1 Introduction

1.1 Environmental nanotechnology

Environmental degradation as a result of development of advanced technologies is one of the serious global concerns [42]. Wastewater from different industrial process are one of the major sources of contamination in natural water bodies [17]. Fresh drinking water is a basic need of a healthy human community. The discharge of hazardous materials into the water bodies is growing substantially. However, increased use of toxic substances for different concerns has significantly raised the load of unwanted pollutants in clean water across the world [17]. The contamination of drinking water with heavy metals like arsenic, fluoride etc. and high load of dissolved solids are of major concern. On the other hand, microbial pathogens are major cause of water borne diseases among children [26]. It is merely not possible to remove these harmful contaminants from water. The safest approach to solve this global problem is to develop cost effective and efficient water treatment technologies, which needs a non-polluting & eco-friendly materials and process that too in a cost-effective manner.

Nanotechnology comprises the manufacturing along with management of materials at the nano level scale, either by scaling up from single groups of atoms or by refining or reducing bulk materials [76]. In the present scenario, nanotechnology has been used in different applications of science and technology such as sectors dealing with energy [67], industrial processes, sensors [129] and more broadly for environmental applications [90, 91]. Nanotechnology based approaches have developed efficient methods and materials for the solution of many challenging problems which were not solved with the help of previous technologies and conventional methods. It requires a combination of nanomaterials, nanocomposites and natural materials for a beneficial and successful treatment method for decontamination of water [113]. From past several years, different nano-based technologies were used for treatment of waste water and management of its sources. Nano structured materials are the principle component of nanotechnology.

1.2 Nanomaterials

Nanomaterials are structural and functional units of nanotechnology. Nanostructure science is extensive and interdisciplinary research area that has been rising exponentially worldwide in the last few decades [64]. It has the potential for transforming the pathways in which materials and products are developed and variety and behavior of functionalities can be retrieved. It is already having a momentous marketable impact, which will undoubtedly rise in the near future. Advantages of the nanomaterials in the field of water treatment and purification have been discussed in the next (1.3) paragraph.

1.3 Advantages of nanomaterial in water treatment

Nanotechnology is an emerging field and covers a wide range of technologies which are presently under the process of development at nanoscale [114]. It plays a major role in the development of innovative methods to produce new products, to substitute existing production equipment and to reformulate new materials and chemicals with improved performance resulting in less consumption of energy and materials and reducing environmental degradations well as enhancing the rate of environmental remediation [45]. New approaches are continually being examined to supplement traditional water treatment methods. These needs to be lower in cost and more effective than current available techniques for the removal of contaminants from water, in this context also nano-technological approaches are considered [74]. Nanoparticles used as potent adsorbents, in some cases are combined with magnetic particles to ease particle separation; nanoparticles used as catalysts for chemical or photochemical destruction of contaminants; nanosized zero-valent iron used for the removal of metals and organic compounds from water; and nano-filtration membranes [12]. Nanoparticles have a great potential to be used in waste water treatment. Its unique characteristic of having high surface area can be used efficiently in removal of toxic metal ions, disease causing microbes, organic and inorganic solutes from water [79]. Various classes of nanomaterials are also proved to be efficient for water treatment like metal-containing nanoparticles, carbonaceous nanomaterials, zeolites and dendrimers. This paper reviews recent advances on nano clay materials as an adsorbent with their application and mechanism in water treatment and purification. Another major field of nanomaterial is nanocomposites, that have high efficiency for removal of contaminants from water [90, 91].

2 Nanocomposite

In nanocomposites, one of the phases are in nanometer range (1 nm = 10−9 m) and they differ from conventional composite with microscale structure, due to their small size and the increment in surface-to-volume ratio [10, 39, 59].

Nanocomposites have been defined by various scientist as:

  • Nanocomposites are “Products with the nanoscale properties that improves the macroscopic quality of the material” [9].

  • Nanocomposite as a solid multiphase material, where one of the phases is 1, 2 and 3-dimensional property with nanometer range (100 nm) having electrical, thermal, optical, mechanical, electrochemical and catalytic qualities and will vary distinctly from the component materials [52].

The definition of nano-composite materials has over the years extended significantly to include different varieties of a system like- amorphous and 1, 2 and 3-dimensional materials, synthesized by two dissimilar materials at the nanometer scale. Thus, the nanocomposite material is a modified advance material having the property of (1 billion of a meter) fillers isolated from variety of different matrix. The stage may be the same as inorganic–inorganic, organic–organic or may be different combination like organic–inorganic [71]. The organic/inorganic class of combination of materials is a potential area of new and advanced research can be taken up.

2.1 Classification of nano-composite

Nanocomposites can be categorized, according to their structural and matrix differences, in three different classes as shown in Fig. 1.

Fig. 1
figure 1

Classification of nano-composites

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2.1.1 Metal based nano-composite

Consists of metallic nanomaterials such as Fe–Cr/Al2O3, Ni/Al2O3, CO/Cr, Fe/MgO, Al/CNT and Mg/CNT etc. with improved magnetic properties like- Superparamagnetism, saturation magnetization also having the property of high electrical resistivity by the disordered grain surface. They have major application in aerospace and automo-tive industries for the synthesis of structural materials [3]. Metal composites along with ceramic composites with CNT showed better results in environmental applications [116].

2.1.2 Polymer-based nano-composite (PBNC)

Consists of thermoplastics, thermoset, layered polymers, modified polymer titanium dioxide, carbon nano tubes with polymer hydroxides with a double layered polymers. Polymer based nanocomposites are extensively used in several industry due to their unique properties such as: easy manufacturing process, ductile nature and light weight. Except this, PBNC have low strength and this is the major disadvantage in comparison to ceramic based nanocomposite and metal nanocomposite. The most effective approach to improve mechanical properties of polymer based nano-composites is the combination of some materials like-addition of fibers, whiskers, particles to supports the polymer matrix for its longer stability [51].

These nanocomposites are of two types:

  1. (a)

    Thermoplastic nanocomposites: These materials are divided into two broad categories: Product generation and Engineering. Thermoplastics filled with nanomaterials have several added features compared with the thermoplastics having conventional materials.

  2. (b)

    Thermoset nanocomposites: These composites are not much significant but it can be manufactured using simple methods.

The following other filler materials are used for the synthesis of nanocomposites.

  • Organo montmorillonite

  • Carbon nanofibres

  • Carbon nanotubes

  • Metallic nanomaterials

  • Ceramics, etc.

2.1.3 Ceramic-based nano-composite (CBNC)

Al2O3/SiO2, Al2O3/TiO2, and SiO2/Ni etc. are the ceramic-based nano-composites. Some experimental studies showed that the toughening mechanism of CBNC is based on the crack-bridging role of the nano sized reinforcements [133]. Therefore, addition of such high strength nanofibres into ceramic matrices has permits the manufacturing of innovative nanocomposites with high toughness and endurance [54].

2.1.4 Nanocomposites: methods and preparation

Ceramic matrix nanocomposites can be prepared by several methods. The most common methods are (1) Power method of conventional technique such as: Spray pyrolysis, precursor route and vapor deposition technique (2) Chemical synthesis methods like- sol–gel, precipitation and colloidal techniques. The methods for preparation of metal matrix nanocomposites are: Liquid metal infiltration, Vapor and Electro-deposition methods and spray pyrolysis. The most important of themincludes reversible inclusion of polymer or pre-polymer in the matrix; In-situ insertion of molecule in polymerization; a straight combination of polymer and substances present; synthesis of template; In-situ polymerization along with sol–gel process [15].

As discussed in the above literature, different types of nanocomposites materials have proved their efficiency as good nano-adsorbent for removal of contaminants from the water. Different types of clay nanocomposites have also been successfully used as a nanoadsorbent for different sector of environment for treatment and water purification processes.

3 Nanomaterial as a nano-absorbent

Nowadays a number of technologies have been introduced into the market for the treatment of water and these advance technologies are gaining attention for the removal of metallic pollutants from waste water; reverse osmosis and membrane filtration are some of the popular technologies being used however coagulation, flocculation and electrolytic removal are also being used in several industries [82, 135]. But these commercial water treatment units are available in the market with variable affordable prices have various disadvantages e.g. consumption of non-renewable energy (being paid in terms of electricity bills), replacement of cartridge (extra burden on the budget) and one of the most important factors is removal of essential minerals like-Ca and Mg which is vital for the human body. So, these commercial units that looks affordable in the first instance to the customers are actually more costly when taken into account. Therefore, there is a requirement of low-priced treatment technology and materials for the removal of such types of contaminants is need of the hour and nano adsorbents have emerged as a fascinating field of research for the removal of these hazardous pollutants from the water [6, 7].

3.1 Nano sorbents

Nano sorbents are the functional units of nanoscience for the adsorption of organic and inorganic substances. Nano adsorbent contains a high capacity to remove the contaminants by adsorption [109]. Figure 2 highlights different types of nano adsorbents used for remediation of contaminants. Nanoadsorbent have been proven having a huge potential for the remediation of pollutants from air and waste water [65]. Nanoadsorbent offers a field of great sorption materials for environmental applications [98]. Use of adsorbents for removal of metallic contaminants in industrial effluents and water should fulfill the following conditions:

  1. 1.

    Nano sorbents should be nontoxic in nature.

  2. 2.

    The sorbents should have high potential of sorption even with low concentration of contaminants.

  3. 3.

    Surface removal of adsorbed contaminant should be easy to remove and

  4. 4.

    The adsorbent could be recycled and regenerated easily.

Fig. 2
figure 2

Types of nano-materials

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Section 2 of review paper explained the phenomenon of adsorption its process and kinetics for the removal of contaminants from the water.

4 Adsorption

Adsorption is a process of removal of soluble materials present in water and in this process, solid adsorbents are being used for the adsorption of contaminants. The most popular solid adsorbent material is activated carbon, which is used in large scale industries for domestic level water purification systems because of its high internal surface area (500–1500 m2/g). High surface area of this adsorbent shows the high affinity of adsorption. The adsorption of substances from water basically depends upon two types of mechanism: Hydrophobic and hydrophilic; the solubility of material in water is very important, the terms solubility represents the chemical interaction or activity of solute and water. It means the high hydrophilic substance lowers the adsorption and vice versa. The main factor which works behind this mechanism is driving force that decreases the surface tension between the matrix and the solid adsorbed [35, 50, 100, 102].

4.1 Adsorption isotherm

The adsorption is the phenomenon in which the amount of adsorbate is adsorbed on the surface of material, at constant temperature and fixed pressure. There are several types of adsorption mechanism, out of which Langmuir and Freundlich adsorption isotherm is most widely used and accepted. The classification of different types of adsorption isotherm is represented in Fig. 3.

Fig. 3
figure 3

Classification of adsorption isotherm

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The mechanism of adsorption isotherm has been explained below.

4.1.1 Langmuir adsorption isotherm

Langmuir [60], explained the concept of adsorption isotherm on theoretical basis for the kinetic theory of gases. Langmuir adsorption is based on monolayer adsorption on the homogeneous surface; this model also suggests that there is no lateral interaction between sorbet molecules [37]. The Eqs. (1) and (2) express the linear and non-linear model of adsorption isotherm.

$$\frac{1}{{q_{e} }} = \frac{1}{{Q_{0} }} + \frac{1}{{bQ_{0} C_{e} }}$$
(1)
$$q_{e} = \frac{{Q_{0} bC_{e} }}{{1 + bC_{e} }}$$
(2)

where qe is amount of adsorbate adsorbed, Q0 maximum capacity of the monolayer for adsorption, the b constant of Langmuir adsorption isotherm model, Ce is concentration of equilibrium where two processes when some of the gas molecules strike on the solid surface and some are evaporated or desorbed [61].

4.1.2 Adsorption isotherm theory of Freundlich

Freundlich adsorption theory explained the mechanism of multilayer adsorption of adsorbate on the surface of adsorbent. It indicates the heterogeneity on the surface of adsorbate. The Eqs. (3) and (4) express the linear and non-linear model of adsorption isotherm [37, 38].

$$\ln \left( {q_{e} } \right) = \ln K_{f} + (1/n)\ln C_{e}$$
(3)
$$q_{e} = K_{f} C_{e}^{{{\raise0.7ex\hbox{$1$} \!\mathord{\left/ {\vphantom {1 n}}\right.\kern-0pt} \!\lower0.7ex\hbox{$n$}}}}$$
(4)

where qe is amount of adsorbate adsorbed, n is intensity of adsorption, Kf is constant of Freundlich adsorption isotherm model which is related to adsorption capacity, Ce is concentration of equilibrium.

4.1.3 Adsorption kinetics

To determine the kinetics of the adsorption process, there are several models determining the adsorption kinetics. Some of them are discussed in this paper.

4.1.3.1 Elovich equation

Elovich model is generally used for the chemical adsorption processes having heterogeneous surface adsorption. This model applies when, surface coverage rate depends upon the time for the chemical adsorption on the solid surface where gas molecule adsorbed without desorption of the products. At that condition the Elovich Eq. (5) express as:

$$\frac{{dq_{t} }}{dt} = a\;\exp \left( { - b q_{t} } \right)$$
(5)

where a and b are the adsorption rate at the initial stage and constant of Elovich equation, qt is the amount of adsorption [130].

4.1.3.2 Pseudo-first-order equation of Lagergren’s

Lagergren’s [58] investigated the simple kinetic model explained the sorption process in solid/liquid by pseudo-first-order expression, that is

$$\frac{{dq_{t} }}{dt} = k_{1} \left( {q_{e} - q_{t} } \right)$$
(6)

where k1 is represents the rate constant of pseudo-first order reaction for adsorption processes, qe and qt denotes volume of adsorbate adsorbed at the time t at equilibrium condition (4).

4.1.3.3 Second kinetic model of Pseudo reaction

This model used for envisaging the kinetic parameters, also, it is based on the hypothesis where sorption takes place by the second order chemical adsorption, the linear expression given as follows

$$\begin{aligned} \frac{t}{{q_{t} }} & = \frac{1}{h} + \frac{t}{{q_{e} }} \\ h & = Kq_{e}^{2} \\ \end{aligned}$$
(7)

where qt is volume of adsorbent adsorb on adsorbate in time t, h is the primary sorption rate and qe is the volume of adsorbent adsorbed at equilibrium [44].

4.1.3.4 Weber and Morris model

The model also called as intra particle diffusion model which is used for the determination of the rate of adsorption in the liquid system because of internal diffusion (6). The general equation expresses as follows

$$q = K_{in} t^{n} + C$$
(8)

The equation gives time progress of the concentration in the state of adsorption. Where Kin is the rate constant [117].

A study carried by Jagtap et al. [44], while demonstrating the experiment in which chitosan was used for defluoridation of fluoride from the drinking water used Langmuir adsorption isotherm to understand the phenomenon of adsorption of fluoride on chitosan surface and plotted the graph 1/qe against 1/Ce. The removal efficiency was calculated by following expression in which they found the dimensionless quantity (r) as 0.62 (if the r value r < 1 adsorption favorable if r > 1 adsorption unfavorable) and therefore, he concluded that the adsorption was favorable in the demonstrated experiments.

$$r = \frac{1}{{1 + bC_{0} }}$$

Langmuir and Freundlich both adsorption isotherm was studied for adsorption study was found the value of Correlation factor (R2) of Langmuir theory (R2 = 0.977) was reported higher value of Freundlich [27] adsorption isotherm (R2 = 0.964) which concluded adsorption of fluoride by monolayer in uniform surface. In another study [126] has been stated that the both Langmuir and Freundlich adsorption isotherm also the help to understand for removing the concentration of heavy metal from wastewater with the help of nanomaterial is a solid surface.

Section 3 explained the nanoclay mineral, its structure with property, mechanism and application for the water treatment.

5 Nano-clay mineral

Nano clay originates from naturally occurring clays, which are mainly made up of finely divided mineral particles. The major portion of clay minerals is covered by layered silicates, which are made-up of silicon and oxygen bonds with some other elements. They can be thought of as a “stack” of two-dimensional single, double or multilayers, which are formed by corner-linked silicate (SiO4) tetrahedrons [49]. Due to the absence of chemical bond between layers of the clay geometry, the capacity of stacks layers increases leading for better absorption and dissipation of water and other available molecules. Such minerals affect the swelling or shrinking properties of the clay.

Clays have been unique in structure and chief commercial mineral, which is used in the industries; and gaining high attention in the current scope of nanotechnology [132]. Multiple application of clay minerals has been reported in the several branches of the science and technology. This enhances the efficiency and improves the quality of the products and also cut down the cost that ultimately protecting the environment. Nano-clays are abundantly present in nature and are related to major group of clay minerals. Clay mineral is an old material used by several ceramists from the prehistoric period to present for making of different types of clay products. China used Kaolin clay (China clay) from the third century for production of several products [89]. Basically, Single layer consists of 2, 3 and 4 layers of silica tetrahedra or aluminum hydroxide octahedra. Cays are made up of hydrous silicates having sharp and fine particles arranged in sheet-like manner. Sheet-like structure of clay minerals are called sheet-structure silicates and Phyllosilicates [72, 134]. Geometry of theses silicates is arranged as pages of a book like manner on one and another with same gaps of Van der Waals forces present between each layers, which is named as ‘interlayer”. Each interlayer made up of substitutions of ion in the layers or sheet of clay minerals and contains negative charges on the surface, this negative charge neutralized by the cations present in the inter-lamellar spaces in the structure of clay. These cations are called exchangeable cations because they can be easily substituted by some new molecules and anions for the modifications of the surface chemistry for desired use of clay mineral. Some major cations present in the inter-lamella spaces are sodium (Na+), potassium (K+), magnesium (Mg2+), and calcium (Ca2+), which are available as exchangeable cations and replaced by surface modifications. In general, material efficiency is based on the chemical structure and performance of the material but in case of clay, its physical characteristics plays a key role to define the different groups of clay [81]. Several separation methods are being used for the processing and extraction process of clay minerals like- centrifugation (energetic stirring), freeze-drying and ultra-centrifugation.

5.1 Classification and properties of clay

Clay minerals have a different type of physical properties like- shrinkage and air-drying in the presence of fire, plasticity, hardness, porosity and adsorption ability [18]. Clay minerals having very small molecular size and high porous property with the large surface area created the good physical and chemical reactions on the surface of clay minerals. These reactions occurred on the surface of clay with favorable conditions such as high electrostatic revulsion, specific cation exchange with crystallinity owing the process of adsorption. The effective porous surface of nano-clay develops higher bonding power on the surface with containment. Hydrous aluminosilicates structure of clay consists of metal and minerals oxides with wider property of stability. These qualities of clay minerals classified clay in some groups but the major class of clay is Kaolinite, montmorillonite, and illite and associated groups according to the Grim’s Classification [31]. These types of clay minerals have different types of structural units.

5.1.1 Structures of nano-clays

The characteristics that decide the configuration of a mineral have come from its chemical structure, geometrical arrangements of molecules and ions, with the electrical forces that bind the molecules in the structure [40]. The eight main elements such as O2+, Si4+, Al3+, Fe2+ Mg2+ Ca2+, Na2+, and K+ are the major constituent of the 99% of the earth crust. The majority of clay minerals consist of Si and (Al2O3) sheets that directly belongs to the Phyllosilicates family [63]. The sub classification of these two major families totally depends on the layer structure. The interconnected sheets of silicates attached with the other sheets of metallic oxygen and with hydroxyl ions [32]. The basic ratio of clay mineral is 1:1 in which one portion is tetrahedral sheet and other is octahedral sheet [128]. In the structure of octahedrons consist of 2 planes of OH which lies a plan of Mg and Al ions, which usually synchronized by hydroxyl sheets with octahedral geometry. The arrangement of these octahedrons in a hexagonal pattern called octahedral sheets [80]. This 2:1 ratio for clay minerals consists of smectite along with mica are major group present in clay mineral family.

6 Description of some of the major clay minerals with its structural properties and applications

The major composition of clay mineral is the same usually consist of two major geometry, one is the tetrahedral and second is octahedral sheets, arranged collectively in different structure. Difference in actual structure of the clay minerals developed the new kind of clay minerals. Some of the major group of clay minerals are discussed below.

6.1 Kaolin

Kaolinite group is a basic and broad group having the different clay minerals such as: dickite, nacrite, kaolinite and halloysite; developed by decomposition process of (orthoclase) feldspar. The dickite and nacrite clays are hydrothermally originated with the mixture of kaolinite [84]. Major composition of kaolinite group is silica (tetrahedrons) and alumina (octahedrons). The arrangement of silica tetrahedrons and alumina octahedrons is 1:1 layered stacking, because of which kaolinite is also called 1:1 clay mineral. The schematic structure of kaolinite is shown in Fig. 4. Kaolin clay is having several industrial applications, it is one of the chief clay minerals in the kaolinite group and also called the china clay. Kaolin use as a filler in the paper and plastic industries for coating and paper filler and its unique size and shape makes it suitable for different application. Its chemically inert structure and fine particle size with white color makes kaolin as best product for the ceramic raw materials, catalyst and adhesives and as an adsorbent for water treatment. The structural formula of kaolinite group is Al2Si2O5(OH)4 and major portion is covered by SiO2, Al2O3, H2O and minor portion is Mg, K, Fe, Ti, etc. elements.

Fig. 4
figure 4

Structural geometry of common clay minerals [31]

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6.2 Smectite and montmorillonite

Smectite is the largest and key class of phyllosilicates clay mineral group. Smectite is chemically very different from the kaolinite group minerals. The symmetry of smectite clay mineral is equidimensional and elongate. Elongate structure of smectite having iron montmorillonite (nontronite) and magnesium montmorillonite (saponite) and lithium montmorillonite (hectorite). The special property of smectite group is replacement of octahedral and tetrahedral sheets. Substitution of Mg and Fe in the place of aluminum in octahedral sheet and replacement of alumina and silicates in the tetrahedral sheet [84]. Ca and Na montmorillonite are major mineral of clay in the group of smectite having minor geometrical dissimilarities in the geometry. Na montmorillonite have a one layer of water while Ca montmorillonite have two water layer in interlayer location in the structure. Na-montmorillonite possesses high swelling capacity and viscosity as compared with the Ca- montmorillonite due to the presence of two water layer in the internal position. Different structural geometry makes smectite group mineral more convenient for the application in the different fields of environment such as good adsorbent (industrial adsorbent), organo-clay (nano-clay) for water treatment, food additives, desiccants, emulsion etc. The common structural formula of the this group is (Ca,Na,H)(Al,Mg,Fe,Zn)2 (Si,Al)4O10(OH)2-XH2O.

6.3 Chlorite

Chlorite group represents the tetrahedral:octaherdral:tetrahedral (2:1) layers with the molecular formula (Mg,Fe,Li)6 AlSi3O10(OH)8. Single group member also have their individual chemical structure like chamosite (Fe2+,Mg)5Al(AlSi3O10)(OH)8, cookeite LiAl5Si3O10(OH)8, orthochamosite (Fe2+,Mg,Fe3+)5Al(AlSi3O10)(OH,O)8, clinochlore (Mg,Fe2+)5Al2Si3O10(OH)8. High presence of chlorite is found in shals. This group includes variety of clay such as: clinochlore, cookeite, donbassite, franklinfurnaceite, nimite, orthochamosite, sudoite, baileychlore and borocookeite [43]. Extensive range of applications of Palygorskite and sepiolitein the industrial sector are also reported [43]. 2:1 layer Palygorskite and sepiolite silicates contains a 2-dimensional tetrahedral sheet and octahedral sheets in 1-dimension. The tetrahedral sheets are grouped into ribbons like structure, every ribbon joints with the following adjacent ribbon with overturn of SiO4 tetrahedral individually with a set of two silica atom and one oxygen atom in a center [29].

6.4 Bentonite clay

Bentonite basically consist of a mineral montmorillonite and having the composition of aluminum Phyllosilicates. Alternation of glassy materials (volcanos) forms the bentonite clay. Bentonite clay minerals having the variety of other minerals such as: kaolin, mica and attapulgite, illite along with quartz, feldspar and gypsum. The general molecular formula of bentonite clay is Al2H2Na2O13Si4. Mainly two types of bentonite clay are found; sodium and calcium bentonite. Sodium bentonite clay having one Na + ions as an exchangeable ion with single water layer particle with swelling property on other hand calcium bentonite clay is a non-swelling type clay in which Ca+ as an exchangeable cation with a presence of double layer of water. Bentonite clay have several application in the different area. It can be used in oil adsorption, pelletizing, cast iron industry and odor and liquid adsorbent. One of the major application of bentonite is waste water treatment, it is used as adsorption/absorption material. Bentonite naturally have the low permeability, which makes bentonite as a sealing material for the landfills construction and rehabilitation to control the contamination of ground water from pollutants [89].

7 Methods for preparation of clay nano-composites

According to the Zapata [131], synthesis of the nano-composites can be achieved by the 3 different routes:

  1. 1.

    Solution Blending

  2. 2.

    Molten State

  3. 3.

    Polymerization

Out of these methods of preparation of nano-clays, Polymerization process have some novel advantages such as:

  • Enhanced compatibility of clay with other matrix of polymer

  • Improved dispersion quality of the clay mineral

  • An effective way to synthesized metallocene nano-composite

Polymerization process develop the spacing between clay layers which increases gap in the structure of clay particle and changes the state of clay mineral from intercalated to exfoliate.

8 Mechanism of nano-clay adsorption in water treatment

Recent studies showed that nano-clay as an adsorbent received more consideration for adsorption of various contaminants from water due to process of surface sorption mechanism. It has been discussed earlier that the nanoclay is non-toxic, low-cost material with the high potential of ion-exchange and abundantly present in nature. As already discussed in the classification of clay minerals (6.2) different types of clays such as bentonite [11], kaolinite [47], illite [21], sepiolite [62], montmorillonite [41] and pyrophyllite [34] have been reported to be efficient for the elimination of pollutants from water. Nanoclay minerals having the high specific surface area and high sorption capacity that provides high structural and chemical stability towards the adsorption of organic and inorganic contaminants.

Adsorption process at the surface of the clay is directly linked to the charge chemistry present at the surface. A different number of the mechanism have been reported for the sorption of metals ions by the nanoclay minerals like-Physical adsorption, Micro-precipitation (involves an exchange of ions at permanent charged sites and development of compounds (complexes) at the edge sites with hydroxyl groups and chemisorption [14, 53] (Figs. 5, 6). The formation of organo clay can be achieved by the exchange of cations with organic molecules [111]. Some of the factors which plays a major role in the adsorption process are explained below.

Fig. 5
figure 5

Mechanism of heavy metal adsorption at the surface of Nanoclay

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Fig. 6
figure 6

Adsorption of pollutants at the different surface locations of nano-clay

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8.1 Effective factors for adsorption process

Some of the major factors required for the better adsorption of molecules in the sorbent, are discussed below.

8.1.1 Innate surface properties of nano-adsorbent

Figure 2 represents the mechanism of surface adsorption. Nature and presence of active sites at the surface of nano-adsorbent is a key challenge [88]. Some of the basic factors are required for the proper functioning of nano-adsorbent in any solution and substract are high surface area, and location of atoms on the surface. High potential of adsorption, maximum resistance property and high surface binding energy at all location of the molecules requires surface attachment, inner side attachment, and edge attachment (Fig. 6). These characteristics of the nano-adsorbent lead to the major portion of the atoms and molecules adsorbing at the surface and on the interfaces to enhance the significant availability and affinity, surface improvement and increasing the number of potential sites, ultimately increasing the surface energy towards the removal of a specific pollutant [86].

8.1.2 External chemistry of nano-adsorbent

Mechanism of external adsorption of nanoadsorbent implicates the use of different functional groups and different variations on the adsorbent surface. Coupling process of different nanoparticles with a variety of external process of functionalization leads towards the greater success in adsorption properties. Besides this, surface functionalization process also prevent from the loss of aggregation of nanoparticle and provides their selectivity. The functionalization of the different groups at the surface of the nanoparticles increases the adsorption capacity of the Nano adsorbent [93].

A study by Vukovic et al. [124] on multiple wall carbon nano tube functionalization with ethylenediamne (C2H4 (NH2)2) by the formation of amide bond with carboxyl groups on external layer of carbon nanotube explained that pH of solution plays a significant role in sorption process. pH plays a key role in the degree of ionization, speciation of metallic ion in the aqueous solution for the removal of Cd II. Another factor that directly affects the role of functionalization of organic groups on surface of nanomaterials or nano-adsorbent is the Zeta Potential, it is usually calculated to check the dispersion of nanomaterials in the liquid and to determine the charges present on the surface of colloids and molecules. It is called electrophoretic mobility (motion of ions within a solution).

9 Applications of nano-clay minerals

Clay minerals are composed of layered silicates with the combination of two elements-silicon and oxygen and having several applications in numerous fileds of environment. Nano-clays are non-toxic and non-combustible materials, which therefore used in manufacturing process of different materials such as flame and fire protection for plastics. Clay minerals finds more attention in industrial applications used as a raw material in construction for e.g. Clay minerals in natural lime rock or in the clay or shale mixed with limestone would contribute SiO2, Al2O3 and possibly Fe, alkalis, and alkaline earths depending on the identity of clay minerals for the manufacture of Portland cement. Kaolinite is best suitable for the manufacture of white Portland cement [92].

Phlogopite, illite, and glauconitic clays are used as agro mineral additive to enhance soil fertility for crop production because of their high content of potassium. Clays composed of montmorillonite and kaolinites are used in pesticide preparations as diluents to enhance even the dispersion of the toxicant and the retention of the pesticide by plants. Especially kaolinites, have been used for centuries in pharmaceutical preparations of intestinal adsorbent drugs and other therapeutically useful applications. Clays are very valuable prime raw materials in the manufacture of several ceramic products for example in ceramic building materials (bricks, tiles, stoneware pipes, domestic sanitary wares, and fittings for sewage and drainage) and domestic ceramics (table wares, dinner ware, flower vases, dental wares, e.g. artificial teeth, etc.) In clarification of portable water, colloidal matter is removed by filtration and/or sedimentation processes. Alum is usually used to flocculate the colloidal materials to enhance its settling and filtration rate.

Films food packaging and plastic surfaces modifications are some other areas for nanoclay application as plastic additives. The addition of nanoclay to the plastics leads to higher tensile strength, improved barrier and abrasion properties, excellent surface qualities, low thermal expansion and very good flow and processing properties. This outstanding property profile qualifies plastic–nanoclay-composites as an interesting alternative to conventionally reinforced materials. In most of the cases, research studies have shown that nano-clay clays are best suitable for water clarification purpose because of possessing the essential dispersion and adsorptive properties in water treatment; further, clays at the same time can be used to reduce and remove bad odor and taste in water and also for softening of water. Removal of metal and inorganic contaminants from waste water due to high adsorption capacity of nanoclay is the key application in the environmental field [110]. Several applications of clay minerals have been shown in the Fig. 7.

Fig. 7
figure 7

Different applications of clay minerals

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10 Summary

There is a huge requirement of cost-effective advanced technologies for water purification, specifically to ensure the quality of drinking water by removing micro pollutants, and strengthening the industrial production process. Development in nanoscience and engineering are considered as novel opening to develop innovative, eco-friendly and cost-effective water treatment technologies. The unique physico-chemical characteristics of nano-materials caught a greater attention for the treatment of water in the current scenario. As of late, modified nano-clays and clay as adsorbents are gaining extensive attention because of their greater potential for the removal of contaminants from different matrices.

Clay and clay minerals have been explored as the adsorbents for the removal of heavy metals from aqueous solution. The advantages of using clay minerals as alternative adsorbents for removal of heavy metals includes high ion sorption/exchange capacity, low permeability, swelling ability, chemical and mechanical stability, and large specific surface area. Different types of clay minerals have been tested for the removal of heavy metal ions from water and wastewater. Some of the recent studies on utilization of clay minerals as adsorbent for water purification are discussed in the manuscript and a glimpse of it is given below.

Modified bentonite clay with HCL was used by Hajjaji and El Arfaoui [36] for the removal of Zn (II) and Kul and Koyuncu [56] used same modified (bentonite with HCL) for the removal of Pb(II); likewise Eren et al. [23] used pillared bentonite by MnCl2 for the removal of Pb(II) and all the studies concluded that bentonite clay was very effective for the adsorption of heavy metal in water treatment. Tirtom et al. [115], worked on removal of Ni(II) and Cd(II) by chitosan-bentonite clay having cross-linked structure to enhance efficiency of adsorbent for adsorption of contaminants from water.

Kaolin clay are the oldest clay mineral used in different environmental and industrial applications. In Tang et al. [112] worked on removal of Cd (II) from the water by influencing certain parameters such as- increasing initial concentration, pH, equilibrium time, dosage and temperature on the adsorption performance; similar type of findings have been reported by Fathima et al. [24] on kaolin-supported bacterial biofilm of Bacillus species for removal of Cr(III) [16]. Removal of Cr (VI) from aqueous solution by onseeds of Artimisa absinthium was performed by Rao et. al. [103] and results showed higher removal efficeincy and Artimisa proved as a novel plant material for cadium removal. Unuabonah et al. [120] performed the experiment on polyvinyl alcohol modified kaolinite clay for the removal of Pb(II) from water and concluded that modified natural clay (kaolinite) as a good adsorbent for removal of Pb(II). Sari and Tuzen [106], investigated the efficiency of on pillared kaolinite using MnO2 for the removal of Cd(II) as well as removal of Pb(II) and Cd(II); also studied by Mascia et al. [75] and the studies resulted in establishing the high removal efficiency of nano-clay [101].

It has be seen that some of the natural clay like- Montmorillonite show significant dye and metal removal capacities; while others still need modifications in order to enhance its adsorption capacities. Study on montmorillonite clay performed by several researchers by activating adsorption capacity [5], Pillared montmorillonite by TiCl2, [87]. Chitosan- montmorillonite beads were prepared by crosslinking with pentasodium tripolyphosphate for the removal of Cu (II) studied by Pereira et al. [95]. Some more toxic metal removal studies was performed by Dos Santos et al. [20] and Wang et al. [127]. For the removal of Co (II) by modified chitosan-montmorillonite and removal of Hg(II) by influence of pH, ionic strength and treatment with different cations [69].

Similarly, the mixture of smectite, illite, calcite used for the removal of Cu (II) and Zn (II) evaluated the adsorption capacity of three natural clay [85]. Palygorskite clay was also found effective for the removal of Cd (II) through HCL modification studies [28].

Pranoto and Fathoni [97], used clay ceramic filter for the removal of Cd by adsorption by model reactions study with the combination of clay and andisol composition. Andisol/clay mixture was effective in minimizing the concentration of cadmium in water by 98.9%. Like-wise Kalebaila et al. [48] also did the same experiment with photo catalysts by modifying the clay with inorganic ions using the sol–gel synthetic process and concluded adsorption process with a good adsorbents will be cost effective in terms of conservation. Table 1 shows summary of different work done by researchers from last several years till the current scenario for treatment of variety of contaminants using nano-clays.

Table 1 Previous research carried out on nano-clay for water treatment
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Advances in clay to make nano-composites clay materials after modification in structural form are used for water treatment [122]. Adsorption offers a wide range of bacterial and organic removal with complete removal of pathogens. Study on clay based nano-composite by Das et al. [19], concluded that Surface modification in halloysite nano-clays for two dissimilar organosilanes makes it beneficial for the adsorption of toxic materials and proved that halloysite is a new adsorbent materials for adsorption of toxic inorganic–organic contaminants from water.

Combined clay adsorption-coagulation study by Ababu et al. [1] concluded that with two-step clay-coagulation method along with aluminum sulphate increases the removal efficiency of Zn, Cu and Cd to 96–99%.

Recent study by Merah and Mohamed [78] worked on the mechanism of nano clay and its water uptake, they used synthesized unsaturated polyester/nanoclay (UP/NC) composites to understand the mechanism of nanoclay and concluded that the addition of I.30E nanoclay enhanced the hydrophobicity of the nanocomposite with a maximum improvement of about 40% at 4 wt.% of nano clay loading. Flexural test results revealed relative degradation in the flexural properties of neat UP and UP/NC, due to moisture uptake. However, the reduction in flexural properties was found to be minimal at the optimum nanoclay loading of 3 wt.%. In this paper, we have elaborated on the types of nano-clays that are common and their associated benefits with reference to water treatment with the combination of nanotechnology. A Full structural flow chart depicting the entire concept dealt in the manuscript has been represented in Fig. 8.

Fig. 8
figure 8

Structure of current review paper

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11 Conclusion and future considerations

Composites of clay used for coating with the naturally synthesized polymer have greater potential for the treatment of water. As discussed in the literature, the efficiency of clay minerals could be increased by integration of new materials at nanoscale for manufacturing of stable clay nano-composites with advance properties.

Polymer–clay nano-composites getting more attention from recent few years in different areas like in automotive Industry (polymers reinforced with carbon nano-tubes with exfoliated clay are being used for the manufacturing of automatic parts), Barrier layers in packing (polyamide-6 clay nanocomposites are mostly used in high barrier packing for food). These nano-composites made good combination of barrier properties with the perfect ratio of O2 and CO2, High mechanical and thermal characteristics (manufacturing of flame retardants), Textiles Industry (for the commercialization of fibers and Coloring of dyes) [33]. On the other hand, there is immediate need for advanced materials for the elimination of emerging pollutants existing in drinking water because present technologies do not have much efficiency for the removal of prevailing pollutants from the water. Modifications in the surface geometry and increment in the surface area make them a compatible material for different applications. More experimental studies are required to produce different results in the area of polymer clay nano-composites for treatment and purification of water. The development of new material and composites for decontamination of water is required for intended uses. Besides this, production capacity of water filter can be increased by the application of nanotechnology because these nanocomposites offers high surface to volume ratio with the presence of number of active sites for the removal of pollutants. Therefore, adsorption is one of the great approaches for the complete removal of contaminants and development of new water purification systems with low cost. Further research is, therefore, required for the development of an appropriate understanding of the structure, property and formulation relationship in nanocomposites for the better output of the water systems. Nano-clay have been proved to be the best materials for the manufacturing of new materials and provide cost effective sustainable solutions to different industries for environmental health and safety. Replacement of conventional methods for purification of water with advanced cost-effective materials have been proven as a promising tool in water purification process all-round the globe.