Effect of volcanic tuff on the characteristics of cement mortar

Al-Zou'by, Jehad; Al-Zboon, Kamel K.

doi:10.1590/S0366-69132014000200018

Abstracts

This paper examines how Jordanian volcanic tuff aggregates affect the characteristics of cement mortar. Five mortar mixes were prepared by replacing normal aggregate (standard sand) with volcanic tuff aggregate in ratios of 0, 25, 50, 75, and 100% (M1 to M5, respectively). Compressive strength, flexural strength, and unit weight were tested at mortar ages of 3, 7, 28, and 56 days. The results revealed improved compressive and flexural strength, which were maximal for the M3 sample. Unit weight decreased as the ratio of volcanic tuff increased. Based on these results, adding Jordanian volcanic tuff in the appropriate ratio will improve these mortar characteristics.

compression; flexure; Jordan; mortar; volcanic tuff

Este artigo examina como agregados de tufos vulcânicos jordanianos afetam as características de argamassas de concreto. Cinco misturas de argamassas foram preparadas substituindo o agregado normal (areia padrão) com agregados de tufos vulcânicos nas proporções 0, 25, 50, 75, e 100% (M1 a M5, respectivamente). Resistência à tração, resistência à flexão, e peso unitário foram testados para tempos de argamassa 3, 7, 28, e 56 dias. Os resultados mostram melhoria nas resistências à tração e à flexão, com valores máximos para a amostra M3. O valor do peso unitário diminuiu com o aumento da proporção de argamassa vulcânica. Portanto, a adição de argamassa vulcânica jordaniana na proporção adequada melhora as características da argamassa.

compressão; flexão; Jordânia; argamassa; tufo vulcânico

Effect of volcanic tuff on the characteristics of cement mortar

Efeito de tufos vulcânicos nas características da argamassa de concreto

Jehad Al-Zou'by; Kamel K. Al-Zboon

Al-Huson University College, Al-Balqa' Applied University, Environmental Department, alzboon@bau.edu.jo

ABSTRACT

This paper examines how Jordanian volcanic tuff aggregates affect the characteristics of cement mortar. Five mortar mixes were prepared by replacing normal aggregate (standard sand) with volcanic tuff aggregate in ratios of 0, 25, 50, 75, and 100% (M1 to M5, respectively). Compressive strength, flexural strength, and unit weight were tested at mortar ages of 3, 7, 28, and 56 days. The results revealed improved compressive and flexural strength, which were maximal for the M3 sample. Unit weight decreased as the ratio of volcanic tuff increased. Based on these results, adding Jordanian volcanic tuff in the appropriate ratio will improve these mortar characteristics.

Keywords: compression, flexure, Jordan, mortar, volcanic tuff.

RESUMO

Este artigo examina como agregados de tufos vulcânicos jordanianos afetam as características de argamassas de concreto. Cinco misturas de argamassas foram preparadas substituindo o agregado normal (areia padrão) com agregados de tufos vulcânicos nas proporções 0, 25, 50, 75, e 100% (M1 a M5, respectivamente). Resistência à tração, resistência à flexão, e peso unitário foram testados para tempos de argamassa 3, 7, 28, e 56 dias. Os resultados mostram melhoria nas resistências à tração e à flexão, com valores máximos para a amostra M3. O valor do peso unitário diminuiu com o aumento da proporção de argamassa vulcânica. Portanto, a adição de argamassa vulcânica jordaniana na proporção adequada melhora as características da argamassa.

Palavras-chave: compressão, flexão, Jordânia, argamassa, tufo vulcânico.

INTRODUCTION

Mortar is a workable paste typically made from a mixture of fine aggregate, a binder such as cement or lime, and water. Mortar becomes hard when it sets, resulting in a rigid aggregate structure. It is used in masonry to bind bricks and stones, to provide an even bed between joints, and to plaster and point exposed masonry surfaces. Mortar in a thin liquid form (grout) is used to fill empty joints in masonry, to stabilize soil, to solidify porous rock, to make cast-in-situ reinforced concrete membranes, and has many other uses [1].

The first zeolite (phillipsite) deposit was discovered in Jordan in 1987, in the Quaternary volcanic tuff of the Jabal Al Aritayn Volcano in northeast Jordan. In 1996, six localities with zeolite deposits were discovered in the volcanic tuff outcrops in northeast Jordan. According to Natural Resources Authority (NRA) estimates, the reserves of volcanic tuff in Jordan exceed two billion tons [2].

The advantages of volcanic tuff include its highly porous structure, high surface area, and low density. It is available in different types, sizes, and colors, and can reduce concrete dead weight. Similar to other pozzolanic material, such as silica fumes and fly ash, substitution with zeolite can improve the strength of concrete via the pozzolanic reaction with Ca(OH)₂ [3]. It can prevent the bleeding, segregation, and delamination of fresh concrete, facilitate pumping processes, decrease the permeability of hardened concrete, enhance durability (especially resistance to alkali-aggregate reactions), increase concrete strength, and minimize the cracking in concrete caused by self-shrinkage [4].

Many recent studies have examined the feasibility of using volcanic tuff as lightweight aggregate, building stone, and pozzolans in cements and concretes [5-14]. The US Department of the Interior Bureau of Reclamation studied the physical and chemical properties of several types of light-weight aggregate, including volcanic tuff (scoria and pumice) [14]. The results verified the feasibility of using such aggregates to produce lightweight concrete. They also used scoria and some expanded slags to produce lightweight concrete with intermediate compressive strength, variable workability, and very satisfactory light-weights ranging from 90 to 110 pounds per cubic foot [14]. Authors investigated the properties of volcanic tuff sand and checked its suitability for use in mortar mixes [8]. Their results indicated that volcanic tuff sand increased mortar adhesion, bonding strength, and durability. Authors reported the physical and mechanical properties of yellow volcanic tuff found in Europe [15]. Authors examined how volcanic tuff aggregates affect the unit weight and strength of concrete, and found that unit weight and strength were reduced as the percentage of volcanic tuff increased [11]. Authors reported the addition of 9, 14, 15 wt.% Afyon Volcanic Tuff (AVT) to a standard wall tile body and found that it could be used successfully to produce wall tiles [9]. The alkaline properties, viscosity, water absorption, and compressive strength of specimens are slightly affected by adding AVT. Authors reported the use of volcanic tuff and other materials to form a composite for masonry blocks [16].

Therefore, this study aims to evaluate how raw volcanic tuff affects the characteristics of cement mortar using different ratios of normal to volcanic tuff aggregates, with a constant water to cement ratio.

MATERIALS AND METHODS

Materials: 12 m³ of raw volcanic (red tuff) was obtained from Jabal Artin, southeastern Jordan. The required quantity was crushed, sieved, and separated into sizes that met the specifications of standard sand (ASTM C778), with sieve numbers 16, 20, 50, 30, 40, and 100. Normal sand was sieved into similar sizes as the volcanic sample. The specific gravity and absorption of the sand were determined according to ASTM C128. The unit weight was determined in accordance with ASTM C29. The chemical composition of the tuff sand was determined using X-ray diffraction (XRD) and X-ray fluorescence (XRF), and is shown in Tables I and ^II, respectively. The cement used in this study was ordinary Portland cement type I.

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Batching: according to ASTM C109, the proportions of materials for standard mortar should be 1 part of cement to 2.75 parts of graded standard sand by weight and a water-cement ratio of 0.485 for all Portland cements [17]. To investigate how tuff sand affected the mortar characteristics, five mortar batches were prepared in accordance with ASTM C305. A mechanical mixer with a controlled mixing speed and mixing time was used for this purpose. The required standard sand was replaced by similar weights of tuff sand in proportions of 0, 25, 50, 75, and 100%, as shown in Table III. Both the standard sand and tuff sand were in a saturated surface dry condition.

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Molding and curing: molding of specimens to determine their compressive and flexural strength was begun after the completion of batching, in accordance with ASTM C109 and ASTM C348, respectively. Table IV lists the dimensions and numbers of specimens for each batch. All molding requirements (e.g., mold preparation, mortar layers, tamping, mixing speed, and timing) were considered. Immediately upon the completion of molding, the test specimens were placed in a moist room with their upper surfaces exposed. After 24 h, the specimens were cured in a water bath constructed of non-corroding materials at room temperature for periods of 3, 7, 28, and 56 days.

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Mechanical properties: after the curing period the specimens were removed from the baths, wiped to give a dry surface, and any loose sand, grains, or incrustations were cleaned from the faces so that they would not prevent contact with the bearing blocks of the testing machine [17]. All samples were sent to the laboratory and tested within 1 h. For the compression strength test, a constant loading was applied on the specimen in the range of 200-400 lbs/s (900-1800 N/s). Compression strength was calculated as follows:

where F_m is the compressive strength in MPa, P is total maximum load in N, and A is the area of loaded surface in mm².

For the flexural strength test, a center-point loading machine was used; its bearing edge was adjusted so that it was at exactly right angles to the length of the prism and parallel to its top face as placed, with the center of the bearing edge directly above the center line of the prism and at the center of the span length. The load was applied at a rate of 600-625 lb/min (2640-2750 N/min), which produced failure in an average time of 50 s. The flexural strength, Fr, in MPa can be calculated as:

where P is the total maximum load in N.

RESULTS AND DISCUSSION

Physical and chemical characteristics: the physical properties of the volcanic tuff sand were investigated in accordance with ASTM C128. Compared with standard sand, the volcanic tuff had a lighter specific gravity, which proved its useful for producing lightweight concrete. It absorbed more water (12.7%) than standard sand (0.65%), which was attributed to the high surface area and porosity. It has been reported that the water absorption of Jordanian tuff ranged from 11.1% (grey tuff) to 25.1% (brown tuff) [18]. Chemically, the volcanic tuff consisted mainly of silica, lime, and other oxides, while 99.5% of the standard sand was SiO₂. Similar results have been reported by other researchers. The physical and mechanical properties of tuff widely vary according to the quarry location and type of rocks [19].

Density of cement mortar: Figs. 1 and 2 show the density of each batch of cubes and prism specimens, respectively. The average density ranged from 2056-2199 kg/m³ for cube samples and from 2097-2191 kg/m³ for prism samples. M1 (100% sand) had the highest density, while M5 (100% volcanic) had the lowest; this was caused by the lower specific gravity of the volcanic tuff in comparison with standard sand. The maximum reduction in density was 5.5%, in M5 cube samples at 7 days. Sand or volcanic tuft constituted only 65% of the mix volume, while cement and water contributed 35%. The water and cement contents were kept the same in all batches, which explains the slight reduction in the density of the volcanic specimens. It has been found that the unit weight decreased with increasing zeolite content in concrete [20]. It has been found that the density of concrete made of volcanic tuff materials was 2059 kg/m³ versus 2398 kg/m³ for normal concrete [21]. Incorporating volcanic ash (VA) in concrete mixes has a similar effect where the density decreased from 2390 kg/m³ in control samples (0% VA) to 2285 kg/m³ at 30% VA, representing a decrease of about 4.4% [22].

Compressive strength: Following ASTM C109 guidelines, 50-mm cubes of cement mortar were tested after curing periods of 3, 7, 28, and 56 days, as shown in Table V. The M3 specimens had higher strength than the M2, M4, and M5 specimens and close to M1 value. Based on the average strengths for all tests and ages, the batch was ranked in the order M3>M1>M4>M2>M5 (Figs. 3-6).

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This means that replacing standard sand with 50% volcanic tuff slightly improved (<1.6%) the compression strength of cement mortar. This result was expected, because the physical characteristics of volcanic tuff sand (i.e., its rough, angular surface texture) increase the bond between the aggregate and cement paste, which in turn increase the mortar strength. Conversely, the large specific surface area of volcanic tuff sand, compared with standard sand, requires more cement paste for coating, which is why M4 and M5 had lower compressive and flexural strengths than M3. Additionally, when added in higher ratios, volcanic tuff materials have a high absorption ratio, which decreases the W/C ratio needed for reaction, affecting the strength of the mixes. It was found that adding volcanic tuff to the concrete mix in a ratio of 20% increased compression strength by 3.8-19.9%, depending on the strength of the concrete and the type of volcanic material [18]. It was found no significant difference in the compression strength of lightweight concrete samples including volcanic tuff versus normal concrete samples [21]. Authors used zeolite in concrete in ratios of 5, 10, and 15%, and found that compressive strength increased with increasing zeolite content [20]. It was found the opposite, reporting that the Schmidt hardness, compressive strength, and flexural strength all decreased with increasing zeolite content in the concrete [4]. It was reported that 30% volcanic tuff in concrete reduced compression strength by 28% [22]. Authors reported that the compression strength of normal concrete (300 kg/cm²) made with limestone at 28 days was greater than that made with volcanic rock, by approximately 0.2, 5, and 14%, for maximum aggregate sizes of 10, 20, and 40 mm, respectively [23]. High-strength concrete (800 kg/cm²) made with limestone had higher compression strength than concrete made with volcanic rock, by approximately 4, 6, and 7% for the respective sizes.

Flexural strength: the flexural strength of 40 × 40 × 160 mm³ mortar prisms was tested after curing periods of 3, 7, 28, and 56 days. After 28 days, M2 and M3 samples had flexural strength of 7.93 and 8.44 MPa, respectively, while M1 samples had a 7.5 MPa (Fig. 9). At 28 and 56 days, all batches had higher strength than M1 samples, as shown in Tables V and ^VI. At all ages, M3 samples had the highest flexural strength, verifying the beneficial effect of using volcanic tuff in cement mortar in a 50% ratio (Figs. 7-10).

The M3 mortar had more rough and angular particles than M2 samples, and a smaller surface area than M4 and M5 samples, which resulted in higher strength. A comparison between M3 and M1 mortar (the control mortar) would depend on the same issues of surface texture and surface area, along with the fact that moderate-or low-strength aggregates can be valuable in preserving the integrity of concrete, which is the case with volcanic tuff sand [24]. Natural sand has a smaller surface area, so a smaller amount of cement is sufficient to coat the sand, accelerating the hydration process and resulting in a rapid initial increase in strength. This explains the higher flexural strength of M1 at 3 and 7 days.

It was reported normal concrete (300 kg/cm²) made with limestone at 28 days had a lower flexural strength than concrete made with volcanic rock, by approximately 6, 4, and 2%, for a maximum aggregate size of 10, 20, and 40 mm, respectively [23].

CONCLUSIONS

This study evaluated how volcanic tuff sand affected compressive strength, flexural strength, and the unit weight of mortar. Five mortar batches were produced, using various weight ratios of normal sand to volcanic tuff sand. Based on the results, we concluded that Jordanian volcanic tuff can be used successfully as construction material. Moreover, the results revealed that the appropriate ratio of blended aggregate, i.e., 50% Jordanian volcanic tuff (from Jabal Artin) can improve mortar characteristics and reduce the unit weight of mortar to some extent.

ACKNOWLEDGEMENTS

This research would not have been possible without financial support from the Scientific Research Support Fund (SRF) under the project "Utilization of Jordanian volcanic tuff in different engineering applications". We would like to place on record our sincere appreciation for the funding provided by SRF.

Rec. 04/07/2013

Ac. 17/11/2013

[1] Z. Y. Zhang, M. Jin, S. C. See, M. O. W. Richardson, E. Rirsch, D. Lambert, et al. "Investigation into nanoclay enhanced coatings for brick moisture reduction and salt formation prevention", in: Protection of historical buildings -PROHITECH Conf., Rome, Italy (2009).
[2] NRA, National Resources Authority of Jordan, Report: Zeolatic Tuff www.NRA.gov (2006).
[3] F. Negis, "Zeolite based composites in energy storage", M.Sc. Diss., Izmir Institute of Technology, Turkey (1999).
[4] K. Semsettin, "The effect of zeolite amount on the physical and mechanical properties of concrete", Int. J. Phys. Sci. 6, 13 (2011) 3041-3046.
[5] Y.Abali, S. U. Bayca, S. Targan, "Evaluation of blends tincal waste, volcanic tuff, bentonite and fly ash for use as a cement admixture", J. Hazard. Mater. 131, 1-3 (2006) 126-30.
[6] N. Augenti, F. Parisi, "Constitutive models for tuff masonry under uniaxial compression", J. Mater. Civ. Eng. 22, 11 (2010) 1102-1111.
[7] G. Faella, G. Manfredi, R. Realfonzo, "Cyclic Behaviour of Tuff Masonry Walls Under Horizontal Loading", in: Proc. 6^th Can. Masonry Symp., Canada (1992) 317-328.
[8] A. Kan, R. Gul, "Properties of Volcanic Tuff Sands as a New Material for Masonry Mortar", Int. J. Nat. Eng. Sci. 2 (2008) 69-74; H. Kaplan, H. Binici, Cem. Concr. World 1 (1996) 23-30.
[9] T. Kavasa, A. Evcin, "Use of Afyon region (Turkey) volcanic tuffs in wall tile production", J. Ind. Ceram. 25, 1 (2005) 17-19.
[10] A. Kılıc, C. D. Ati, A. Teymen, O. Karahan, Ari Kamuran, The effects of scoria and pumice aggregates on the strengths and unit weights of lightweight concrete, Sci. Res. Essays 4, 10 (2009) 961-965.
[11] A. Kilic, C. D. Atis, E. Yasar, F. Ozcan, "High-strength lightweight concrete made with scoria aggregate containing mineral admixtures", Cem. Concr. Res. 33, 10 (2009) 1595-1599.
[12] M. M. Smadi, E. Migdady, "Properties of High Strength Tuff Lightweight Aggregate Concrete", Cem. Concr. Comp. 13, 2 (1991) 129-135.
[13] A. G. Turkmenoglu, A. Tankut, "Use of tuffs from central Turkey as admixture in pozzolanic cements assessment of their petrographical properties", Cem. Concr. Res. 32, 4 (2002) 629-637.
[14] USBR, US Bureau of Reclamation, "Concrete manual. A Manual for the Control of Concrete Construction", 7^th Ed., United States Printing Office, Denver, Colorado, USA (1963).
[15] G. Marcari, G. Manfredi, A. Prota, M. Pecce, "In-plane shear performance of masonry panels strengthened with FRP", Composites Part B 38, 7-8 (2007) 887-901.
[16] A. Hartley, G. Mullins, R. Sen, "Repair of concrete masonry block wall using carbon fiber", in: Proc. Adv. Composite Mater. Bridges Struct., Montreal, Quebec, Can. Soc. Civil Eng. (CSCE) (1996) 795-802.
[17] WSDOT, Washington State Department of Transportation, "Compressive Strength of Hydraulic Cement Mortars (Using 2-in. or (50-mm) Cube Specimens", http://www.wsdot.wa.gov/publications/manuals/fulltext/M46-01/t106.pdf (2010).
[18] A. Yasin, T. A. Mohammed, R. H. Hassan, I. S. Eid, "Effect of volcanic tuff on the concrete compressive strength", Contemp. Eng. Sci. 5, 6 (2012) 295-306.
[19] A. Evangelista, A. Pellegrino, "Caratteristiche geotecniche di alcunerocce tenere italiane", Atti del Terzo Ciclo Conf. Meccanica Ingegneria delle Rocce MIR90, Torino, Italy (1990).
[20] C. Basyigit, "The effect of zeolit rate on the thermo-mechanical properties of concrete", Int. J. Phys. Sci. 5, 7 (2010) 968-971.
[21] Abu-Baker Mohammad, "Comparison the compression strength of the light weight concrete made of volcanic tuff with normal concrete", 2^nd Int. Eng. Conf., Aden, Yemen, www.adenuniv.net/uploads/conf/Engg%202/vol%201/22.pdf (2009).
[22] B. J. Olawuyi, K. O. Olusola, "Compressive Strength of Volcanic Ash/Ordinary Portland Cement Laterized Concrete", Civ. Eng. Dim. 12, 1 (2010) 23-28.
[23] P. Piyachon "Properties of Concrete using Coarse Aggregate from Volcanic Rock", M.Sc. Thesis, Kasetsart Univ. (2004).
[24] A. M. Neville, J. J. Brooks, "Concrete Technology", Longman Sci. Tech. Publ. (1987) Chapt. 12 and 13.

Publication Dates

Publication in this collection
21 July 2014
Date of issue
June 2014

History

Received
04 July 2013
Accepted
17 Nov 2013

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] [1] Z. Y. Zhang, M. Jin, S. C. See, M. O. W. Richardson, E. Rirsch, D. Lambert, et al. "Investigation into nanoclay enhanced coatings for brick moisture reduction and salt formation prevention", in: Protection of historical buildings -PROHITECH Conf., Rome, Italy (2009).

[2] [2] NRA, National Resources Authority of Jordan, Report: Zeolatic Tuff www.NRA.gov (2006).

[3] [3] F. Negis, "Zeolite based composites in energy storage", M.Sc. Diss., Izmir Institute of Technology, Turkey (1999).

[4] [4] K. Semsettin, "The effect of zeolite amount on the physical and mechanical properties of concrete", Int. J. Phys. Sci. 6, 13 (2011) 3041-3046.

[5] [5] Y.Abali, S. U. Bayca, S. Targan, "Evaluation of blends tincal waste, volcanic tuff, bentonite and fly ash for use as a cement admixture", J. Hazard. Mater. 131, 1-3 (2006) 126-30.

[6] [6] N. Augenti, F. Parisi, "Constitutive models for tuff masonry under uniaxial compression", J. Mater. Civ. Eng. 22, 11 (2010) 1102-1111.

[7] [7] G. Faella, G. Manfredi, R. Realfonzo, "Cyclic Behaviour of Tuff Masonry Walls Under Horizontal Loading", in: Proc. 6^th Can. Masonry Symp., Canada (1992) 317-328.

[8] [8] A. Kan, R. Gul, "Properties of Volcanic Tuff Sands as a New Material for Masonry Mortar", Int. J. Nat. Eng. Sci. 2 (2008) 69-74; H. Kaplan, H. Binici, Cem. Concr. World 1 (1996) 23-30.

[9] [9] T. Kavasa, A. Evcin, "Use of Afyon region (Turkey) volcanic tuffs in wall tile production", J. Ind. Ceram. 25, 1 (2005) 17-19.

[10] [10] A. Kılıc, C. D. Ati, A. Teymen, O. Karahan, Ari Kamuran, The effects of scoria and pumice aggregates on the strengths and unit weights of lightweight concrete, Sci. Res. Essays 4, 10 (2009) 961-965.

[11] [11] A. Kilic, C. D. Atis, E. Yasar, F. Ozcan, "High-strength lightweight concrete made with scoria aggregate containing mineral admixtures", Cem. Concr. Res. 33, 10 (2009) 1595-1599.

[12] [12] M. M. Smadi, E. Migdady, "Properties of High Strength Tuff Lightweight Aggregate Concrete", Cem. Concr. Comp. 13, 2 (1991) 129-135.

[13] [13] A. G. Turkmenoglu, A. Tankut, "Use of tuffs from central Turkey as admixture in pozzolanic cements assessment of their petrographical properties", Cem. Concr. Res. 32, 4 (2002) 629-637.

[14] [14] USBR, US Bureau of Reclamation, "Concrete manual. A Manual for the Control of Concrete Construction", 7^th Ed., United States Printing Office, Denver, Colorado, USA (1963).

[15] [15] G. Marcari, G. Manfredi, A. Prota, M. Pecce, "In-plane shear performance of masonry panels strengthened with FRP", Composites Part B 38, 7-8 (2007) 887-901.

[16] [16] A. Hartley, G. Mullins, R. Sen, "Repair of concrete masonry block wall using carbon fiber", in: Proc. Adv. Composite Mater. Bridges Struct., Montreal, Quebec, Can. Soc. Civil Eng. (CSCE) (1996) 795-802.

[17] [17] WSDOT, Washington State Department of Transportation, "Compressive Strength of Hydraulic Cement Mortars (Using 2-in. or (50-mm) Cube Specimens", http://www.wsdot.wa.gov/publications/manuals/fulltext/M46-01/t106.pdf (2010).

[18] [18] A. Yasin, T. A. Mohammed, R. H. Hassan, I. S. Eid, "Effect of volcanic tuff on the concrete compressive strength", Contemp. Eng. Sci. 5, 6 (2012) 295-306.

[19] [19] A. Evangelista, A. Pellegrino, "Caratteristiche geotecniche di alcunerocce tenere italiane", Atti del Terzo Ciclo Conf. Meccanica Ingegneria delle Rocce MIR90, Torino, Italy (1990).

[20] [20] C. Basyigit, "The effect of zeolit rate on the thermo-mechanical properties of concrete", Int. J. Phys. Sci. 5, 7 (2010) 968-971.

[21] [21] Abu-Baker Mohammad, "Comparison the compression strength of the light weight concrete made of volcanic tuff with normal concrete", 2^nd Int. Eng. Conf., Aden, Yemen, www.adenuniv.net/uploads/conf/Engg%202/vol%201/22.pdf (2009).

[22] [22] B. J. Olawuyi, K. O. Olusola, "Compressive Strength of Volcanic Ash/Ordinary Portland Cement Laterized Concrete", Civ. Eng. Dim. 12, 1 (2010) 23-28.

[23] [23] P. Piyachon "Properties of Concrete using Coarse Aggregate from Volcanic Rock", M.Sc. Thesis, Kasetsart Univ. (2004).

[24] [24] A. M. Neville, J. J. Brooks, "Concrete Technology", Longman Sci. Tech. Publ. (1987) Chapt. 12 and 13.

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Effect of volcanic tuff on the characteristics of cement mortar

Efeito de tufos vulcânicos nas características da argamassa de concreto

Abstracts

Publication Dates

History