A Scientometric Analysis Review on Agricultural Wastes Used as Building Materials

: The rapid urbanization of developed countries and the difﬁculty in disposing of agricultural wastes have created opportunities for the construction industry to use agricultural wastes. A wide variety of agricultural waste materials are already in use with concrete as substitutes for cement and aggregates, as well as reinforcing materials. This study reviews the available literature published from 1935 to 2022 on agricultural wastes being used as building materials. The research utilizes a bibliographic approach based on the Scopus database. This article retrieves data employing the Scopus database and incorporates 671 articles based on the keywords, agricultural wastes used as building materials. The scientometric analysis is the second step, wherein the patterns of the obtained articles are investigated with various factors such as countries with the most publications, sources that have the most publications, most frequently appearing keywords, and articles with more relevant research works. A summary of the results obtained at various stages of the research is depicted in each phase. Detailed quantitative and qualitative discussions are also conducted to achieve the three main objectives: the summarization of quantitative data, discussion of the existing application, and identiﬁcation of future research directions. These ﬁndings serve the future endeavor of agricultural waste-to-building materials’ incineration academic research. The scientometric review paves the way for academics from various nations to impart novel ideas and information and foster research collaboration.


Introduction
The construction industry worldwide consists of real estate and urban development that include residential and office buildings, retail properties, hotels, amusement parks, and many such establishments. Concurrently, the urban development sector comprises any subsectors such as water supply and sanitation, urban transport, schools, and healthcare that aid in city development and management [1].
The demand for and cost of building materials are increasing daily due to the shortage of raw materials [2]. Therefore, the procurement of natural resources for building materials is becoming a global issue. Furthermore, conventional building materials, such as cement, require a great deal of thermal and electrical energy. Hence, during production, it results in higher construction costs. Furthermore, the construction industry is inherently unsustainable. These observations suggest that more scientific research works are needed in developing more sustainable and environmentally friendly building materials without sacrificing or relinquishing the building quality [3].
In addition, the disposal of wastes generated from crops such as sugarcane bagasse, wheat husks, coconut shell, and rice husks is crucial in developing countries. For example, India has been reported to produce over 600 (MT) of agricultural waste in a year [4].
Moreover, as the farming system becomes more intensive, agricultural wastes are expected to be generated more because of the rising agricultural practices in the current decade [5]. The predominantly used methods for disposing of and dealing with agricultural wastes are dumping, incinerating, and composting conventionally. Unfortunately, all these methods have significant negative environmental consequences. However, new research attempts have shown that agricultural waste and its byproducts can be utilized to develop a viable and preliminary solution to the recently identified challenges, either in part or as a whole [6,7].
The use of agricultural wastes in the construction industry reduces the environmental impact of waste disposal in landfills, thereby reducing the pollution caused by conventional building materials such as cement [8]. There has been partial replacing of the sand in the production of cement blocks with agricultural crop wastes such as peanut shells, rice husks, rice straws, and coconut shells. The utilization of agricultural wastes in producing blocks has met ASTM standards for the strength and durability of the product [9][10][11][12][13][14][15][16][17]. In addition, wat and barley straw fibers stabilized the soil to produce bricks with properties facilitating the development of environmentally friendly and safe building materials [18]. Furthermore, it was demonstrated that straw bale instead of soil construction led to more environmentally friendly buildings. Materials with thermal performance and low embodied energy have been cited as the reason for this issue. It has also been concluded that the use of agricultural wastes as building materials is acceptable and can help meet the sustainability goals, and at the same time reduce pollution and other harmful effects involved [19,20].
The field of research employing agricultural wastes as building materials and their applications in construction can almost be traced back to the beginning of the 21st century. The state of agricultural wastes being economical, universally available, cost-efficient, and yet a possible building material motivated the current investigation. These agricultural wastes are utilized as building material on supplementary cementitious materials (SCMs), an alternative to recycled aggregate, and alternative building materials. The utilization of agricultural wastes in the construction industry assists environmental and sustainable development in various ways.
This article qualitatively evaluates the global trend of the literature seeking alternative agricultural wastes as building materials from 1935 to 2022. In the current study, scientometric analysis was conducted to examine the published articles that employed agricultural wastes for construction. Therefore, a systematic analysis of various studies on agricultural wastes as building materials is provided including an assessment of the current state of the research and a forecast of future trends based on the knowledge of the application of agricultural wastes as building materials.
As a visual reference, this type of investigation on the performance of scientists can reveal patterns followed and improve the research in developing and mature disciplines [21,22]. In recent years, bibliometric analysis has become a popular method. The main objective of the bibliometric study is to measure the performance within a specific field or body of literature in national and international scientific and technological research [23][24][25][26]. Data from a wide range of fields, such as biology, physics, social science, and health science have been incorporated into the methodology employed in preparing this article. Even when traditional literature reviews fail to provide enough direction, bibliometric analyses play an important role in helping researchers chart a course forward [27]. Figure 1 illustrates the Sankey diagram of the country, keyword, and source of topics researched. Bibliometric analysis was conducted based on three principles: the Zipf, Bradford, and Lotka laws [28]. According to the Zipf's law, predicting the distribution of words in a text is possible based on their frequency [29]. The Bradford's law is a good starting point for librarians in determining the number of core journals in a given field of study [30,31]. In accordance with the Law of Scientific Productivity, formulated by Lotka, an author's published articles, on average once in every two years in a given field, measure the scientific productivity of the author [32,33]. published articles, on average once in every two years in a given field, measure the scientific productivity of the author [32,33]. Bibliometrics is the study of the structure of documents using tools, objectives, frequency classification, ranking, and reference analysis. Although document structures are essential for all topics, they are particularly important in the field of information inspection [34]. In the concept of "sustainable alternative building material" in this article, the unique values of the documents were created through knowledge diagrams based on keywords, groups, and citations using the VOSviewer quantification feature [35]. This method was applied for validation from the year 1935 to 2022. The outcome of the bibliometric analysis is demonstrated in Figure 2. VOSviewer is used to view bibliographic analysis, and to create and view graphical maps based on author sections and other important published topics. Network maps Bibliometrics is the study of the structure of documents using tools, objectives, frequency classification, ranking, and reference analysis. Although document structures are essential for all topics, they are particularly important in the field of information inspection [34]. In the concept of "sustainable alternative building material" in this article, the unique values of the documents were created through knowledge diagrams based on keywords, groups, and citations using the VOSviewer quantification feature [35]. This method was applied for validation from the year 1935 to 2022. The outcome of the bibliometric analysis is demonstrated in Figure 2. published articles, on average once in every two years in a given field, measure the scientific productivity of the author [32,33]. Bibliometrics is the study of the structure of documents using tools, objectives, frequency classification, ranking, and reference analysis. Although document structures are essential for all topics, they are particularly important in the field of information inspection [34]. In the concept of "sustainable alternative building material" in this article, the unique values of the documents were created through knowledge diagrams based on keywords, groups, and citations using the VOSviewer quantification feature [35]. This method was applied for validation from the year 1935 to 2022. The outcome of the bibliometric analysis is demonstrated in Figure 2. VOSviewer is used to view bibliographic analysis, and to create and view graphical maps based on author sections and other important published topics. Network maps VOSviewer is used to view bibliographic analysis, and to create and view graphical maps based on author sections and other important published topics. Network maps utilize various colors, shapes, and symbols to represent the relationship and its relative contribution. The number of sides represents nodes, and the thickness of the link chain represents the connectivity with the number of copies made by the researcher. Some researchers have used the VOSviewer software (version 1.6.18) to publish the bibliometric analysis results [36][37][38][39][40][41][42].
In this study, a scientometric analysis was conducted on the bibliometric data regarding the utilization of agricultural wastes as building materials. A scientometric analysis was employed to address the fundamental flaws of conventional manual reviews. More precisely, the identification of sources with the greatest number of articles, co-occurrence of keywords, author collaboration, the most cited articles, and regions actively engaged in the utilization of agricultural wastes as building materials were studied.

Methodology
To complete the examination of this research, the researchers observed the articles on "agricultural wastes as building materials" distributed in the World Logical Diary through 2022 and considered their relevance. For the corresponding exploration, the relevant data sets were scrutinized from the Scopus database. A complete analysis was carried out with the whole content of the publications (articles, book chapters, and proceeding papers), involving investigations on "agricultural wastes used as building materials" and "agricultural wastes in the construction industry". In this bibliometric assessment, the segments examined were articles, authors, and references. Figure 3 displays the graphical representation of the methodology of this research. utilize various colors, shapes, and symbols to represent the relationship and its relative contribution. The number of sides represents nodes, and the thickness of the link chain represents the connectivity with the number of copies made by the researcher. Some researchers have used the VOSviewer software (version 1.6.18) to publish the bibliometric analysis results [36][37][38][39][40][41][42].
In this study, a scientometric analysis was conducted on the bibliometric data regarding the utilization of agricultural wastes as building materials. A scientometric analysis was employed to address the fundamental flaws of conventional manual reviews. More precisely, the identification of sources with the greatest number of articles, co-occurrence of keywords, author collaboration, the most cited articles, and regions actively engaged in the utilization of agricultural wastes as building materials were studied.

Methodology
To complete the examination of this research, the researchers observed the articles on "agricultural wastes as building materials" distributed in the World Logical Diary through 2022 and considered their relevance. For the corresponding exploration, the relevant data sets were scrutinized from the Scopus database. A complete analysis was carried out with the whole content of the publications (articles, book chapters, and proceeding papers), involving investigations on "agricultural wastes used as building materials" and "agricultural wastes in the construction industry". In this bibliometric assessment, the segments examined were articles, authors, and references. Figure 3 displays the graphical representation of the methodology of this research.

Data Acquisition
In this study, the data obtained from the existing literature play a pivotal role as they determine the scientific basis of the concluded results. Therefore, the database and the search system were sensibly selected. Scopus was chosen as the bibliographic database because it is comprehensive and structured, serving as a powerful source for intensive scientific research. It is the most widely used and recognized database for bibliographic

Data Acquisition
In this study, the data obtained from the existing literature play a pivotal role as they determine the scientific basis of the concluded results. Therefore, the database and the search system were sensibly selected. Scopus was chosen as the bibliographic database because it is comprehensive and structured, serving as a powerful source for intensive scientific research. It is the most widely used and recognized database for bibliographic research. Between the period of 1935-2022 with the keyword "agricultural wastes used as building materials", a total of 671 publications were retrieved from the Scopus database, including articles, conference contributions, book chapters, and books. Table 1 lists the document publication types for the same stipulated time (1935 to 2022) and indicates the language in which the articles were published. In total, 96% of the documents were published in the English language. Regarding the publication access of the articles, 74% of the articles were published as open source.

Trends in Scientific Study on Agricultural Wastes Used as Building Materials
Journal trends in "agricultural wastes used as building materials" from the year 1935 to 2022 are presented and elucidated in this section. As was mentioned, 671 published articles were obtained from this period of time. The yearly publication trend is depicted in Figure 4. Since 2004, the number of articles published on the topic has increased significantly. Every decadal year, for example, 1985 and 1995, a peak in the publication trend is observed. Despite this, the number of research articles published has steadily increased over the last four decades. From 2015 to 2020, the number of publications was seen to grow exponentially. research. Between the period of 1935-2022 with the keyword "agricultural wastes used as building materials", a total of 671 publications were retrieved from the Scopus database, including articles, conference contributions, book chapters, and books. Table 1 lists the document publication types for the same stipulated time (1935 to 2022) and indicates the language in which the articles were published. In total, 96% of the documents were published in the English language. Regarding the publication access of the articles, 74% of the articles were published as open source.

Trends in Scientific Study on Agricultural Wastes Used as Building Materials
Journal trends in "agricultural wastes used as building materials" from the year 1935 to 2022 are presented and elucidated in this section. As was mentioned, 671 published articles were obtained from this period of time. The yearly publication trend is depicted in Figure 4. Since 2004, the number of articles published on the topic has increased significantly. Every decadal year, for example, 1985 and 1995, a peak in the publication trend is observed. Despite this, the number of research articles published has steadily increased over the last four decades. From 2015 to 2020, the number of publications was seen to grow exponentially.

Analysis of Research Keywords
Existing studies and research topics are described regarding keywords [43]. A close relationship indicated between two or more keywords is stated as keyword co-occurrence. Author keywords and fractional counting are used to improve the quality of VOSviewer results [44]. This review started with a broader topic search to analyze the research trend of "agricultural wastes used as building materials". The retrieved publications were examined to see the most popular keywords associated with "agricultural wastes used as building materials". Figure 5 shows the most occurring keywords. The minimum number of cooccurrences was maintained following the default value, which was six. Maintaining this limiting condition, 35 published articles out of 671 were initially selected.

Analysis of Research Keywords
Existing studies and research topics are described regarding keywords [43]. A close relationship indicated between two or more keywords is stated as keyword co-occurrence. Author keywords and fractional counting are used to improve the quality of VOSviewer results [44]. This review started with a broader topic search to analyze the research trend of "agricultural wastes used as building materials". The retrieved publications were examined to see the most popular keywords associated with "agricultural wastes used as building materials". Figure 5 shows the most occurring keywords. The minimum number of co-occurrences was maintained following the default value, which was six. Maintaining this limiting condition, 35 published articles out of 671 were initially selected. In general, there were closer ties among the keywords in the same grouping ( Figure  5). For example, studies on agricultural wastes and compressive strength have frequently been carried out in the same publication. In Figure 5, the interconnectedness of keywords is illustrated by the distances and connection lines that connect them. The most frequently studied keywords are agricultural waste, building materials, brick, and concrete. According to the visualization of the literature samples, the average year of publication (Avg. Pub. Year), the average citation (Avg. Citation), and the average normalized citation (Avg. Norm. Citation) are further summarized in Table 2. The following information was utilized for the tabulation [45].   In general, there were closer ties among the keywords in the same grouping ( Figure 5). For example, studies on agricultural wastes and compressive strength have frequently been carried out in the same publication. In Figure 5, the interconnectedness of keywords is illustrated by the distances and connection lines that connect them. The most frequently studied keywords are agricultural waste, building materials, brick, and concrete. According to the visualization of the literature samples, the average year of publication (Avg. Pub. Year), the average citation (Avg. Citation), and the average normalized citation (Avg. Norm. Citation) are further summarized in Table 2. The following information was utilized for the tabulation [45].

Analysis of Articles' Sources
Analyzing the journal's impact in the specific field helps readers obtain the best information available and quickly identify the journals that may be best for publication [46]. The journal sources were also summarized, and the annual number of published articles are discussed here too. The minimum number of articles in VOSviewer was set to 6. Among the 394 sources identified, 18 satisfied the thresholds set and were included in the composite network. The source occurrences map is illustrated in Figure 6.   Table 3 provides a quantitative summary of the impact of the sources.

Analysis of Articles' Regions
On a minimal count, the number of countries included per document is 20. In 102 countries, each with a threshold of 13 countries, the total strength of co-production groups with other countries was calculated and the country with the highest unlimited bandwidth was selected. Figure 7 demonstrates the collective network based on the collaboration of the countries. The four groups of elements identified from the cluster network are:

•
The clustered links for Brazil, Spain, the United Kingdom, and the United States are 12 and the total link strength is 4353. This cluster collection has the most considerable number of articles (143 articles with other countries was calculated and the country with the highest unlimited bandwidth was selected. Figure 7 demonstrates the collective network based on the collaboration of the countries. The four groups of elements identified from the cluster network are: • The clustered links for Brazil, Spain, the United Kingdom, and the United States are 12 and the total link strength is 4353. This cluster collection has the most considerable number of articles (143 articles).

•
The clustered links for China, India, and Malaysia are 12 and the total link strength is 5237. This cluster collection has the most considerable number of articles (176 articles).

•
The clustered links for Germany, Russian Federation, and Thailand are 12 and the total link strength is 2395. This cluster collection has the most considerable number of articles (73 articles).

•
The clustered links for France, Italy, and Turkey are 12 and the total link strength is 4961. This cluster collection has the most considerable number of articles (86 articles).
A quantitative summary of the impact of sources, including 13 countries, is reported in Table 4. Conclusively, India and China contributed the most research on agricultural wastes being used as building materials.   A quantitative summary of the impact of sources, including 13 countries, is reported in Table 4. Conclusively, India and China contributed the most research on agricultural wastes being used as building materials.

Description of Active Research Areas: Agricultural Wastes Used as Building Materials
Wastes generated from the primary treatment of some natural and agricultural products can be important alternatives to ecological concrete production [11]. Agricultural wastes can be applied as an alternative in sheets, bricks, proof cement, wall panels, cement panels, particle boards, and insulation panels [47]. Figure 8 shows various applications of agricultural wastes as building materials.

Description of Active Research Areas: Agricultural Wastes Used as Building Materials
Wastes generated from the primary treatment of some natural and agricultural products can be important alternatives to ecological concrete production [11]. Agricultural wastes can be applied as an alternative in sheets, bricks, proof cement, wall panels, cement panels, particle boards, and insulation panels [47]. Figure 8 shows various applications of agricultural wastes as building materials.
Many studies worldwide have validated the importance of agricultural waste in considering future uses and introducing many new types of agricultural waste that can be further used. Due to their environmental friendliness and economic viability, global and affordable agricultural wastes are considered a starting point for this investigation. Amorphous silica is abundantly present in agricultural waste ash, which makes it an excellent candidate to be utilized as a pozzolanic material [48]. When researchers used agricultural waste as an alternative for 30% cement in high-strength concrete, they demonstrated that this material proves to be a potential alternate candidate that can be employed. Despite such substitutions, agricultural waste ash cement has demonstrated excellent performance in mortar and concrete even when exposed to a hydrochloric acid solution [49].

Agricultural Wastes Used in Concrete
Emphasis is placed on using agricultural-waste-incorporated cement in concrete to increase the mechanical qualities of mixed agricultural waste concrete. It is critical to understand and interpret the cost efficiency of any new technology in a sustainable building. A study in [49] examined the economics of using agricultural-waste-incorporated cement in the production of concrete. As a result, efforts should be made to find ways to incorpo- Many studies worldwide have validated the importance of agricultural waste in considering future uses and introducing many new types of agricultural waste that can be further used. Due to their environmental friendliness and economic viability, global and affordable agricultural wastes are considered a starting point for this investigation. Amorphous silica is abundantly present in agricultural waste ash, which makes it an excellent candidate to be utilized as a pozzolanic material [48]. When researchers used agricultural waste as an alternative for 30% cement in high-strength concrete, they demonstrated that this material proves to be a potential alternate candidate that can be employed. Despite such substitutions, agricultural waste ash cement has demonstrated excellent performance in mortar and concrete even when exposed to a hydrochloric acid solution [49].

Agricultural Wastes Used in Concrete
Emphasis is placed on using agricultural-waste-incorporated cement in concrete to increase the mechanical qualities of mixed agricultural waste concrete. It is critical to understand and interpret the cost efficiency of any new technology in a sustainable building. A study in [49] examined the economics of using agricultural-waste-incorporated cement in the production of concrete. As a result, efforts should be made to find ways to incorporate various agricultural wastes into concrete as sustainable materials. A review of all the available publications (articles, book chapters, and conference papers), as a result of searches on the terms "agricultural wastes" and "agricultural cement", was carried out in this investigation.
Novel residues of 100:0 (blast furnace slag/sugar cane straw ash), 85:15 (85/15), 75:25 (75/25), and 67:33 (67/33) were examined as a partial replacement for the blast furnace slag to evaluate whether the ash obtained from biomass could be used as a filler in bituminous blends. After the successful treatment, most of the examined biomass ashes were assessed and found to be environmentally friendly, with the absence of hazardous particles, making them an ideal alternative for the natural fillers in bituminous mixes. The findings also revealed that the alkaline solution affected the compressive strength development, reaching more than 60 MPa after 90 days of specimen curing. Consequently, sugar cane straw ash demonstrated favorable results as it is a viable material for alkali-activated binders [50].
There is a good chance that most of the investigated biomass ashes could be used as a natural filler in bituminous mixtures because of their low organic matter and harmful fines content [51].
Employing spectroscopic methods, the interaction between sugarcane bagasse ash (SCBA) and the brick-making clay in a brick-making process was evaluated. At temperatures between 800 and 1100 • C, brick-making clay and SCBA were mixed before being hydraulically uniaxially compressed and sintered [52].
When concrete was submerged in a 5% magnesium sulphate solution for 364 days, it was subjected to various tests to determine its qualities, such as setting time, compressive strength, and expansion owing to magnesium sulphate assault. The expansion level of the concrete bar created with 30% slag powder was the same as that of the concrete bar manufactured from Portland cement Type V. Pozzolanic material palm oil fuel ash (POFA) acted as a good substitute for cement in concrete according to the obtained results [53].
Environmental concerns such as pollution and energy usage have piqued the public's attention in recent years. The accompanying legislation has prompted the building industry to emphasize thermal insulation more. The development and implementation of bio-based insulating materials may help reduce the negative environmental impact of buildings by lowering the amount of energy utilized during the construction and operation of structures [54].
Prusty et al. [9] discussed the agricultural waste materials that can be utilized as a partial substitute for fine aggregates in concrete. It has been observed that the workability of the agricultural waste concrete, which includes groundnut shell, oyster shell, cork, rice husk ash (RHA) [55][56][57], and tobacco waste as an alternative, stood superior to that of concrete having just groundnut shell. According to the review, many significant studies are needed on all fine aggregates replacing agricultural waste materials. Nevertheless, this research provided more assurance on the utilization of concrete, which is a noteworthy discovery.
Research was done in [58] examining the durability, mechanical characteristics, global warming potential (GWP), and air pollutants of various ternary-and quaternary-RHA blended concrete mixes. As a conclusion, it was discovered that ternary and quaternary concrete mixes, including RHA and fly ash, decreased GWP while boosting durability without affecting the design strength.
Many studies have used oil palm ash in concrete, mortar, and cement paste as a pozzolanic material, either as a binder or as a filler substitute to lessen the negative environmental effect [59].
Concrete's mechanical qualities improved when SCMs such as fly ash and silica fume were utilized in ordinary Portland cement (OPC) as a partial substitute for OPC. Consequently, RHA was examined as a potential alternative solid-phase microbe SCM. Three different diameters of RHA (600 mm, 150 mm, and 44 mm) were used in conjunction with 10% and 20% partial cement replacements. In addition to RHA-modified concrete specimens, a commonly used local Class C fly ash was also included for comparison purposes [60].
Based on various alternatives to traditional SCMs, the performance and durability of recycled aggregate concrete were assessed in [61] incorporating the available industrial byproducts, including RHA, POFA/POCP, and other industrial byproducts. The compressive strength and mass change of concrete were measured based on the effects of hydrochloric acid and magnesium sulphate (MgSO 4 ).
The feasibility of recycled aggregate concrete was evaluated in [62] utilizing readily industrial byproducts such as RHA and POFA as alternatives to traditional SCMs. In addition, an investigation of the impact of compressive strength and microstructural analysis were carried out.
Magnesium oxysulfate cement (MOSC) is one of the new cements that has garnered significant interest in the cement industry in recent years. MOSC is a ternary cementing system composed of active MgO and a specific concentration of MgSO 4 solution. Low energy consumption, low thermal conductivity, and high fire resistance are the primary advantages of MOSC [63].
In recent years, many scientists have employed MOSC to recycle industrial solid wastes, such as fly ash, which have been studied extensively. Both low-and high-calcium fly ash have promising application prospects in MOSC, with a dosage that can reach up to 50% of MgO [55,64].
To improve the utilization of forestry wastes and save MgO, composites containing locust powders with 0-25% mass of MgO were mechanically mixed and cured for 3 days and 100 days. Mechanical properties, water resistance, and microstructure of the slurry were investigated. The maximum locust dosage based on fluidity was found to be 25% [56,65].
From the Scopus database, 564 articles were retrieved with the keywords "Agricultural Waste Used in Concrete". From the data analysis, the top 10 globally cited articles are reported in Table 5 with total citations (TC), TC per year, normalized TC (Norm. TC), and reference (Ref.).

Agricultural Wastes Used in Insulation
Building insulations are generally made from materials derived from petrochemicals (mostly polystyrene) and natural sources treated with high energy efficiency (glass and rock wool). Bringing "sustainability" into the design process of buildings prompted researchers to examine the development of thermal and acoustic insulating materials made from natural or recycled resources. In [76], the current state of the art was provided in the field of building insulation products made from natural or recycled materials.
Insulation materials made from natural fiber waste appeared to be an excellent alternative thanks to their abundant availability in the southern regions of Chile, potential low cost, minimal energy consumption during the manufacturing process, and high bio-degradation rate at the end of their lives. Moreover, the flexural and compressive stresses of expanded polystyrene block insulation were assessed and compared with conventional insulation. Furthermore, the flexural stress values were compared with the findings obtained from the conventional expanded polystyrene type IX and documented [77].
A scientific plan for bio-insulation research was presented as the conclusion, as well as recommendations for selecting suitable types of treatments, both traditional and innovative, for enhancing specific properties, the order in which properties should be tested along with a scientific presentation of research findings [78]. This research could precisely aid in the development of a more detailed understanding of the current state of bio-insulation research.
An environmentally acceptable method was developed for replacing cement with wood ash at 10, 15, 20, and 25%. In addition, styrene-butadiene polymers were added to increase strength and stiffness for modifying mortars. In all likelihood, by substituting cement with up to 10% wood ash, 1.5% banana fibers, and 0.3% styrene-butadiene polymer emulsion, the best performance could be achieved among other ingredients. Furthermore, according to the researchers, the composite material produced has excellent thermal insulation capabilities and may be employed in various cement-based applications [79].
From the Scopus database, 149 articles were retrieved using the keywords "Agricultural Wastes Used in Insulation". From that data analysis, the top 10 globally cited articles are reported in Table 6 with total citations (TC), TC per year, normalized TC (Norm. TC), and reference (Ref.).

Agricultural Wastes Used in Thermal Insulating Materials
From the environmental point of view, insulation serves to be very energy efficient. The expected energy has the advantage that, if it is used for construction, the required operating energy can significantly be decreased. The energy saved helps reduce the causes of environmental pollution. Table 7 represents the physical properties of boards made of recycled materials manufactured from various agricultural wastes. The waste-incorporated materials are used in the construction of floors, walls, roofs, bridges, boats, and other vessels. These building insulations are easy to handle, dust-free, and non-irritating to the skin. They also provide good thermal insulation. Table 7. Physical properties of insulation boards from agricultural wastes [89].

Agricultural Wastes Used in Mortar
The thermal advantages of cork mortars for renderings were compared with cementexpanded polystyrene mortars, specifically in steady and unsteady situations [90]. The average thermal conductivity of the mortar was reduced by over 76%, and its density was decreased by around 30% when 70% of the dry weight of the olive stone was added to the cement lime mortar. Conclusively, based on the percentage of the olive stone added, a significant decrease in the thermal conductivity was observed compared with the reduction in the density [91,92]. From the Scopus database, 149 journals were retrieved using the keyword "Agricultural Wastes Used in Mortar". From the data analysis, the top 10 globally cited articles are reported in Table 8

Microstructural Characteristics of Agricultural Waste Ash
Microstructural analysis of agricultural waste ash is essential because it can considerably affect the performance of the agricultural waste ash blended cementitious system, particularly the mechanical properties [121][122][123][124][125]. Understanding the microstructures of various types of agricultural waste ash enables one to predict the behavior of ash-concrete blends.
In the literature, micrographs of corncob ash revealed the presence of both macroand micropores. Crystalline and spherical CCA particles were also observed [126][127][128]. In addition, it was stated that coconut shell ash particles have an extremely irregular shape [129]. Nevertheless, some particles were discovered to be spherical. The scanning electronic microscopy micrograph of GNSA uncovered that its surface is irregular and porous [130]. POFA has highly porous particles, but when it is grounded, its porosity is significantly reduced [131]. In addition, it has been reported that RHA particles have an irregular shape, and it is evident from the structure of RHA that its pores vary in size from nanome-

Microstructural Characteristics of Agricultural Waste Ash
Microstructural analysis of agricultural waste ash is essential because it can considerably affect the performance of the agricultural waste ash blended cementitious system, particularly the mechanical properties [121][122][123][124][125]. Understanding the microstructures of various types of agricultural waste ash enables one to predict the behavior of ash-concrete blends.
In the literature, micrographs of corncob ash revealed the presence of both macroand micropores. Crystalline and spherical CCA particles were also observed [126][127][128]. In addition, it was stated that coconut shell ash particles have an extremely irregular shape [129]. Nevertheless, some particles were discovered to be spherical. The scanning electronic microscopy micrograph of GNSA uncovered that its surface is irregular and porous [130]. POFA has highly porous particles, but when it is grounded, its porosity is significantly reduced [131]. In addition, it has been reported that RHA particles have an irregular shape, and it is evident from the structure of RHA that its pores vary in size from nanometers to micrometers. These pores contribute to an increased RHA surface area [93,132]. In its microstructure, SCBA particles include prismatic, spherical, and fibrous particles [133]. Figure 10 displays the influence of various agricultural waste ashes on the compressive strength of blended concrete after 28 days of curing. Even though the addition of agricultural waste ashes increases the compressive strength, exceeding the optimal replacement level of cement with agricultural waste ashes decreases the compressive strength of the cementitious system. RHA-and SCBA-blended concrete had a higher normalized compressive strength than concrete blended with CCA and POFA.

Mechanical Properties of Agricultural Waste Used in Building Materials
Buildings 2023, 13, 0 17 of 28 shape [129]. Nevertheless, some particles were discovered to be spherical. The scanning electronic microscopy micrograph of GNSA uncovered that its surface is irregular and porous [130]. POFA has highly porous particles, but when it is grounded, its porosity is significantly reduced [131]. In addition, it has been reported that RHA particles have an irregular shape, and it is evident from the structure of RHA that its pores vary in size from nanometers to micrometers. These pores contribute to an increased RHA surface area [93,132]. In its microstructure, SCBA particles include prismatic, spherical, and fibrous particles [133]. Figure 10 displays the influence of various agricultural waste ashes on the compressive strength of blended concrete after 28 days of curing. Even though the addition of agricultural waste ashes increases the compressive strength, exceeding the optimal replacement level of cement with agricultural waste ashes decreases the compressive strength of the cementitious system. RHA-and SCBA-blended concrete had a higher normalized compressive strength than concrete blended with CCA and POFA.  Figure 10 displays the influence of various agricultural waste ashes on the compressive strength of blended concrete after 28 days of curing. Even though the addition of agricultural waste ashes increases the compressive strength, exceeding the optimal replacement level of cement with agricultural waste ashes decreases the compressive strength of the cementitious system. RHA-and SCBA-blended concrete had a higher normalized compressive strength than concrete blended with CCA and POFA. shape [129]. Nevertheless, some particles were discovered to be spherical. The scanning electronic microscopy micrograph of GNSA uncovered that its surface is irregular and porous [130]. POFA has highly porous particles, but when it is grounded, its porosity is significantly reduced [131]. In addition, it has been reported that RHA particles have an irregular shape, and it is evident from the structure of RHA that its pores vary in size from nanometers to micrometers. These pores contribute to an increased RHA surface area [93,132]. In its microstructure, SCBA particles include prismatic, spherical, and fibrous particles [133]. Figure 10 displays the influence of various agricultural waste ashes on the compressive strength of blended concrete after 28 days of curing. Even though the addition of agricultural waste ashes increases the compressive strength, exceeding the optimal replacement level of cement with agricultural waste ashes decreases the compressive strength of the cementitious system. RHA-and SCBA-blended concrete had a higher normalized compressive strength than concrete blended with CCA and POFA.  Figure 10 displays the influence of various agricultural waste ashes on the compressive strength of blended concrete after 28 days of curing. Even though the addition of agricultural waste ashes increases the compressive strength, exceeding the optimal replacement level of cement with agricultural waste ashes decreases the compressive strength of the cementitious system. RHA-and SCBA-blended concrete had a higher normalized compressive strength than concrete blended with CCA and POFA.   The optimal replacement level of RHA and SCBA in concrete has been determined to be between 10 and 20%. The normalized compressive strengths of RHA-and SCBAblended concrete were approximately 1.2 times that of control concrete. In addition to the 10% replacement level, 20% has been reported as the optimal replacement level for POFA in previous research works. At the optimal replacement level, the normalized compressive strengths of POFA-modified concrete ranged from 1.01 to 1.11. Normalized compressive strengths for CCA-based concrete ranged between 0.81 and 1.02 and 0.88 and 1.08 at the optimal replacement levels of 5 to 10%, respectively [156].

Research Trends and Recommendations
As a sustainable alternative building material, agricultural waste has led to relevant literature works over the past decades. Apart from the articles and technical documents, there have been many other publications and research attempts in this field. The most important building materials are sand, cement, concrete, insulators, and brick, as illustrated in Figure 11 based on their usage. Many research works have been carried out on replacing cement and concrete, and trending research is toward thermal insulation, brick, and aggregate. Technology acts as an important tool for sustainable construction. Thermal insulation is one of the most significant ways to decrease energy consumption. From the year 2008 to 2022, the total number of keyword entries found was 671 including concrete, wood, and steel [157].
10% replacement level, 20% has been reported as the optimal replacement level for POFA in previous research works. At the optimal replacement level, the normalized compressive strengths of POFA-modified concrete ranged from 1.01 to 1.11. Normalized compressive strengths for CCA-based concrete ranged between 0.81 and 1.02 and 0.88 and 1.08 at the optimal replacement levels of 5 to 10%, respectively [156].

Research Trends and Recommendations
As a sustainable alternative building material, agricultural waste has led to relevant literature works over the past decades. Apart from the articles and technical documents, there have been many other publications and research attempts in this field. The most important building materials are sand, cement, concrete, insulators, and brick, as illustrated in Figure 11 based on their usage. Many research works have been carried out on replacing cement and concrete, and trending research is toward thermal insulation, brick, and aggregate. Technology acts as an important tool for sustainable construction. Thermal insulation is one of the most significant ways to decrease energy consumption. From the year 2008 to 2022, the total number of keyword entries found was 671 including concrete, wood, and steel [157]. In agriculture, the utilization of agricultural waste products in the building materials industry helps reduce the emissions from waste storage or incineration, avoiding the excessive accumulation of waste in sanitary landfills and improving environmental quality. There is a dearth of thermal science research on agricultural waste in concrete, cement, and brick. Several researchers have employed agricultural wastes as building materials in various fields. However, agricultural wastes such as refractory bricks have not been used as building materials in various cases. Figure 12 shows the development of keywords in this research. From 1935 to 2007, the keywords connected with future work were bedding, biomass, blended cement, compressive strength, farm residue, heavy metals, and waste management. From 2008 to 2014, keywords in the research changed to agricultural wastes, biomass, recycling, compressive strength, and building materials. The indices are weighted inclusion index: 3.71, inclusion In agriculture, the utilization of agricultural waste products in the building materials industry helps reduce the emissions from waste storage or incineration, avoiding the excessive accumulation of waste in sanitary landfills and improving environmental quality. There is a dearth of thermal science research on agricultural waste in concrete, cement, and brick. Several researchers have employed agricultural wastes as building materials in various fields. However, agricultural wastes such as refractory bricks have not been used as building materials in various cases. Figure 12 shows the development of keywords in this research. From 1935 to 2007, the keywords connected with future work were bedding, biomass, blended cement, compressive strength, farm residue, heavy metals, and waste management. From 2008 to 2014, keywords in the research changed to agricultural wastes, biomass, recycling, compressive strength, and building materials. The indices are weighted inclusion index: 3.71, inclusion index: 3.70, occurrences: 17, and stability index: 1.33. In 2015-2018, keywords in the research changed to agricultural waste, thermal conductivity, thermal insulation, waste management, compressive strength, waste, rice husk, straw, building materials, bio composite, and agricultural byproducts. The indices are weighted inclusion index: 4.59, inclusion index: 4.33, occurrences: 62, and stability index: 1.38. From 2019 to 2020, keywords in the research changed to agricultural waste, straw, thermal conductivity, building materials, bio composite, agricultural byproducts, mechanical properties, and thermal insulation. The indices are weighted inclusion index: 7.44, inclusion index: 6.66, occurrences: 89, and stability index: 2.94. Finally, from 2019 to 2020, the keywords in research were agricultural byproducts, agricultural waste, RHA, and waste management. The indices are the weighted inclusion index: 1.36, inclusion index: 1.45, occurrences: 13, and stability index: 0.39. These points help us understand the connection of keywords and future words for research on these keywords. management, compressive strength, waste, rice husk, straw, building materials, bio composite, and agricultural byproducts. The indices are weighted inclusion index: 4.59, inclusion index: 4.33, occurrences: 62, and stability index: 1.38. From 2019 to 2020, keywords in the research changed to agricultural waste, straw, thermal conductivity, building materials, bio composite, agricultural byproducts, mechanical properties, and thermal insulation. The indices are weighted inclusion index: 7.44, inclusion index: 6.66, occurrences: 89, and stability index: 2.94. Finally, from 2019 to 2020, the keywords in research were agricultural byproducts, agricultural waste, RHA, and waste management. The indices are the weighted inclusion index: 1.36, inclusion index: 1.45, occurrences: 13, and stability index: 0.39. These points help us understand the connection of keywords and future words for research on these keywords.

Discussion
As was previously mentioned, a variety of operations and a wide range of sources result in enormous amounts of waste being generated. The challenges associated with disposing of waste products are illustrated by their hazardous and complex composition. These wastes could contaminate usable lands and cause problems for waste management authorities if they are dumped in landfills. The flowchart of generated agricultural wastes, their related disposal effects, and the benefits of them being used as building materials are demonstrated in Figure 13. Additionally, waste materials have a tendency to contaminate water when they come into contact with water bodies.
Moreover, a number of waste products in powder form are simple to combine with air and pollute the atmosphere. If waste is dumped close to agricultural lands, this could have an impact on cultivable lands. Therefore, it is necessary to dispose of or reuse waste materials properly because not doing so puts the natural environment and human health in danger. One of the most popular building materials is concrete. Therefore, recycling waste into concrete would be a more environmentally friendly strategy. Concrete can use

Discussion
As was previously mentioned, a variety of operations and a wide range of sources result in enormous amounts of waste being generated. The challenges associated with disposing of waste products are illustrated by their hazardous and complex composition. These wastes could contaminate usable lands and cause problems for waste management authorities if they are dumped in landfills. The flowchart of generated agricultural wastes, their related disposal effects, and the benefits of them being used as building materials are demonstrated in Figure 13. Additionally, waste materials have a tendency to contaminate water when they come into contact with water bodies.
On the other hand, several agricultural wastes (RHA, etc.) contain chemical compounds that are appropriate for SCMs. As a result, these waste materials can replace cement in concrete, which is a benefit of using waste materials in concrete. Furthermore, according to the majority of researchers, adding waste materials produces composites with better strength characteristics at a lower price. In addition, waste management issues can be resolved by reducing the amount of waste that ends up in landfills, thereby preserving the environment. Recycled aggregate concrete has comparatively weak mechanical properties due to the existence of weak bonds between the old mortar and aggregate, alongside cross cracks and fractures in the recycled aggregates developed during the recycling process. However, some improvement methods, such as adding mineral admixtures, changing the mixing process, and coating recycled aggregates with cement slurry or admixture solution, can help mitigate the strength loss caused by incorporating recycled aggregates. For the purpose of generating large quantities of recycled aggregate concrete, these processes must be further studied. Furthermore, it is important to look into the structural and material aspects of long-term durability performance.
As already mentioned, waste materials used as SCMs can possibly enhance the mechanical properties of concrete in addition to producing concrete that is more environmentally friendly. The filler effect and pozzolanic properties of SCMs enable this improvement. However, there is an optimal limit at which adding SCMs to concrete no longer improves its properties. As a result, it is still necessary to investigate how SCMs can be utilized in large quantities without losing their material properties.

Application
Sustainable development should be of particular importance as the global population increases, and the concrete industry should contribute to this development. Utilizing Moreover, a number of waste products in powder form are simple to combine with air and pollute the atmosphere. If waste is dumped close to agricultural lands, this could have an impact on cultivable lands. Therefore, it is necessary to dispose of or reuse waste materials properly because not doing so puts the natural environment and human health in danger. One of the most popular building materials is concrete. Therefore, recycling waste into concrete would be a more environmentally friendly strategy. Concrete can use a variety of waste products as natural aggregate replacements, including plastic, rubber, recycled concrete aggregate, glass, ashes, and slag.
On the other hand, several agricultural wastes (RHA, etc.) contain chemical compounds that are appropriate for SCMs. As a result, these waste materials can replace cement in concrete, which is a benefit of using waste materials in concrete. Furthermore, according to the majority of researchers, adding waste materials produces composites with better strength characteristics at a lower price. In addition, waste management issues can be resolved by reducing the amount of waste that ends up in landfills, thereby preserving the environment.
Recycled aggregate concrete has comparatively weak mechanical properties due to the existence of weak bonds between the old mortar and aggregate, alongside cross cracks and fractures in the recycled aggregates developed during the recycling process. However, some improvement methods, such as adding mineral admixtures, changing the mixing process, and coating recycled aggregates with cement slurry or admixture solution, can help mitigate the strength loss caused by incorporating recycled aggregates. For the purpose of generating large quantities of recycled aggregate concrete, these processes must be further studied. Furthermore, it is important to look into the structural and material aspects of long-term durability performance.
As already mentioned, waste materials used as SCMs can possibly enhance the mechanical properties of concrete in addition to producing concrete that is more environmentally friendly. The filler effect and pozzolanic properties of SCMs enable this improvement. However, there is an optimal limit at which adding SCMs to concrete no longer improves its properties. As a result, it is still necessary to investigate how SCMs can be utilized in large quantities without losing their material properties.

Application
Sustainable development should be of particular importance as the global population increases, and the concrete industry should contribute to this development. Utilizing byproducts and agricultural wastes in concrete is one approach. According to the studies, many agricultural wastes, such as CCA, POFA, RHA, GNSA, etc., may be used as partial replacements or additions of aggregate or cement in concrete, mortar, and brick production. These replacements can considerably contribute to the construction industry's cost-effectiveness, energy savings, and environmental impact reduction. Considering the current criteria for sustainable infrastructure and the associated environmental benefits, the use of agricultural wastes as aggregate or cement in concrete production can also contribute to the concrete industry's sustainability.

Conclusions
This study used a three-stage holistic approach to review the articles published in the "agricultural wastes used as building materials" domain over the past decades.

•
In addition to Scopus, bibliometrics was utilized to compile this review's findings. A total of 671 publications with the keywords "agricultural wastes used as building materials", "agricultural wastes used as a replacement of cement", and "agricultural wastes used as a replacement of aggregate" were found and investigated. • It was found that the journals of Building and Environment, Energy and Buildings, Journal of Cleaner Production, and Construction and Building Materials have all published research works in the field of agricultural wastes used as building materials. There was consensus that Renewable and Sustainable Energy Reviews held the most sway.

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The research communities in China, India, and Australia have all made significant contributions, and there are many active links between them. India had a considerable yearly impact. • Qualitative analysis summarized the major areas of research on agricultural wastes used as building materials and discussed existing gaps. This comprehensive review adds knowledge to the framework and direction for future research on this topic.

•
With the help of this study, researchers can identify high-impact journals or scholars, understand recent trends in research on agricultural wastes as building materials, and promote academics and related works to think creatively about incorporating new agricultural wastes as building materials.

Recommendations for Future Research Work
The following future studies are recommended based on the analysis performed in this research.

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Limited research works have been published on the use of agricultural wastes as fine aggregate in concrete. This allows for a thorough examination of the engineering characteristics of every agricultural-waste-based concrete mix and a comparison with conventional concrete.

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The majority of studies on concrete made from agricultural waste have primarily focused on compressive strength. All agricultural-waste-based concretes and their corresponding conventional concrete, however, could be studied for other properties such as tensile and flexural strengths, elastic modulus, and ultrasonic pulse velocity.

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Few durability studies on agricultural-waste-based concretes have been published. Therefore, future research on the durability characteristics of various agricultural waste concrete types can be conducted.

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Agricultural waste ash has been employed as fine aggregate in concrete in a number of research attempts. As a result, other raw agricultural wastes might be utilized in concrete to partially replace the fine aggregate and achieve the desired effects on the characteristics of concrete. • Additional studies are needed to establish the strength variations and thermal properties when using these agricultural wastes as a fine aggregate replacement in concrete.