles introduced abundant micro- and mesopores, enhancing the complexity of the pore structure and improving the thermal insulation and flame retardancy properties of the aerogels. The directionally freeze-cast aerogel achieved a thermal conductivity of 0.040 W·mK-1, and maintained excellent thermal insulation ability even at 220 °C. Furthermore, the aerogel exhibited nonflammable and self-extinguishing characteristics. This environmentally friendly manufacturing method provides new ideas for the design of MOF-based composites, thereby expanding their application areas.

Molecular dynamics simulation of alloying characteristics of Al–Mg nanoparticles under different process heating conditions

ABSTRACT The effect of thermal process parameters on the alloying of Al–10Mg (wt%) system has been studied in molecular dynamics approach. Five distinct values of heating rate have been considered for Al and Mg nanoparticles (NPs) to melt, coalesce followed by identical cooling. Detailed investigation of Al-Mg NPs alloying has been done in terms of alloying temperature, atomic migration, coalescence kinetics and mechanical characteristics for various heating rates were carried out. Prior to the alloying simulation, component melting simulations of Al and Mg single particles (SPs) were conducted to determine the melting temperature of NPs and to inspect their individual thermo-stability. From the change in potential energy, its evident that the melting temperature of the component NPs significantly depends on heating rates. Following the component melting, alloying simulations were conducted in three distinct phases: (i) heating, (ii) relaxation, and (iii) cooling and solidification. Following the solidification, uniaxial tensile test simulation was done on a block cut to characterise the mechanical behaviour in context to dislocation analysis, HCP evolution, stacking fault analysis and corresponding stress–strain relationship. Obtained results showed a substantial affiliation of heating rates and coalescence kinetics but showed minimal effect on mechanical properties.

The effect of constant electric field on the crack growth process of aluminum nanosheet using molecular dynamics simulation

Aluminum nanosheets are a form of Al nanoparticle that have been recently manufactured on an industrial scale and have a variety of uses. Al nanoparticles are extensively used in a variety of sectors, including aerospace, construction, medical, chemistry, and marine industries. Crack propagation in various constructions must be investigated thoroughly for structural design purposes. Cracks in nanoparticles may occur during the production of nanosheets (NSs) or when different mechanical or thermal pressures were applied. In this work, the effect of a continuous electric field on the fracture formation process of aluminum nanosheets was investigated. For this study, molecular dynamics simulation and LAMMPS software were used. The effects of various electric fields on several parameters, including as stress, velocity (Velo), and fracture length, were explored, and numerical data were retrieved using software. The results show that the amplitude of the electric field parameter affected the atomic development of modeled Al nanosheets throughout the fracture operation. This effect resulted in atomic resonance (amplitude) fluctuations, which affected the mean interatomic forces and led the temporal evolution of atoms to converge to certain specified initial conditions. The crack length in our modeled samples ranged from 22.88 to 32.63 Å, depending on the electric field parameter (0.1–1 V/Å). Finally, it was determined that the crack growth of modeled Al nanosheets may be controlled using CEF parameters in real-world situations.

Plasmonic Al, Ga and in-doped zinc oxide nanoparticles as key components for the design of electrophoretic inks with MWIR and LWIR absorbance properties

Doped zinc oxide nanocrystals (NCs) are halfway through semiconductors and metals. They exhibit unique optoelectronic properties from a high surface density of free-charge-carriers, which are responsible for localized surface plasmon resonance (LSPR). Here, a one-pot approach is presented to synthesize doped aluminum, gallium or indium zinc oxide NCs, making them all stable in non-polar media. The effect of doping on the growth mechanisms and the final crystalline structure were studied as a function of the aliovalent doping atom used. Doping atoms were integrated by substitution of Zn atom into the crystalline mesh of ZnO with a wurtzite phase identified as the primary crystalline phase for all samples by X-ray Diffraction (XRD). Typical aluminiun doped ZnO NCs (AZO) or Gallium doped NCs (GZO) nanoflowers were identified as a single crystalline structure by High-Resolution-Transmission Electron Microscopy (HR-TEM). Indium doped ZnO NCs (IZO) and pristine ZnO appeared significantly different with spherical and heart-like shapes, respectively. The doping level tendency was identified through Energy Dispersive X-ray (EDX) and increased form Al to Ga and In doping atoms. All plasmonic doped NCs have broadband infrared absorption in the Middle-wave (MWIR) and Long-wave infrared (LWIR) wavelengths, making them interesting for thermal regulation or thermal camouflage. As part of the latter application, dispersions of doped ZnO NCs were formulated as electrophoretic inks and their IR-absorbing performances determined by using a homemade setup including an infrared camera. AZO, GZO, and IZO NCs based inks achieved temperature contrasts of 15 °C and 6 °C in the MWIR and LWIR wavelengths.

Synthesis and characterisation of calcium-iron-aluminium nanocomposites for electromagnetic radiation shielding application.

Electromagnetic shielding parameters are crucial to investigate unexplored nanoparticles and their nanocomposites. Herein, calcium-iron-aluminium (Ca: Fe: Al) nanocomposites are synthesised using the simple solution combustion technique. The as-synthesised nanocomposites with various doping concentrations of Al nanoparticles are characterised to study the structural and surface parameters and to confirm the successful formation. Further, the procured Ca: Fe: Al nanocomposites along with various doping concentrations are utilised for electromagnetic shielding applications, and various shielding parameters are calculated. It was confirmed that Ca: Fe: Al nanocomposites are suitable for electromagnetic shielding applications.

Numerical study on effect of hybrid nanofluid as a passive heat transfer enhancement technique and different climates on thermal performance in a linear Fresnel collector

AbstractA notable distinction in this research is the utilization of a new method for calculating critical heat flux (CHF) based on a Look‐Up Table. The present study comprehensively investigates the effects of hybrid nanofluid, a type of passive heat transfer enhancement technique, on convection heat transfer coefficients and CHF. The study covers five different climates representing significant climate conditions in Iran, namely Bandar Abbas, Esfahan, Shiraz, Tehran, and Yazd, each with different solar irradiations. The nanoparticles considered in this study include silver, nickel, and aluminum, as well as Ag‐Au hybrid nanofluid with volumetric concentrations of 0.1%, 0.3%, 0.5%, 1%, and 2%. The modeling results reveal that the heat transfer coefficient increases with the volumetric concentration of nanoparticles. According to the results, at the CHF point for 2 vol% Ag–Au hybrid nanofluid and Ag, Ni, and Al nanoparticles, the heat transfer coefficient shows an increase of 28%, 11.5%, 10.6%, and 4.9%, respectively, compared to the results for pure water in Shiraz. Despite the acceptable results and effective performance of 2 vol% Ag–Au hybrid nanofluid for a linear Fresnel reflector, economically, 2 vol% nickel nanoparticles are identified as the most suitable choice.

Bioaccessibility of trace elements and Fe and Al endogenic nanoparticles in farmed insects: Pursuing quality sustainable food

This study investigated the in vitro bioaccessibility of aluminum, copper, iron, manganese, lead, selenium, and zinc in three important species of farmed insects: the yellow mealworm (Tenebrio molitor), the house cricket (Acheta domesticus) and the migratory locust (Locusta migratoria). Results show that all three insect species constitute excellent sources of essential elements (Fe, Cu and Zn) for the human diet, contributing to the recommended dietary allowance, i.e., 10%, 50%, and 92%, respectively. A higher accumulation of Se (≥1.4 mg Se/kg) was observed with increasing exposure concentration in A. domesticus, showing the possibility of using insects as a supplements for this element. The presence of Al and Fe nanoparticles was confirmed in all three species using single particle-inductively coupled plasma-mass spectrometry and transmission electron microscopy. The results also indicate that Fe bioaccessibility declines with increasing Fe-nanoparticle concentration. These findings contribute to increase the nutritional and toxicological insights of farmed insects.

Al nanoparticles coated with polyaniline and functionalized modified multi-walled carbon nanotubes (MWCNT) for removal of Ni2+ and Zn2+ from a simulated industrial effluent

Heavy metals are one of the most important environmental pollutants. One of the methods of absorbing heavy metals from industrial wastewater is the use of synthesized nanosorbents. The high cost and low efficiency of some common industrial wastewater treatment processes have created limitations. One of the interesting methods is the absorption process by carbon nanotubes as a new method. The present research aims to investigate the application of Al nanoparticles coated with polyaniline and functionalized modified multi-walled carbon nanotubes (MWCNT) for removal of Ni2+ and Zn2+ from a simulated industrial effluent. In the present study, the effect of absorption process time, pH, nickel and zinc ion dose, adsorbent dose and temperature on the efficiency of heavy metal absorption was investigated. The concentration of metal ions was measured using the ICP model ES-710. FTIR spectra for modified MWCNT nanotubes and polyaniline-coated alumina nanoparticles were recorded before and after adsorption using a PerkinElmer Spectrum One FTIR vacuum oven. X-ray diffraction patterns were obtained by XRD Rigaku Ultima IV, Japan, and SEM and TEM micrograph analysis were performed by FESEM TESCAN MIRA 3 and PHILIPS CM300, respectively.The maximum removal efficiency of nickel and zinc cations using nano alumina coated with polyaniline was obtained at pH 10 and 8, respectively. The maximum removal percentage of these two metal ions using functionalized MWCNTs can also be obtained at pH 7 and 8. The optimal concentration of metal ions for the highest removal efficiency of studied cations using surface modified alumina nanoparticles and functionalized MWCNT was obtained at 800 mg/L and 100 mg/L, respectively. In addition, the adsorption efficiency decreased with increasing process temperature. The obtained results showed that surface MWCNT with carbonyl, carboxyl and hydroxyl functional groups together with alumina nanoparticles modified by polyaniline can be considered as a potential adsorbent for absorbing nickel and zinc cations from simulated industrial effluents.