Investigating the Retrofitting Effect of Fiber-Reinforced Plastic and Steel Mesh Casting on Unreinforced Masonry Walls

Unreinforced masonry (URM) is one of the most popular construction materials around the world, but vulnerable during earthquakes. Due to its brittle nature, the URM structures may lead to a possible collapse of the wall of a building during earthquake events causing casualties. In the current research, an attempt is made to enhance the seismic capacity of URM structures by proposing a new innovative composite material that can improve the shear strength and deformation capacity of the URM wall systems. The results revealed that the fiber-reinforced plastic having high tensile and shear stiffness can significantly increase in-plane as well as out-of-plane bending strength of the URM wall. It was recorded that the bending moment of the prism increased up to 549.5% by increasing the bending moment from 490 N*mm to 3183 N*mm per mm deflection of prism upon using glass fibers. Moreover, the ductility ratio amplified up to 5.73 times while the stiffness ratio increased up to 4.16 times with the aid of glass fibers. Since the material used in this research work is low cost, easily available, and no need for any skilled labor, which is economically good. Therefore, the URM walls retrofitted with fiber-reinforced plastic is an economical solution.


Introduction
Unreinforced masonry (URM) structures are the most favorable way of construction for human beings since far-off ages due to their resilience to environmental effects, durability as well as ease of construction. It can be seen around the world in various forms which mainly depend upon construction material availability, in different forms around the globe depending upon the availability of construction materials, the monetary condition of the area, and its local culture [1]. Placing pebbles, bricks, or blocks one above the other using any binding agent, such as mortar, is the easiest form. Blocks of concrete are the most contemporary type of construction unit, while the stone is considered the first unit used in the construction of masonry structures pursued by sun-dried and burnt clay bricks.
Nowadays, the utmost number of unreinforced masonry structures are constructed without considering any seismic resistance features, especially in rural areas [2]. On the other side, it has been observed from the recent earthquake around the globe that masonry structures are highly seismic vulnerable [3]. A devastating earthquake having a magnitude of 7.6 caused more than 73,000 fatalities, injuring about 70,000 local residents and ultimately affecting 3.5 million people in the northwest region of Pakistan, specifically Kashmir [4]. The Asian Development Bank and World Bank Report [ADB- WB 2005] show that the earthquake devastated around 203,579 residential units and damaged 196,574 other facilities [5]. Since the damaged buildings suffered during the earthquake consist of stone and brick masonry constructions [6]. Therefore, it is necessary to improve the seismic performance of unreinforced masonry buildings by retrofitting or rehabilitation.
An earthquake triggers various types of structural damage in masonry structures [7]. Various aspect of different types of damages generated by an earthquake in a masonry structure has been summarized in a technical report prepared by The Applied Technology Council [8]. Reconstruction of the affected facility due to an earthquake is very expensive, causing substantial economic loss. For this reason, retrofitting the affected building is considered the most economical solution and recommended alternative to mitigating the associated seismic risk [9]. Several conventional techniques, such as ferrocement overlay [10], grout injection [11], reinforced concrete jacketing [12], application of steel elements [13], bed joint reinforcement [14], polypropylene band [15], etc., and modern techniques such as the application of fiber-reinforced plastic [16], center core technique [17], and post-tensioning [18] are currently being used around the globe for retrofitting and rehabilitation of masonry structures [19]. However, non-conventional techniques are costly and require special materials and technologies [20]. To cope with this situation, a thorough literature survey about several retrofitting methods, and glass fiber retrofitting techniques were selected for this particular research. The availability of local materials and skilled labor was one of the main criteria for selecting this technique. This study focuses on comparing unreinforced masonry structures retrofitted with glass fibers. The primary objective of the research study is to investigate the strength, stiffness, and durability of unreinforced masonry walls utilizing glass fiber retrofitting techniques.
Several research works have investigated the stability of unreinforced masonry walls and retrofitted masonry walls under static and dynamic loading conditions [21]. Elgawady et al. [22] performed experimentation on unreinforced masonry walls, which are retrofitted with shotcrete overlay. Three prototype masonry walls by means of half-scale clay bricks and the required amount of mortar were made. Keeping one of them as a controlled unit, the performance of shotcrete layer thickness has been assessed using the remaining two walls by retrofitting one wall with a single-sided 40 mm dense shotcrete layer and providing a 30 mm layer on both sides of the other wall. The results reveal that the lateral load strength of the tested wall increased by three while providing shotcrete layers on both sides, enhancing the ductile failure. Adopting the same technique, Lawrence F. Kahn [23] prepared fifteen three square feet (91.44 cm × 91.44 cm) and four square feet (121.92 cm × 121.92 cm) brick masonry panels and retrofitted them with 3.5 inches of reinforced shotcrete layer. Exposing the panels to the diagonal tension test, he observed a 6 to 25 times increased ultimate load. Sivaraj et al. [24] experimentally investigated the out-of-plane shear behavior of two types of masonry wall: a controlled burned clay brick masonry wall strengthened with glass fiber-reinforced polymers (GFRP) glued externally. It has been observed from the failure mode on the wall that GFRP reasonably controls the impact of an earthquake. Thus, several attempts have been made to control the damage to the masonry walls; however, the seismic performance of the URM still needs proper attention. This research focuses on the shear strength and deformation capacity of the URM wall systems retrofitted with glass fiber and ferrocement strips. For this purpose, a prism of a specific size is constructed and tested through compressive strength, flexural strength, and diagonal tension tests. The results obtained indicated significant improvement of the URM retrofitted walls, highlighting the applications of glass fiber and ferrocement.

Preparing Prisms for Testing
All the casted prisms have dimension of 228.6 mm thickness, 609.6 mm height, and 609.6 mm length. A motor paste was prepared using 1:4 (cement:sand). A wooden base having a dimension equal to 762 mm × 304.8 mm (length × width) has been used to Materials 2023, 16, 257 3 of 13 construct a prism. First-class bricks and the above-mentioned materials were used to construct prism adopting the English bond of bricks.

Glass Fiber Sample
Seven samples out of twenty-one samples were coated with glass fiber. Glass fiber sheet was prepared locally and then cut into strips of dimension 609.6 mm (2ft) in length and 50.8 mm (2 inches) wide and then fixed on the wall with screw and steel washer and also the specified bonding solution was sprayed before fixing the strips for a proper joint with the wall as shown in Figure 1a.
All the casted prisms have dimension of 228.6 mm thickness, 609.6 mm h 609.6 mm length. A motor paste was prepared using 1:4 (cement: sand). A wo having a dimension equal to 762 mm × 304.8 mm (length × width) has been u struct a prism. First-class bricks and the above-mentioned materials were us struct prism adopting the English bond of bricks.

Glass Fiber Sample
Seven samples out of twenty-one samples were coated with glass fiber. sheet was prepared locally and then cut into strips of dimension 609.6 mm (2f and 50.8 mm (2 inches) wide and then fixed on the wall with screw and steel w also the specified bonding solution was sprayed before fixing the strips for a p with the wall as shown in Figure 1a. These samples were fitted so that a 50.8 mm gap was fixed between each strip; also, at the ends of the wall (228.6 mm thick), glass fiber strip was coate nuity purposes as shown in Figure 1a.

Ferrocement Strip Samples Casting
Out of twenty-one, seven samples were plastered with wire mesh used (d The wire mesh was cut in 50.8 mm thickness and 304.8 mm in length, as show 1b, and then was fitted on brick masonry with screw and steel washer in such each strip was fixed on the wall with 50.8 mm gap between two successive st samples were then plastered in 1:3 (cement: sand) and then cured.

Compressive Strength Test of Brick
The compressive load-bearing capacity of bricks used in the tested prism investigated, following the guidelines of ASTM C67 [25]. According to the pr capping has been provided using cement sand mortar to fill frogged bricks uniform loading. A universal testing machine (UTM) (UH-200A Shimadzu, Ky was utilized to investigate the compression capacity of bricks by applying th sion load on the bed (228.6 × 228.6 mm 2 ) of the brick. These samples were fitted so that a 50.8 mm gap was fixed between each successive strip; also, at the ends of the wall (228.6 mm thick), glass fiber strip was coated for continuity purposes as shown in Figure 1a.

Ferrocement Strip Samples Casting
Out of twenty-one, seven samples were plastered with wire mesh used (dimension). The wire mesh was cut in 50.8 mm thickness and 304.8 mm in length, as shown in Figure 1b, and then was fitted on brick masonry with screw and steel washer in such a way that each strip was fixed on the wall with 50.8 mm gap between two successive strips. These samples were then plastered in 1:3 (cement:sand) and then cured.

Compressive Strength Test of Brick
The compressive load-bearing capacity of bricks used in the tested prism has been investigated, following the guidelines of ASTM C67 [25]. According to the prescription, capping has been provided using cement sand mortar to fill frogged bricks and allow uniform loading. A universal testing machine (UTM) (UH-200A Shimadzu, Kyoto, Japan) was utilized to investigate the compression capacity of bricks by applying the compression load on the bed (228.6 × 228.6 mm 2 ) of the brick.

Prism Flexure Test
The out-of-plane strength of the prism has been investigated following the guidelines of ASTMC78/C78-M18 [26]. Six samples having dimensions 0.609 m × 0.609 m (2ft × 2ft) with 228.6 mm (9 inches) thick prism were tested in flexure. A controlled sample and two prisms retrofitted with glass fiber retrofitted were tested. The test was conducted in such a way that the prism was supported by two steel rods, each having a 50.8 mm (2 inches) diameter and 609.6 mm (2 ft) length separated at a 508 mm (20 inches) distance. The vertical force was applied at the center of a steel road placed in the middle of a prism using a hydraulic loading jack having a capacity of 200 kN (20 tons) as shown in Figure 2a. Rubber pads having a thickness equal to 12.7 (0.5 inches) were placed beneath each steel rod to ensure uniform distribution of stresses, avoiding stress concentration and local failure.
Materials 2023, 16,257 4 of with 228.6 mm (9 inches) thick prism were tested in flexure. A controlled sample and tw prisms retrofitted with glass fiber retrofitted were tested. The test was conducted in suc a way that the prism was supported by two steel rods, each having a 50.8 mm (2 inche diameter and 609.6 mm (2 ft) length separated at a 508 mm (20 inches) distance. The ve tical force was applied at the center of a steel road placed in the middle of a prism usin a hydraulic loading jack having a capacity of 200 kN (20 tons) as shown in Figure 2a. Ru ber pads having a thickness equal to 12.7 (0.5 inches) were placed beneath each steel ro to ensure uniform distribution of stresses, avoiding stress concentration and local failur The testing was carried out in a movable straining frame allowing movement in th horizontal direction and applying vertical load through hydraulic jacks. Firstly, the pris was placed on supports of steel rods while the hydraulic jacks were set on the center the prism. In order to record the real-time load, a data logger (UCAM-70A; Kyowa, Japa was connected to the calibrated cell as well as a displacement sensor was used to recor the vertical displacement of the prism, as shown in Figure 2b. The testing was carried out in a movable straining frame allowing movement in the horizontal direction and applying vertical load through hydraulic jacks. Firstly, the prism was placed on supports of steel rods while the hydraulic jacks were set on the center of the prism. In order to record the real-time load, a data logger (UCAM-70A; Kyowa, Japan) was connected to the calibrated cell as well as a displacement sensor was used to record the vertical displacement of the prism, as shown in Figure 2b.

Prism Diagonal Compression Test
This test was carried out according to the ASTM E519/E510-10 [27]. The objective/goal of the test was to find out the tensile capacity, shear stress, shear strain, and shear modulus of the samples. The dimension of the sample that was used was 609.6 mm in length, 609.6 mm in width, and 2743.2 mm in thickness. A total of 9 specimens were made and then 6 of them were retrofitted because of the local failure in the specimens.
To record the horizontal lengthening and vertical shortening of the prism two displacement sensors were installed in the diagonal direction having an average gauge length of 490 mm. Load cell was also installed at the top of the shoe of the sample. Load cell and displacement sensors (Kanetec Peacock, Japan) were then connected to the data logger for the data record. Vertical load causes shear stress in the sample. The diagonal tension test setup is shown in Figure 3. mm in width, and 2743.2 mm in thickness. A total of 9 specimens were made and then 6 of them were retrofitted because of the local failure in the specimens.
To record the horizontal lengthening and vertical shortening of the prism two displacement sensors were installed in the diagonal direction having an average gauge length of 490 mm. Load cell was also installed at the top of the shoe of the sample. Load cell and displacement sensors (Kanetec Peacock, Japan) were then connected to the data logger for the data record. Vertical load causes shear stress in the sample. The diagonal tension test setup is shown in Figure 3.

Compressive Strength Test of Prism
The compression test of samples was carried out in accordance with ASTM E447-74 [28]. The dimension of the compression specimen was 609.6 mm in length, 609.6 mm in width, and 2743.2 mm in thickness. A total of three compression samples were constructed. All compression specimens were tested after 28 days. The compression specimens of samples were tested under uni-axial compressive loading till failure as shown in Figure 4a,b. The compressive strength for all compression specimens of samples' compressive stresses was calculated by dividing the peak load by the area exposed to the load.

Compressive Strength Test of Prism
The compression test of samples was carried out in accordance with ASTM E447-74 [28]. The dimension of the compression specimen was 609.6 mm in length, 609.6 mm in width, and 2743.2 mm in thickness. A total of three compression samples were constructed. All compression specimens were tested after 28 days. The compression specimens of samples were tested under uni-axial compressive loading till failure as shown in Figure 4a,b. The compressive strength for all compression specimens of samples' compressive stresses was calculated by dividing the peak load by the area exposed to the load.  Compression test of samples was carried out in universal testing machine (UTM) having 200 tons load capacity. Two displacement sensors were installed, one in the front of the specimen and one in the back of the compression specimen of samples. The compressive strength of masonry was calculated by dividing peak vertical load by the cross- Compression test of samples was carried out in universal testing machine (UTM) having 200 tons load capacity. Two displacement sensors were installed, one in the front of the specimen and one in the back of the compression specimen of samples. The compressive strength of masonry was calculated by dividing peak vertical load by the cross-sectional area of a prism. Modulus of elasticity was calculated from the stress-strain curve as a secant modulus between two points corresponding to 1/20th and 1/3rd of the peak vertical stress.

Brick Compression Strength
The compression capacity of three days cured bricks used in the construction of the test prism is illustrated in Figure 5. It can be seen in Table 1 that the mean strength of three randomly taken bricks is about 12,064.37 kN/m 2 . Moreover, it has been learned that the average strength of middle to high-class bricks ranges from 10,342.14-13,789.51 kN/m 2 [29]. Therefore, it can be stated that middle to high-class bricks was used in the assessment of unreinforced masonry wall retrofitting using glass fibers. Compression test of samples was carried out in universal testing machine (UTM) having 200 tons load capacity. Two displacement sensors were installed, one in the front of the specimen and one in the back of the compression specimen of samples. The compressive strength of masonry was calculated by dividing peak vertical load by the crosssectional area of a prism. Modulus of elasticity was calculated from the stress-strain curve as a secant modulus between two points corresponding to 1/20 th and 1/3 rd of the peak vertical stress.

Brick Compression Strength
The compression capacity of three days cured bricks used in the construction of the test prism is illustrated in Figure 5. It can be seen in Table 1 that the mean strength of three randomly taken bricks is about 12,064.37 kN/m 2 . Moreover, it has been learned that the average strength of middle to high-class bricks ranges from 10,342.14-13,789.51 kN/m 2 [29]. Therefore, it can be stated that middle to high-class bricks was used in the assessment of unreinforced masonry wall retrofitting using glass fibers.

Prism Flexural Strength Adopting Bilinear Idealization Approach
Load displacement bilinear idealization is based on the envelope curve of loaddisplacement response, identifying the transition behavior of a structure from elastic to inelastic deformation [30]. Reviewing the existing idealized bilinear methods for various nonlinear testing data interpretation procedures [31], the author decided to utilize it for the unreinforced masonry prism retrofitted by glass fiber. Figure 6 illustrates the bilinear idealization of an elasto-plastic behavior of a structure, assuming that area under the bilinear curve is equivalent to the area below the curve.
Load displacement bilinear idealization is based on the envelope curve of load-displacement response, identifying the transition behavior of a structure from elastic to inelastic deformation [30]. Reviewing the existing idealized bilinear methods for various nonlinear testing data interpretation procedures [31], the author decided to utilize it for the unreinforced masonry prism retrofitted by glass fiber. Figure 6 illustrates the bilinear idealization of an elasto-plastic behavior of a structure, assuming that area under the bilinear curve is equivalent to the area below the curve. Additionally, the straight line between 0.0 to 0.4 Pu defines initial stiffness while the maximum deformation (post-peak displacement) occurred at a 20% reduction of Pu. Moreover, Py (yield load) can be obtained using Equation (1) [32].
where Py is the yield load, Δ failure represents the deformation at failure, fa ilu re w which indicates the energy dissipated until failure occurs. The load-taking capacity, as well as the bending moment of the prism using glass fiber, were assessed. The bending moment capacity of two tested prisms is shown in Figure 7. It can be observed that one prism (GF1) attains a maximum bending moment of 3166.67 N-mm with a maximum deformation of 11.55 mm. While the other prism (GF2) reaches the highest value of bending moment, up to 3184.72 N-mm with deformation of 8.98 mm. According to the Australian masonry code (AS3700), the permissible flexural strength of the unreinforced masonry wall is about 200 N-mm. It can be observed that both the prism retrofitted with glass fiber satisfies the minimum permissible strength criteria due to the higher bending capacity caused by the glass fiber confinement [33]. Similar studies have been reported by Messali et al. [34]. Moreover, Kalali and Kabir [35] have proved that glass fiber significantly reduces the seismic risk of the masonry wall by increasing the bending capacity and ductility. Additionally, the straight line between 0.0 to 0.4 P u defines initial stiffness while the maximum deformation (post-peak displacement) occurred at a 20% reduction of P u . Moreover, P y (yield load) can be obtained using Equation (1) [32].
where P y is the yield load, ∆ failure represents the deformation at failure, w f ailure which indicates the energy dissipated until failure occurs. The load-taking capacity, as well as the bending moment of the prism using glass fiber, were assessed. The bending moment capacity of two tested prisms is shown in Figure 7. It can be observed that one prism (GF1) attains a maximum bending moment of 3166.67 N-mm with a maximum deformation of 11.55 mm. While the other prism (GF2) reaches the highest value of bending moment, up to 3184.72 N-mm with deformation of 8.98 mm. According to the Australian masonry code (AS3700), the permissible flexural strength of the unreinforced masonry wall is about 200 N-mm. It can be observed that both the prism retrofitted with glass fiber satisfies the minimum permissible strength criteria due to the higher bending capacity caused by the glass fiber confinement [33]. Similar studies have been reported by Messali et al. [34]. Moreover, Kalali and Kabir [35] have proved that glass fiber significantly reduces the seismic risk of the masonry wall by increasing the bending capacity and ductility.  Figure 8 illustrates the load-displacement curve of the two tested prisms and their corresponding bilinear idealized curves. It is evident from the idealized bilinear curve that the glass fiber retrofitted prism possesses considerable load-bearing capacity in inelastic deformation zone. It indicates that glass fiber increases the ductile behavior of the unreinforced masonry wall (URM). D. P. Abrams [36] claimed similar findings for the unreinforced masonry walls. All the characteristics and parameters of the idealized bilinear envelope are shown in Table 2.  forced masonry wall (URM). D.P. Abrams [36] claimed similar findings for the unreinforced masonry walls. All the characteristics and parameters of the idealized bilinear envelope are shown in Table 2. Figure 7. Graph between bending moment and deformation of glass fiber coated samples. Figure 8 illustrates the load-displacement curve of the two tested prisms and th corresponding bilinear idealized curves. It is evident from the idealized bilinear curve th the glass fiber retrofitted prism possesses considerable load-bearing capacity in inelas deformation zone. It indicates that glass fiber increases the ductile behavior of the un inforced masonry wall (URM). D. P. Abrams [36] claimed similar findings for the unre forced masonry walls. All the characteristics and parameters of the idealized bilinear e velope are shown in Table 2.

Stiffness and Ductility of Prisms
Stiffness and ductility are the two parameters often used to assess the out-of-pla failure of unreinforced masonry walls [37]. Stiffness indicates the ability of a structure withstand external loading in an elastic region, while ductility reflects the ability o

Stiffness and Ductility of Prisms
Stiffness and ductility are the two parameters often used to assess the out-of-plane failure of unreinforced masonry walls [37]. Stiffness indicates the ability of a structure to withstand external loading in an elastic region, while ductility reflects the ability of a structure to experience inelastic deformation without significant loss is worth deriving [38]. Ductility can be defined in many ways depending on the parameter under consideration. According to the definition of ductility stated in ASTM E-2126, the ratio of ultimate displacement (∆ u ) at 80% of the peak load to the displacement (∆ yield ) at yield limit state (P yield ) [39]. It can be expressed mathematically by Equation (2).
Comparing the stiffness of the control prism coated with ferrocement and glass fiber, it can be witnessed from Figure 9 that the stiffness ratio increased up to 12.93 times using ferrocement and 4.16 times using glass fiber. The lower stiffness of the glass fiber retrofitted prism compared to ferrocement is due to the stretchable nature of the glass fiber strips yielding higher ultimate strength as evidenced by Kalali and Kabir [35], while the higher stiffness ferrocement-coated prism indicates brittle nature depreciated in earthquakeprone zones [40].
The ductility ratio of the glass fiber-coated prism is 5.73 times greater than the controlled one, while the ferrocement-coated prism enhances ductility up to 0.75 times, as shown in Figure 10. The higher ductility exhibited by the glass fiber is due to its stretchable nature as evidenced by Kalali and Kabir [35]. Therefore, the enhanced results of using glass fiber coating have proven its feasibility in retrofitting unreinforced masonry walls. it can be witnessed from Figure 9 that the stiffness ratio increased up to 12.93 times using ferrocement and 4.16 times using glass fiber. The lower stiffness of the glass fiber retrofitted prism compared to ferrocement is due to the stretchable nature of the glass fiber strips yielding higher ultimate strength as evidenced by Kalali and Kabir [35], while the higher stiffness ferrocement-coated prism indicates brittle nature depreciated in earthquakeprone zones [40]. The ductility ratio of the glass fiber-coated prism is 5.73 times greater than the controlled one, while the ferrocement-coated prism enhances ductility up to 0.75 times, as shown in Figure 10. The higher ductility exhibited by the glass fiber is due to its stretchable nature as evidenced by Kalali and Kabir [35]. Therefore, the enhanced results of using glass fiber coating have proven its feasibility in retrofitting unreinforced masonry walls.  The ductility ratio of the glass fiber-coated prism is 5.73 times greater than the controlled one, while the ferrocement-coated prism enhances ductility up to 0.75 times, as shown in Figure 10. The higher ductility exhibited by the glass fiber is due to its stretchable nature as evidenced by Kalali and Kabir [35]. Therefore, the enhanced results of using glass fiber coating have proven its feasibility in retrofitting unreinforced masonry walls.

Elastic Modulus (E) of Prisms
The elastic modulus is a ratio between stress and corresponding strain while the stress should be below the proportional limit. It measures the rigidity and stiffness of a material. In terms of the stress-strain curve, the slope of the curve in the range of proportional limit is the modulus of elasticity.
The ASTM E447-74 [28] was used to evaluate the elastic modulus, and the secant modulus was utilized to determine the value based on the peak vertical stress of 1/20th and 1/3 peak. Figure 11 and Table 3 present the results of the controlled sample (CS), prism coated with glass fiber (GF), and ferrocement (FCS). The modulus of elasticity of the CS is 1.64 MPa, while that of GF and FCS is 2.28 MPa and 2.48 MPa. The percent increase in the modulus of elasticity of FCS and GF as compared to CS is 71.45% and 59.68%, respectively. The confining effect caused by the ferrocement and anchorage properties provided by the glass fiber noticeably increases the elastic properties of the coated prism [41]. modulus was utilized to determine the value based on the peak vertical stress of 1/20th and 1/3 peak. Figure 11 and Table 3 present the results of the controlled sample (CS), prism coated with glass fiber (GF), and ferrocement (FCS). The modulus of elasticity of the CS is 1.64 MPa, while that of GF and FCS is 2.28 MPa and 2.48 MPa. The percent increase in the modulus of elasticity of FCS and GF as compared to CS is 71.45% and 59.68%, respectively. The confining effect caused by the ferrocement and anchorage properties provided by the glass fiber noticeably increases the elastic properties of the coated prism [41].

Shear Modulus (G) of Prisms
The shear modulus, often denoted by G is a measurement of the prism's rigidity and it is calculated from the ratio of shear stress to shear strain.
The shear strength, corresponding strain, and shear modulus are presented in Table  4. The shear modulus of CS is given as 275 MPa, while that of GF and FCS is 227.3 MPa and 393.86 MPa. The shear modulus values were obtained from the stress strain curves shown in Figure 12, Figure 13 and Figure 14. The percent increase in the shear modulus of FCS as compared to CS was 43.22%, while a 16.25% decrease was observed in GF. The increase in the shear modulus of FCS is attributed to the combined effect of steel fiber and ferrocement overlay.

Shear Modulus (G) of Prisms
The shear modulus, often denoted by G is a measurement of the prism's rigidity and it is calculated from the ratio of shear stress to shear strain.
The shear strength, corresponding strain, and shear modulus are presented in Table 4. The shear modulus of CS is given as 275 MPa, while that of GF and FCS is 227.3 MPa and 393.86 MPa. The shear modulus values were obtained from the stress strain curves shown in Figures 12-14. The percent increase in the shear modulus of FCS as compared to CS was 43.22%, while a 16.25% decrease was observed in GF. The increase in the shear modulus of FCS is attributed to the combined effect of steel fiber and ferrocement overlay.

Conclusions
The feasibility of utilizing glass fiber as a means of retrofitting material in unreinforced brick masonry (URM) walls has been investigated in this research. The flexural strength of the brick's prism was investigated along with the ductility and stiffness ratio. The following conclusions can be stated from the results.

•
A significant increase has been observed in the bending moment of prism utilizing glass fiber. It can be seen that the bending moment of a controlled specimen is about 490 N*mm/mm while it raised to 3183 N*mm/mm (average bending moment of two prisms) by means of glass fibers.

•
The ultimate load-bearing capacity of a prism using glass fibers has been increased considerably along with the ductility and stiffness ratios. It can be observed that the ductility ratio amplified up to 5.73 times while the stiffness ratio increased up to 4.16 times with the aid of glass fibers. • It has been observed from the failure pattern that glass fibers de-nailed firstly followed by the cracking of the brick prism.
Based on the results obtained, it is clear that retrofitting with glass fiber and ferrocement significantly enhances the performance of the URM which is an economical solution. In addition, it is recommended for future work to assess the seismic performance of the URM walls retrofitted with glass fiber and ferrocement.