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"Latar Belakang: Residu radikal bebas pasca perawatan internal bleaching dapat mengganggu proses polimerisasi resin komposit. Akibatnya, terjadi penurunan kekuatan ikatan restorasi. Antioksidan ekstrak teh hijau dapat digunakan untuk menghilangkan radikal bebas pasca bleaching dan meningkatkan shear bond strength resin komposit. Tujuan: mengetahui perbedaan shear bond strength resin komposit pada dentin pasca internal bleaching dengan dan tanpa aplikasi ekstrak teh hijau pada konsentrasi yang berbeda selama 2 menit. Metode: 25 gigi premolar, dipotong dalam arah mesiodistal, dan dibagi menjadi 5 kelompok: Kelompok 1 dentin normal, Kelompok 2 dentin pasca bleaching, Kelompok 3 dentin 2 minggu pasca bleaching, Kelompok 4  dentin pasca bleaching dengan teh hijau 10% 2 menit, dan Kelompok 5 dentin pasca bleaching dengan aplikasi teh hijau 35% 2 menit. Semua kelompok diaplikasikan restorasi resin komposit. Uji shear bond strength menggunakan Universal Testing Machine. Analisis statistik menggunakan one-way ANOVA dan Uji Post Hoc Bonferroni. Hasil: Uji Post Hoc Bonferroni menunjukkan perbedaan bermakna antara kelompok 1 dan 4, kelompok 2 dan 5, serta kelompok 4 dan 5. Kesimpulan: Aplikasi antioksidan ekstrak teh hijau 35% selama 2 menit lebih tinggi dalam meningkatkan shear bond strength resin komposit dibandingkan dengan aplikasi ekstrak teh hijau 10% selama 2 menit pada dentin pasca internal bleaching menggunakan hidrogen peroksida 35%.

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Introduction: Internal bleaching treatment could leave free radicals in the dentinal tubules. It can interfere with the polymerization process of the composite resin. Antioxidants from green tea extract can remove the free radicals after bleaching and increase the shear bond strength of composite resin.

Objective: To determine the shear bond strength of composite resin on dentin after internal bleaching with and without green tea extract application at different concentrations in 2 minutes.

Methods: 25 premolars were cut in mesiodistal direction and divided into five groups: Group 1 normal dentin, Group 2 bleached dentin, Group 3 bleached dentin, Group 4 10% green tea application in 2 minutes, and Group 5 35% green tea application in 2 minutes. All groups were restored with composite resin. All specimens' shear bond strength was tested with the Universal Testing Machine. The data were analyzed with one-way ANOVA and Bonferroni Post Hoc Test.

Results: Post Hoc Bonferroni test showed that there were statistical differences  in groups 1 and 2, groups 1 and 4, groups 2 and 5, and groups 4 and 5.

Conclusion: 35% green tea extract is more effective than 10% green tea extract as an antioxidant for increasing the shear bond strength of composite resin after internal bleaching."

"ABSTRAKSandblasting dilakukan pada permukaan restorasi veneer indirek resin kompositsebelum direkatkan pada email menggunakan resin semen Multi-step danSADRC. Tujuan penelitian ini untuk mengetahui pengaruh durasi sandblastingterhadap kuat rekat geser veneer indirek resin komposit yang direkatkan padaemail. Pengujian kuat rekat geser menggunakan Universal Testing Machine,kemudian analisa patahan dengan Stereomicroscope dan Scanning ElectronMicroscope. Hasil penelitian menunjukkan bahwa grup resin semen Multi-stepmenghasilkan kuat rekat geser yang lebih tinggi dan berbeda bermaknadibandingkan grup SADRC. Durasi sandblasting yang berbeda, tidak memberikanperbedaan nilai kuat rekat yang bermakna baik pada grup resin semen Multi-stepmaupun SADRC.

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BSTRACTSandblasting was performed on the surface of indirect composite resin veneer(VIRK) restorations before bonding to enamel using Multi-step resin cement andSADRC. The purpose of this study was to determine the effect of sandblastingduration on Shear Bond Strength (SBS) of VIRK bonded to enamel. Shear BondStrength test was done using Universal Testing Machine, failure analysis wasevaluated using Stereomicroscope and Scanning Electron Microscope. The resultsshowed that VIRK cemented with Multi-step produces higher SBS andsignificantly different than VIRK cemented with SADRC. Sandblasting durationdid not influence SBS value of VIRK cemented with Multi-step and SADRC."

"The aim of this in vitro study was to evaluate the shear bond strength of resin composite materials to dentin by using different bonding agents. Forty human premolars were selected for the study, and cylindrical posts of either Spectrum TPH and Charisma were bonded vertically to a standard flat dentinal area, prepared on the buccal survace. A chisel-shaped shearing blade, attached to the crosshead of a universal mechanical testing machine. The shear bond strengths to dentin of 10 resin composite-dentin adhesive combinations were measured. The results showed that the bond strength values of dentin bonding agents were not significant (p>0.05). It seems important for clinicians to use the combination of resin composite and dentin bonding agent recommended by the manufacturer."

"Penelitian ini bertujuan untuk membandingkan kuat rekat geser dan Adhesive Remnant Index (ARI) breket metal yang direkatkan dengan dua semen resin light cure berbeda. Dua puluh gigi premolar atas manusia ditanam dalam akrilik dan dibagi menjadi dua kelompok; kelompok A: Transbond XT + breket Mini Dyna Lock, kelompok B: Enlight + breket Mini Dyna Lock. Hasil penelitian menunjukkan kuat rekat geser kelompok A adalah 12,46 ± 0,35 MPa, ARI: 1 dan 2, dan kelompok B adalah 9,69 ± 0,53 MPa, ARI: 2, (p <0,05). Disimpulkan bahwa terdapat perbedaan bermakna kuat rekat geser pada kedua kelompok dengan kegagalan ikatan bersifat kohesif.

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The aims of this study was to compare shear bond strength (SBS) and Adhesive Remnant Index (ARI) of metal bracket bonded with two different light cured resin cements. Twenty extracted human upper premolar embedded in acrylic and divided into two groups; Group A: Transbond XT + Mini Dyna Lock brackets, group B: Enlight + Mini Dyna Lock brackets.

The results showed SBS of group A was 12.46 ± 0.35 MPa, ARI: 1 and 2, and group B was 9.69 ± 0.53 MPa , ARI: 2, (p <0.05). It was concluded that the SBS of two groups was significantly different with cohesive bond failure."

"Efek sandblasting terhadap kekuatan rekat geser veneer indirek resin komposit. Perlekatan antara restorasi veneer indirek resin komposit (VIRK) dengan permukaan email diperoleh dari penggunaan resin semen multi-step (MS). Material self-adhesive dual-cured resin cement (SADRC) dengan satu tahap pemakaian mulai banyak diperkenalkan. Tujuan: Untuk mengetahui efek sandblasting (SB) terhadap kekuatan rekat geser VIRK pada email dengan menggunakan resin semen multi-step dan SADRC. Metode: Empat puluh spesimen yaitu bagian bukal email gigi premolar manusia, diratakan dan dipoles menggunakan silikon karbida. Spesimen VIRK dimasukkan dalam ruang Solidilite untuk penyinaran, kemudian dibagi menjadi 2 grup, tanpa sandblasting (n=20) dan dengan sandblasting selama 10 detik (n=20). Selanjutnya direkatkan pada email dengan menggunakan resin semen multi-step (n=10) dan SADRC (n=10). Setelah 2 jam disimpan dalam inkubator, kekuatan rekat geser spesimen diuji menggunakan Universal Mechanical Testing Machine. Data dianalisis statistik dengan uji one-way ANOVA. Hasil: Nilai rata-rata kekuatan rekat geser multi-step tanpa SB (18,95±7,80MPa) dan multi-step SB (19,30±8,21MPa) memiliki perbedaan bermakna dengan SADRC tanpa SB (4,85±2,12MPa) dan SADRC dengan SB (9,57±3,45MPa)(p<0,05). Simpulan: Sandblasting dapat meningkatkan kekuatan rekat geser VIRK pada email yang menggunakan resin semen multi-step dibandingkan dengan SADRC.

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Attachment between restoration and enamel surface in indirect resin composite veneer restoration (IRCV) is obtained using multi-step (MS) resin coment. Recently, a one step self-adhesive dual-cured resin coment (SADRC) was introduced. Objective: To determine the effect of sandblasting on shear bond strenght (SBS) of IRCV to enamel using MS resin coment and SADRC. Methods: Forty specimens of buccal surface of enamel human premolar were used. The specimens were flattened and polished using silicon carbide. IRCV cylindrical specimens were light-cured in Solidilite chamber and were divided into two groups: IRCV without sandblasting (n=20) and with sandblasting for 10 seconds (n=20) and then bonded to enamel using MS (n=10) and SADRC (n=10), respectively. After 24h SBS of specimens were tested using a Universal Testing machine. Data were analyzed statistically by one-way ANOVA. Results: The average SBS value of IRCV without SB and bonded with MS was 18.95±7.80MPa and MS with SB was 19.30±8.21MPa. They were differ significantly with SADRC without SB (4.85±2.12MPa) and SADRC with SB (9.57±3.45MPa)(p<0.05). Conclusion: Sandblasting significantly increased SBS VIRK to enamel using MS resin cement than SADRC."

"Pemakaian semen Portland putih di Indonesia cenderung hanya digunakan sebagai pekerjaan finishing saja. Hal ini dikarenakan harga yang mahal karena semen Portland putih merupakan produk impor di Indonesia. Kini, dengan diproduksinya semen Portland putih oleh PT. Indocement Tunggal Prakarsa, Tbk, mendorong diaplikasikannya semen Portland putih sebagai bahan penyusun beton dengan fungsi sebagai elemen struktur. Campuran beton dengan menggunakan semen Portland putih dikenal dengan istilah Beton Semen Putih. Hasil penelitian mengenai karakteristik beton semen putih belum banyak dipublikasikan. Oleh karena itu perlu dilakukan penelitian terhadap karakteristik beton semen putih.Tujuan penelitian ini adalah untuk mempelajari pengaruh variasi rasio air-semen terhadap kuat geser dan susut pada beton semen putih kemudian dibandingkan dengan beton normal yang menggunakan semen Portland komposit. Metode dan prosedur pelaksanaan pengujian beton putih dilakukan dengan mengacu pada Standar ASTM dan dilaksanakan di Laboratorium Struktur dan Material Departemen Teknik Sipil Fakultas Teknik Universitas Indonesia. Beton Semen Putih dibuat dengan menggunakan semen Portland putih dan pasir putih dengan komposisi tertentu. Variasi rasio air-aemen yang digunakan pada campuran beton adalah 0,4; 0,45; 0,5; dan 0,55. Kemudian dilakukan pengujian terhadap kuat geser pada umur 28 hari dan susut selama 56 hari. Dari hasil pengujian, dapat disimpulkan bahwa kenaikan rasio air-semen sebesar 0,1 akan meningkatkan 26,52% susut pada beton semen putih. Nilai susut beton semen putih pada rasio air-semen 0,5 lebih besar 18,75% dibandingkan dengan nilai susut beton normal. Kenaikan rasio air-semen sebesar 0,1 akan menurunkan kuat geser senilai 11,58% pada beton semen putih. Beton semen putih memiliki kuat geser lebih tinggi 10,35% dibandingkan beton normal.

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The used of white Portland cement in Indonesia tend to be used only as a finishing work. The reason for this is its price was expensive while it was an imported product in Indonesia. Now, white Portland cement is produced by PT. Indocement Tunggal Prakarsa, Tbk. encouraging its applied as an structural element. Concrete mix with white Portland cement is known by the term White Cement Concrete. The research's result on the characteristics of white cement concrete has not been much publicized. Therefore, it is need to do the research of it.

Goal of this research is to study the influence of variations in water-cement ratio for shear strength and shrinkage of white cement concrete then it compared with the normal use of Portland composite cement. Methods and procedures of the testing are based on ASTM Standards and implemented in the Laboratory of Structure and Materials Department of Civil Engineering, Faculty of Engineering, University of Indonesia. White Cement Concrete made with white Portland cement and white sand with a specific composition. Variations in water-cement ratio that are used in the concrete mixture are 0.4, 0.45, 0.5 and 0.55. Then we do the shrinkage's test for 56 days and shear strength's test at the age of 28th day. From this research, it can be concluded that increasing 0.1 of water-cement ratio will increase 26.52% shrinkage in white cement concrete. Shrinkage's value of white cement concrete with water-cement ratio of 0.5 is greater 18.75% than its normal concrete. The increase in 0,1 of water-cement ratio will decrease 11.58% the shear strength in white cement concrete. White cement concrete has shear strength 10.35% higher than normal concrete."

"Latar Belakang : Braket berperan sebagai media penyalur gaya ke gigi sehingga braket perlu didesain dengan tepat. Desain braket berdasarkan konfigurasi basisnya terdiri dari mesh dan nonmesh. Basis braket tipe nonmesh dengan desain yang tepat dapat menghasilkan kekuatan rekat sesuai kriteria optimal.Tujuan : Untuk mengetahui nilai kuat rekat geser optimal pada tiga jenis braket metal nonmesh dan menvalidasi simulasi desain jenis rumus bangun ruang dasar braket metal nonmesh.Metode : Tiga puluh gigi premolar pertama rahang atas dibagi ke dalam tiga kelompok uji braket metal nonmesh (Tipe 1, Tipe 2, dan Tipe 3). Gigi difiksasi dalam self acrylic. Permukaan bukal gigi dibersihkan dengan pumice lalu dietsa dengan asam fosforik 37% selama 15 detik. Braket di-bonding pada permukaan tengah mahkota klinis lalu di-light cure selama 20 detik. Kuat rekat geser diuji menggunakan universal testing machine dengan blade method dan cross- head speed 0,5mm/min pada arah oklusogingival dan mesiodistal. Penilaian Adhesive Remnant Index dengan magnifikasi 10x. Analisa data menggunakan software SPSS 27.Hasil : Kuat rekat geser dan nilai Adhesif Remnant Index pada tiga jenis braket metal nonmesh pada arah oklusongivial tidak berbeda bermakna (p>0,05). Kuat rekat geser pada arah mesiodistal pada tiga jenis braket metal nonmesh berbeda bermakna antara braket tipe 2 dan tipe 3 (p£0,05) sedangkan nilai Adhesif Remnant Index tidak berbeda bermakna (p>0,05).Kesimpulan : Kuat rekat paling optimal adalah braket tipe 2 dengan rumus bangun ruang dasar braket “Maze Base Design” dengan konfigurasi area undercut menyerupai labirin. Konfigurasi tersebut memberikan retensi optimum pada perlekatan braket ke gigi.

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Background : Bracket acts as medium for transmitting force to the teeth therefore bracket needs to be designed appropriately. Bracket design based on the base configuration consists of mesh and nonmesh. The appropriate design of nonmesh bracket produce bond strength according to optimal criteria.

Objective : Determine optimal shear bond strength and validate design simulation of the base bracket structure formula for three types of nonmesh metal bracket.

Material and Method : Thirty maxillary first premolars were divided into three test groups (Type 1, Type 2, and Type). Teeth were fixed in self acrylic. Buccal surface of tooth was cleaned with pumice and etched (37% phosphoric acid) for 15 seconds. Bracket was bonded to the middle surface of clinical crown and light cured for 20 seconds. Shear bond strength was tested using universal testing machine with blade method and cross head speed of 0.5 mm/min in occlusogingival and mesiodistal directions. Adhesive Remnant Index (ARI) assessment was 10x magnification. Data was analyzed by using SPSS 27 software.

Result : Shear bond strength and ARI for three types of nonmesh metal brackets in occlusogingival direction were not significantly different (p>0.05). Shear bond strength in mesiodistal direction was significantly different between type 2 and type 3 bracket (p£0,05), however the ARI was not significantly different (p>0.05).

Conclusion : The most optimal bond strength was type 2 bracket with “Maze Base Design” as type of bracket base structure formula. It had configuration a labyrinth-shaped undercut area providing optimum retention for bracket attachment to teeth."

"Latar Belakang: Prosedur internal bleaching dengan hidrogen peroksida 35% dapat meninggalkan residu radikal bebas pada struktur gigi yang akan mengganggu kekuatan ikatan restorasi resin komposit. Natrium askorbat sebagai antioksidan dapat menghilangkan residu radikal bebas dan meningkatkan kekuatan ikatan geser resin komposit pada gigi.Tujuan: mengetahui kekuatan ikatan geser resin komposit pada gigi pasca internal bleaching dengan hidrogen peroksida yang diaplikasikan natrium askorbat 10% dan 35% selama 2 menit dan 10 menit Metode: Prosedur internal bleaching dilakukan pada 25 gigi premolar yang dipotong menjadi dua bagian buko-palatal, kemudian sampel dibagi menjadi 5 kelompok. Kelompok 1 tanpa aplikasi natrium askorbat, kelompok 2 aplikasi natrium askorbat 35% selama 2 menit, kelompok 3 aplikasi natrium askorbat 35% selama 10 menit, kelompok 4 aplikasi natrium askorbat 10% selama 2 menit, dan kelompok 5 aplikasi natrium askorbat 10% selama 10 menit. Semua kelompok dilakukan restorasi resin komposit kemudian dilakukan uji kekuatan ikatan geser dengan alat Universal Testing Machine (UTM). Data yang diperoleh dianalisa secara statistik dengan ANOVA satu jalur dan Uji Post Hoc Bonferroni. Hasil: Hasil uji Bonferroni menunjukkan perbedaan bermakna kekuatan ikatan geser pada kelompok 1 dan 2; kelompok 1 dan 3; kelompok 2 dan 4, dan kelompok 3 dan 5. Sedangkan antara kelompok 2 dan 3; dan kelompok 4 dan 5 tidak terdapat perbedaan bermakna. Kesimpulan: Aplikasi natrium askorbat 35% selama 2 menit cukup untuk meningkatkan kekuatan ikatan geser resin komposit pada gigi pasca internal bleaching dengan hidrogen peroksida 35%.

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Background: Internal bleaching with 35% hydrogen peroxide will produce free radical residues within the tooth structure and disrupt the bond strength of composite resin restorations. Sodium ascorbate as an antioxidant can remove free radical residues and increase the shear bond strength of composite resins. Objective: To examine the effect of 10% and 35% sodium ascorbate application on the shear bond strength of composite resin after internal bleaching with 35% hydrogen peroxide. Methods: Internal bleaching procedure was performed on 25 premolars, then the samples were divided into 5 groups. Group 1 without sodium ascorbate, group 2 application of 35% sodium ascorbate for 2 minutes, group 3 application of 35% sodium ascorbate for 10 minutes, group 4 application of 10% sodium ascorbate for 2 minutes, and group 5 application of 10% sodium ascorbate for 10 minutes. All groups were restored with composite resin and tested for shear bond strength with Universal Testing Machine (UTM). The data were statistically analyzed with one-way ANOVA and Bonferroni Post Hoc Test. Results: The results showed that there were statistical differences between groups 1 and 2; groups 1 and 3; groups 2 and 4, and groups 3 and 5. Meanwhile between groups 2 and 3; and groups 4 and 5 there was no significant difference. Conclusion: Application of 35% sodium ascorbate for 2 minutes increased the shear bond strength of the composite resin after internal bleaching with 35% hydrogen peroxide."

"[ABSTRAKTelah dilakukan penelitian pembuatan beton ringan atau lightweightconcrete (LWC) menggunakan batu apug (BA) dan abu sekam padi (ASP).Sampel beton ringan yang dibuat mengandung BA dengan fraksi berbeda, adapunmaterial semen, pasir, dan abu sekam padi volumenya dijaga tetap. Terdapat duaparameter utama yang menentukan sifat mekanik sampel LWC masing-masingadalah densitas sampel dan rasio air/semen (w/c). Sifat mekanik yang palingutama dari LWC adalah kekuatan tekan. Pada campuran dengan fraksi volumebatu apung terbesar (100%) menghasilkan densitas dan kekuatan tekan palingrendah masing-masing sebesar (1389,6 kg/m3 dan 11,1 MPa). Diketahui bahwamakin rendah fraksi batu apung dalam sampel beton makin tinggi nilai densitasdan kekuatan tekannya, disebabkan oleh tingginya nilai fraksi pori baik poriterbuka maupun pori tertutup dalam sampel beton. Observasi terhadap fotomikroSEM batu apung menunjukkan bahwa terdapat sejumlah besar pori dengan bentukmemanjang ke bagian dalam dari permukaan sampel beton. Pori hadir dengankerapatan jumlah pori relatif besar serta dengan ukuran yang bervariasi. Fakta inimenjelaskan mengapa batu apung besifat ringan karena memiliki densitas massayang rendah. Pola difraksi sinar X sampel beton ringan memperlihatkan dominasifasa kristalin diidentifikasi sebagai fasa quartz (SiO2). Namun dapat dipastikansampel beton ringan terdiri dari fasa campuran antara fasa kristalin dan dengansedikit fasa amorph.Fotomikro SEM beton ringan menunjukkan bahwa senyawa Kalsium SilikatHidrat (CSH) mulai tumbuh pada waktu awal proses hidrasi dan terusberkembang sampai umur beton mencapai umur hidrasi 28 hari yang ditandaidengan sifat fisik yang padat dan peningkatan kekuatan beton. Dapat dipastikanbahwa senyawa CSH ini memiliki peranan penting terhadap pengaturan sifatmekanik seperti kekuatan tekan. Penelitian ini menyimpulkan bahwa batu apungdan abu sekam padi adalah material berbasis silika amorph yang memiliki densitaslebih rendah terutama dibandingkan dengan material pembentuk beton lainnya.Baik densitas dan kekuatan tekan sampel beton ringan ditentukan oleh rasio antarabatu apung dan abu sekam padi. Ditemukan rasio terkecil BA/ASP yaitu 8menghasilkan nilai densitas dan kekuatan tekan optimal, masing-masing pada usiabeton 28 hari sebesar 1891 kg/m3 dan 23 MPa. Komposisi beton ringan yangterbaik diperoleh dari hasil penelitian ini adalah komposisi campuran PCC (1,00) :Pasir (1,00) : ASP (0,05) : BA (0,50) dengan nilai Slump 8 cm ditandai oleh nilairasio antara kuat tekan dan densitas tertinggi adalah 1285.;

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ABSTRACTResearch studies on the manufacture of lightweight concrete (LWC) usingpumice and rice husk ash (RHA) materials have been done. LWC samples weremade of pumice materials with a different mass fraction, while the cement, sand,and rice husk ash materials were keep fixed. It was found that there are two mainparameters that determine the mechanical properties of LWC which are densityand the water and cement ratio (w/c ratio). The main mechanical properties ofLWC sample is the power press. Samples with the largest volume fraction ofpumice (100%) resulted in lightest density (1389.6 kg/m3) and the smalleststrength of LWC (11.1 MPa). It was found that, the lower the mass fraction ofpumice in LWC samples, the higher the density values and compressive strengthwere obtained. This was caused by the high mas fraction value of pores, whichwere both open and closed pores. Scanning electron micorscopy (SEM) imagesfor the pumice showed that the there are a large number of regular and structuredpores extending deep inside the surface of the sample. It was observed that porespresent with pore size does not vary significantly but with the density of therelatively large number of pores, indicating pumice has a low mass density. TheXRD pattern of the lightweight concrete samples indicated that the samples weredominated by crystalline phases in which the quartz (SiO2) is the main phase anda small fraction of amorphous phase was also obtained.SEM images of lightweight concrete samples showed that the structure ofCalcium Silicate Hydrates (CSH) started growing at the beginning of hydrationtime and continue to evolve into a more solid structure until the age of 28 days,where the compound has an important role to the mechanical properties such ascompressive strength. The study concluded that the pumice and rice husk ash isare amorphous silica-based material which has a lower density compared to otherconcrete forming material such as cement and sands. Both density and lightweight concrete compressive strength are determined by the ratio between pumiceand rice husk ash, in which the smallest ratio 8 resulted in the largest density andcompressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at theage of 28 days. The study concluded that the best composition for lightweightconcrete samples was the following: PCC (1,00): Sand (1,00): ASP (0,05): BA(0,50) with a slump value of 8 cm resulted in the largest value of a ratio betweencompressive strength and density of 1285.;Research studies on the manufacture of lightweight concrete (LWC) usingpumice and rice husk ash (RHA) materials have been done. LWC samples weremade of pumice materials with a different mass fraction, while the cement, sand,and rice husk ash materials were keep fixed. It was found that there are two mainparameters that determine the mechanical properties of LWC which are densityand the water and cement ratio (w/c ratio). The main mechanical properties ofLWC sample is the power press. Samples with the largest volume fraction ofpumice (100%) resulted in lightest density (1389.6 kg/m3) and the smalleststrength of LWC (11.1 MPa). It was found that, the lower the mass fraction ofpumice in LWC samples, the higher the density values and compressive strengthwere obtained. This was caused by the high mas fraction value of pores, whichwere both open and closed pores. Scanning electron micorscopy (SEM) imagesfor the pumice showed that the there are a large number of regular and structuredpores extending deep inside the surface of the sample. It was observed that porespresent with pore size does not vary significantly but with the density of therelatively large number of pores, indicating pumice has a low mass density. TheXRD pattern of the lightweight concrete samples indicated that the samples weredominated by crystalline phases in which the quartz (SiO2) is the main phase anda small fraction of amorphous phase was also obtained.SEM images of lightweight concrete samples showed that the structure ofCalcium Silicate Hydrates (CSH) started growing at the beginning of hydrationtime and continue to evolve into a more solid structure until the age of 28 days,where the compound has an important role to the mechanical properties such ascompressive strength. The study concluded that the pumice and rice husk ash isare amorphous silica-based material which has a lower density compared to otherconcrete forming material such as cement and sands. Both density and lightweight concrete compressive strength are determined by the ratio between pumiceand rice husk ash, in which the smallest ratio 8 resulted in the largest density andcompressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at theage of 28 days. The study concluded that the best composition for lightweightconcrete samples was the following: PCC (1,00): Sand (1,00): ASP (0,05): BA(0,50) with a slump value of 8 cm resulted in the largest value of a ratio betweencompressive strength and density of 1285., Research studies on the manufacture of lightweight concrete (LWC) usingpumice and rice husk ash (RHA) materials have been done. LWC samples weremade of pumice materials with a different mass fraction, while the cement, sand,and rice husk ash materials were keep fixed. It was found that there are two mainparameters that determine the mechanical properties of LWC which are densityand the water and cement ratio (w/c ratio). The main mechanical properties ofLWC sample is the power press. Samples with the largest volume fraction ofpumice (100%) resulted in lightest density (1389.6 kg/m3) and the smalleststrength of LWC (11.1 MPa). It was found that, the lower the mass fraction ofpumice in LWC samples, the higher the density values and compressive strengthwere obtained. This was caused by the high mas fraction value of pores, whichwere both open and closed pores. Scanning electron micorscopy (SEM) imagesfor the pumice showed that the there are a large number of regular and structuredpores extending deep inside the surface of the sample. It was observed that porespresent with pore size does not vary significantly but with the density of therelatively large number of pores, indicating pumice has a low mass density. TheXRD pattern of the lightweight concrete samples indicated that the samples weredominated by crystalline phases in which the quartz (SiO2) is the main phase anda small fraction of amorphous phase was also obtained.SEM images of lightweight concrete samples showed that the structure ofCalcium Silicate Hydrates (CSH) started growing at the beginning of hydrationtime and continue to evolve into a more solid structure until the age of 28 days,where the compound has an important role to the mechanical properties such ascompressive strength. The study concluded that the pumice and rice husk ash isare amorphous silica-based material which has a lower density compared to otherconcrete forming material such as cement and sands. Both density and lightweight concrete compressive strength are determined by the ratio between pumiceand rice husk ash, in which the smallest ratio 8 resulted in the largest density andcompressive strength, which are 1890.5 kg/m3 and 23.2 MPa respectively at theage of 28 days. The study concluded that the best composition for lightweightconcrete samples was the following: PCC (1,00): Sand (1,00): ASP (0,05): BA(0,50) with a slump value of 8 cm resulted in the largest value of a ratio betweencompressive strength and density of 1285.]"