Synthesis and Characterization of Crystalline NaY-Zeolite from Belitung Kaolin as Catalyst for n -Hexadecane Cracking

: Crystalline sodium Y (NaY) zeolite has been synthesized using alternative natural source of aluminate and silicate, extracted from natural Belitung kaolin. Prior to use, the natural kaolin was pretreated to obtain fragmented metakaolin and extracted silica. Synthesis was conducted with the addition of NaY gel (two types of NaY seeds were used, prepared from colloidal sillica or sodium silica water) using hydrothermal method for 21 h at 100 ◦ C. The characterization on the as-synthesized zeolites conﬁrmed that the one prepared using colloidal silica-seed has closer structure similarity to NaY zeolite that was synthesized using pro analysis silicate and aluminate sources. Thus, the rest of the synthesis of NaY was carried out using colloidal silica-NaY seed. The NaY zeolites then were converted to HY, through ammonium-exchange followed by calcination, to be tested as cracking catalysts using n -hexadecane as a probe molecule. It shows that HY from metakaolin and extracted silica gives high performance, i.e., n -hexadecane conversion of 58%–64%, also C 5 -C 12 percentage yield and selectivity of 56%–62% and 98%. This work has shown the potential to utilize kaolin as alternative silicate aluminate sources for crystalline zeolite synthesis and to obtain inexpensive and environmentally friendly catalyst materials.


Introduction
Zeolite, one type of tectosilicate group from alumina silicate family [1,2], has played an important role for more than 100 years in the chemical industry, and is widely used in various fields such as water purification [3,4], adsorption, separation, anticorrosion [5] and catalysis processes [6]. Furthermore, Zeolite Y, a member of Faujasite (FAU) framework has long been used as a catalyst in cracking reaction for crude petroleum to more valuable gasoline, diesel and many products [7]. Its superiority properties such as unique topology, large surface area, adsorption capacity, pore size uniformity, thermal stability and having active sites with diverse strength become the main attractions related to their application [8].
Conventional hydrothermal zeolite synthesis method is still quite popular. The synthesis is carried out by mixing certain amount of aluminate [AlO 4 ] 5− and silicate [SiO 4 ] 4− precursors in an alkaline medium at 60-200 • C in Teflon-lined autoclave for a specific time [9]. However, synthesis of high crystalline zeolite is still expensive because it requires pro analytical chemicals as precursors of aluminate and silicate. On the other hand, in some countries including Indonesia, natural aluminosilicate

Synthesis of NaY Zeolite
Synthesis of NaY zeolite was carried out according to certain molar composition (Na 2 O:Al 2 O 3 : SiO 2 :H 2 O = 10.67:1:10:180) as reported in Liu, 2016 [22] with some adjustment. Certain amount of metakaolin and extracted silica were used as aluminate and silicate source accordingly, based on the SiO 2 /Al 2 O 3 ratio of the pretreated materials. They were mixed with deionized water until homogeneous. Two sets of NaY seeds were prepared using colloidal silica (Ludox HS40) or sodium silica water by following the molar ratio reported in Ginter, et al. [23]. Then, the seed 10 w/w % of the mixture was transferred to the mixture, was stirred in propylene bottle and aged for 24 h at room temperature. The crystallization was carried out in Teflon-lined stainless-steel autoclave and Crystals 2019, 9,404 3 of 14 polypropylene bottle at 100 • C for 24 h. The white precipitate then was filtered, washed and dried at room temperature.

Characterization
Extensive solid-state characterization techniques such as X-Ray Diffraction (XRD), X-Ray Fluoresence (XRF), Fourier Transform-Infra Red (FTIR), Scanning Electron Microscopy with Energy Dispersive X-Ray Spectroscopy (SEM-EDX), were carried out on kaolin, metakaolin, extracted silica and the as-synthesized material. Analysis of functional group of NaY zeolite was carried out using Alpha Bruker FTIR spectrometer. XRD analysis was carried out on PANanalytical: X'Pert Pro XRD Elemental analysis was performed on PANanalytical: Epsilon1 X-Ray Flourosence Spectrometer (XRF) (Complete surface area analysis was characterized using Quantachrome. All the characterization were carried out at Universitas Indonesia. SEM Image was captured at KAIST, South Korea, using Field Emission SEM FEI Magellan 400 and FIG Quanta FEG 450. All solid state NMR measurement were conducted at the University of Warwick's Solid State NMR facility, UK. All 29 Si single pulse Magic-Angle Spinning Nuclear Magnetic Resonance (MAS NMR) measurements were performed at 7.05 T ( 29 Si Larmor frequency (ν o ) of 59.6 MHz, 1 H Larmor frequency of 300.1 MHz) using a Varian/Chemagnetics Infinity Plus spectrometer. These experiments were performed using a Bruker 7 mm HX probe which enabled a MAS frequency of 5 kHz to be implemented. Pulse length calibration was performed on solid kaolinite from which a 29 Si π/2 pulse time of 4.25 µs was measured. All experiments were undertaken using a 29 Si π/2 flip angle, a recycle delay of 240 s, and high power 1 H decoupling of 80 kHz during data acquisition. The analogous cross-polarization MAS (CPMAS) experiments utilized an initial 1 H π/2 pulse of 4 µs, a Hartmann-Hahn contact time of 4 ms which was comprised of a ramp from 75% and 100% during that period, a 2.5 s recycle delay, and high power 1 H decoupling of 80 kHz during data acquisition. All 29 Si chemical shifts were reported against the IUPAC recommended primary reference of Me 4 Si (δ iso = 0.0 ppm), via a kaolinite secondary reference at δ iso = −92 ppm [24].
Single pulse 27 Al MAS NMR measurements were performed at 9.45 T ( 27 Al Larmor frequency of 103.9 MHz) using a Bruker Avance HD-400 spectrometer. All experiments were conducted using a Bruker 3.2 mm HX probe which enabled a MAS frequency of 20 kHz. The 27 Al pulse optimization and chemical shift referencing was undertaken using the IUPAC primary reference of 1.1 M solution of Al(NO 3 ) 3 set to 0 ppm [1]. A 'non-selective' (solution) π/2 pulse time of 18 µs (corresponding to a 'selective' (solid) pulse time of 6 µs) was accurately calibrated on this solution. In order to obtain quantitative results, a tip angle of π/12 was used which corresponded to a selective 1.0 µs pulse length which was used with a recycle delay of 0.5 s.

Catalytic Cracking Test
The catalytic activity of HY zeolites was tested using micro activity test (MAT) reactor located at PT Pertamina, following procedure reported in [18]. Approximately 0.5 g of catalyst was placed into a silica reactor, purged with N 2 gas to remove all impurities at a temperature of 573 K for 30 min, followed by injection of 1.35 g of n-hexadecane feed into the reactor for 80 s. After the reaction finished, the gas and liquid products were collected and characterized with GC-RGA and GC simulated distillation, respectively.

Characterization of Raw Materials
The detailed composition and SiO 2 /Al 2 O 3 ratio from Belitung kaolin is measured using XRF, before and after pre-treatment, is listed in Table 1. It reveals that in raw kaolin, SiO 2 and Al 2 O 3 were the predominant oxides with a mass ratio of 1.71. The SiO 2 /Al 2 O 3 ratio of metakaolin, as a result of dehydroxilation process to kaolin, is not different from that of kaolin. However while silica extraction has successfully removed 88% of aluminate (AlO 4 5-) and increased the silicate (SiO 4 ) content to 90.5%.
The metakaolin and extracted silica then were used as precursors in NaY synthesis. XRD patterns of starting materials ( Figure 1) shows that the structure of raw kaolin stays intact after purification, but then changed significantly after dehydroxylation processes to form metakaolin. The absence of kaolinite peaks at 2θ 12.36 • and 24.88 • indicates that the long-ordered pattern of layered aluminosilicate no longer existed due to dehydroxylation process, damaging bonding amongst silicate/aluminate in the structure. Further change is shown in the pattern of extracted silica, in which most of the peaks related to kaolinite structure [25], leaving the broad hump around 2θ 15 • -35 • , indicative of materials that became more amorphous. XRD patterns of starting materials ( Figure 1) shows that the structure of raw kaolin stays intact after purification, but then changed significantly after dehydroxylation processes to form metakaolin. The absence of kaolinite peaks at 2θ 12.36° and 24.88° indicates that the long-ordered pattern of layered aluminosilicate no longer existed due to dehydroxylation process, damaging bonding amongst silicate/aluminate in the structure. Further change is shown in the pattern of extracted silica, in which most of the peaks related to kaolinite structure [25], leaving the broad hump around 2 15°-35°, indicative of materials that became more amorphous.
FTIR spectra from Figure 2 shows that the spectra of raw materials, activated and purified kaolin had similar peaks. There were two sharp peaks between 3700 cm −1 and 3614 cm −1 assigned for stretching structural hydroxyl groups (-ν ~Si-OH and ~Al-OH respectively), typical from phyllosilicate aluminosilicates [26]. The 1650 cm −1 -1600 cm −1 band, corresponded attributed to adsorbed water molecule bending vibration (H-O-H), is observed. A group of large bands at 1121 cm −1 -1019 cm −1 , attributed to Si-O-Si(Al) asymmetric stretching vibration groups, 922 cm −1 for Al-OH groups, 785 cm −1 -698 cm −1 for Si-O-Al groups and 1400 cm −1 -420 cm −1 for Si-O covalent bond were observed. After dehydroxylation process, the two peaks attributed to ~Si-OH and ~Al-OH bands merged into one broad band at 3750 cm −1 -3500 cm −1 . A group of new peaks observed at 1500-1350 cm −1 attributed to Al-O-Al [27], separated from original Al-O-Si bonds appeared at 1121 cm −1 -1019 cm −1 . This result is in agreement with disruptive ~Al-O-Si~ after kaolin transformed to metakaolin [25]. Extracted silica also show different spectra from kaolin and metakaolin. It can be seen that the spectrum of extracted silica has broad peak for hydrogen bonded ~Si-OH group at 3700-3490 cm −1 , a peak attributed to adsorbed water molecule at 1620 cm −1 and broad peak at 1200-1000 cm −1 assigned for Si-O groups, while the peaks for ~Al-O groups disappeared. This is indicative of aluminum removal, supporting the XRD and XRF data and successful silica extraction.  FTIR spectra from Figure 2 shows that the spectra of raw materials, activated and purified kaolin had similar peaks. There were two sharp peaks between 3700 cm −1 and 3614 cm −1 assigned for stretching structural hydroxyl groups (-ν~Si-OH and~Al-OH respectively), typical from phyllosilicate aluminosilicates [26]. The 1650 cm −1 -1600 cm −1 band, attributed to adsorbed water molecule bending vibration (H-O-H), is observed. A group of large bands at 1121 cm −1 -1019 cm −1 , attributed to Si-O-Si(Al) asymmetric stretching vibration groups, 922 cm −1 for Al-OH groups, 785 cm −1 -698 cm −1 for Si-O-Al groups and 1400 cm −1 -420 cm −1 for Si-O covalent bond were observed. After dehydroxylation process, the two peaks attributed to~Si-OH and~Al-OH bands merged into one broad band at 3750 cm −1 -3500 cm −1 . A group of new peaks observed at 1500-1350 cm −1 attributed to Al-O-Al [27], separated from original Al-O-Si bonds appeared at 1121 cm −1 -1019 cm −1 . This result is in agreement with disruptive~Al-O-Si~after kaolin transformed to metakaolin [25]. Extracted silica also show different spectra from kaolin and metakaolin. It can be seen that the spectrum of extracted silica has broad peak for hydrogen bonded~Si-OH group at 3700-3490 cm −1 , a peak attributed to adsorbed water molecule at 1620 cm −1 and broad peak at 1200-1000 cm −1 assigned for Si-O groups, while the peaks for~Al-O groups disappeared. This is indicative of aluminum removal, supporting the XRD and XRF data and successful silica extraction.  Figure 3a displays the layered structure of kaolin, as a member of phyllosilicate group [12,26]. Meanwhile the metakaolin image in Figure 3b shows that the structure has been damaged and become amorphous after dehydroxylation. This is in agreement with the results reported in Abdullahi, et al. [28]. 29 Si and 27 Al solid state NMR measurements from Figure 4 were carried out to obtain more information on structural changes on kaolin before and after pre-treatment. Figure 4a shows the NMR spectra of raw kaolin. The 29 Si NMR spectra consists of a single peak at −90 ppm that attributed to Q 3 -Si tetrahedral with three bridges oxygen atom and one non bridge oxygen atom (3Si, 1Al), according to Stepanov, et al., 2016 [29], while the 27 Al NMR shows a single peak at 0 ppm which ascribed to octahedral Al [29]. This agrees to the structure of tetrahedral (SiO4)-octahedral (AlO6)-tetrahedral (SiO4) layers in raw kaolin. In metakaolin, as shown in Figure 4b, most of Si peak is still Q 3 but with poorer environment, but the Al peak is shifted to −60 ppm, which attributed to AlO4, the tetrahedral Al [30]. This indicates that after dehydroxylation, the layered structure of kaolin is fragmented to SiO4 and AlO4. Overall, from all the characterization results, the silicate and aluminate precursors for synthesis of NaY have successfully been provided.   Figure 3a displays the layered structure of kaolin, as a member of phyllosilicate group [12,26]. Meanwhile the metakaolin image in Figure 3b shows that the structure has been damaged and become amorphous after dehydroxylation. This is in agreement with the results reported in Abdullahi, et al. [28].

SEM Images in
. Figure 2. Fourier Transform-Infra Red spectra for the raw precursor materials. Figure 3a displays the layered structure of kaolin, as a member of phyllosilicate group [12,26]. Meanwhile the metakaolin image in Figure 3b shows that the structure has been damaged and become amorphous after dehydroxylation. This is in agreement with the results reported in Abdullahi, et al. [28]. 29 Si and 27 Al solid state NMR measurements from Figure 4 were carried out to obtain more information on structural changes on kaolin before and after pre-treatment. Figure 4a shows the NMR spectra of raw kaolin. The 29 Si NMR spectra consists of a single peak at −90 ppm that attributed to Q 3 -Si tetrahedral with three bridges oxygen atom and one non bridge oxygen atom (3Si, 1Al), according to Stepanov, et al., 2016 [29], while the 27 Al NMR shows a single peak at 0 ppm which ascribed to octahedral Al [29]. This agrees to the structure of tetrahedral (SiO4)-octahedral (AlO6)-tetrahedral (SiO4) layers in raw kaolin. In metakaolin, as shown in Figure 4b, most of Si peak is still Q 3 but with poorer environment, but the Al peak is shifted to −60 ppm, which attributed to AlO4, the tetrahedral Al [30]. This indicates that after dehydroxylation, the layered structure of kaolin is fragmented to SiO4 and AlO4. Overall, from all the characterization results, the silicate and aluminate precursors for synthesis of NaY have successfully been provided.   Figure 4 were carried out to obtain more information on structural changes on kaolin before and after pre-treatment. Figure 4a shows the NMR spectra of raw kaolin. The 29 Si NMR spectra consists of a single peak at −90 ppm that attributed to Q 3 -Si tetrahedral with three bridges oxygen atom and one non bridge oxygen atom (3Si, 1Al), according to Stepanov, et al., 2016 [29], while the 27 Al NMR shows a single peak at 0 ppm which ascribed to octahedral Al [29]. This agrees to the structure of tetrahedral (SiO 4 )-octahedral (AlO 6 )-tetrahedral (SiO 4 ) layers in raw kaolin. In metakaolin, as shown in Figure 4b, most of Si peak is still Q 3 but with poorer environment, but the Al peak is shifted to −60 ppm, which attributed to AlO 4 , the tetrahedral Al [30]. This indicates that after dehydroxylation, the layered structure of kaolin is fragmented to SiO 4 and AlO 4 . Overall, from all the characterization results, the silicate and aluminate precursors for synthesis of NaY have successfully been provided.

Synthesis of NaY Zeolite Seeds
The NaY seeds were prepared following the method reported by Liu, et al. [22] using two types of silicate sources, LUDOX HS40 and silica water, and compared to commercial NaY from Wako. The characterization results of the NaY seeds are explained below.
XRD pattern from Figure 5 shows the XRD patterns of NaY zeolites synthesis using LUDOX HS-40 and silica water as silicate sources, labeled NaY-LDX and NaY-SW respectively. They were compared to the pattern of NaY from Abbas, et al. [31] and Foster, et al. from IZA Online [32]. From this figure, it reveals that only NaY-LDX has typical peaks of NaY zeolite and has a similarity with NaY zeolite commercial. Thus, it was chosen as seed for the rest of NaY synthesis. . XRD data of as-synthesized NaY seeds synthesized using silica water (top) and LUDOX (middle) compared with commercial NaY (bottom). Figure 6 presents the infrared spectra of as-synthesized and commercial NaY zeolites. The broad band between 3650 cm −1 and 3405 cm −1 is attributed to the hydrogen-bonded silanol groups from the surface of zeolites, while peak at 1640 cm −1 indicates the existence of water molecule on the surface. The large peak at 1140-450 cm −1 is assigned for the lattice Si-O-Si or Si-O-Al vibrations. The peaks observed at finger print area below 700 cm −1 are similar to that of the typical peaks from NaY [26].

Synthesis of NaY Zeolite Seeds
The NaY seeds were prepared following the method reported by Liu, et al. [22] using two types of silicate sources, LUDOX HS40 and silica water, and compared to commercial NaY from Wako. The characterization results of the NaY seeds are explained below.
XRD pattern from Figure 5 shows the XRD patterns of NaY zeolites synthesis using LUDOX HS-40 and silica water as silicate sources, labeled NaY-LDX and NaY-SW respectively. They were compared to the pattern of NaY from Abbas, et al. [31] and Foster, et al. from IZA Online [32]. From this figure, it reveals that only NaY-LDX has typical peaks of NaY zeolite and has a similarity with NaY zeolite commercial. Thus, it was chosen as seed for the rest of NaY synthesis.

Synthesis of NaY Zeolite Seeds
The NaY seeds were prepared following the method reported by Liu, et al. [22] using two types of silicate sources, LUDOX HS40 and silica water, and compared to commercial NaY from Wako. The characterization results of the NaY seeds are explained below.
XRD pattern from Figure 5 shows the XRD patterns of NaY zeolites synthesis using LUDOX HS-40 and silica water as silicate sources, labeled NaY-LDX and NaY-SW respectively. They were compared to the pattern of NaY from Abbas, et al. [31] and Foster, et al. from IZA Online [32]. From this figure, it reveals that only NaY-LDX has typical peaks of NaY zeolite and has a similarity with NaY zeolite commercial. Thus, it was chosen as seed for the rest of NaY synthesis. . XRD data of as-synthesized NaY seeds synthesized using silica water (top) and LUDOX (middle) compared with commercial NaY (bottom). Figure 6 presents the infrared spectra of as-synthesized and commercial NaY zeolites. The broad band between 3650 cm −1 and 3405 cm −1 is attributed to the hydrogen-bonded silanol groups from the surface of zeolites, while peak at 1640 cm −1 indicates the existence of water molecule on the surface. The large peak at 1140-450 cm −1 is assigned for the lattice Si-O-Si or Si-O-Al vibrations. The peaks observed at finger print area below 700 cm −1 are similar to that of the typical peaks from NaY [26]. . XRD data of as-synthesized NaY seeds synthesized using silica water (top) and LUDOX (middle) compared with commercial NaY (bottom). Figure 6 presents the infrared spectra of as-synthesized and commercial NaY zeolites. The broad band between 3650 cm −1 and 3405 cm −1 is attributed to the hydrogen-bonded silanol groups from the surface of zeolites, while peak at 1640 cm −1 indicates the existence of water molecule on the surface. The large peak at 1140-450 cm −1 is assigned for the lattice Si-O-Si or Si-O-Al vibrations. The peaks observed at finger print area below 700 cm −1 are similar to that of the typical peaks from NaY [26]. . FTIR spectra of as-synthesized of NaY zeolite using NaY seeds generated from silica water (top) and LUDOX (middle), compared to commercial NaY (bottom).
The 29 Si and 27 Al solid state NMR from Figure 7 are very powerful probes to analyze the structure of Si and Al species in the aluminosilicate materials [29]. Figure 7 shows the 29 Si NMR spectra of the NaY-LDX, NaY-SW and commercial NaY zeolites. It can be seen from the results of the deconvolution of each material that there are five peaks at chemical shifts of −80 to −90 ppm, −85 to −95 ppm, −90 to −100 ppm, −95 to −105 ppm and −100 to −110 ppm that are observed, which respectively attributes to Q 0 Si (4Al), Q 1 Si (3Al), Q 2 Si (2Al), Q 3 Si (1Al) and Q 4 Si (0Al) that describes all types of -Si-O-Al-O-in the framework of zeolites [33]. In NaY-LDX, the highest intensity is shown by Q 2 which indicates that the SiO4 4− surrounded by two AlO4 5− are the dominating species in NaY-LDX framework, while Q 0 and Q 4 species are the lowest intensity, while both in NaY-SW and commercial NaY, Q 3 has the highest and Q 1 , Q 4 have similar intensities.
The 27 Al NMR spectra of all NaY zeolites show strong peak with chemical shifts between 50 and 70 ppm as an evidence of tetrahedral Al species in the framework [29]. However, a small peak at 0 ppm chemical shift, attributed to octahedral Al species, was observed in NaY-SW spectrum. This indicates that NaY-SW contains not only framework-Al species but also Al on the surfaces so NaY-SW has poorer structure compared to NaY-LDX. The NMR data analysis supports the XRD result to use NaY-LDX as seed in NaY synthesis. So, in this research, NaY LDX was chosen as seed for the next NaY synthesis. Figure 6. FTIR spectra of as-synthesized of NaY zeolite using NaY seeds generated from silica water (top) and LUDOX (middle), compared to commercial NaY (bottom).
The 29 Si and 27 Al solid state NMR from Figure 7 are very powerful probes to analyze the structure of Si and Al species in the aluminosilicate materials [29]. Figure 7 shows the 29 Si NMR spectra of the NaY-LDX, NaY-SW and commercial NaY zeolites. It can be seen from the results of the deconvolution of each material that there are five peaks at chemical shifts of −80 to −90 ppm, −85 to −95 ppm, −90 to −100 ppm, −95 to −105 ppm and −100 to −110 ppm that are observed, which respectively attributes to Q 0 Si (4Al), Q 1 Si (3Al), Q 2 Si (2Al), Q 3 Si (1Al) and Q 4 Si (0Al) that describes all types of -Si-O-Al-O-in the framework of zeolites [33]. In NaY-LDX, the highest intensity is shown by Q 2 which indicates that the SiO 4 4− surrounded by two AlO 4 5− are the dominating species in NaY-LDX framework, while Q 0 and Q 4 species are the lowest intensity, while both in NaY-SW and commercial NaY, Q 3 has the highest and Q 1 , Q 4 have similar intensities. Figure 6. FTIR spectra of as-synthesized of NaY zeolite using NaY seeds generated from silica water (top) and LUDOX (middle), compared to commercial NaY (bottom).
The 29 Si and 27 Al solid state NMR from Figure 7 are very powerful probes to analyze the structure of Si and Al species in the aluminosilicate materials [29]. Figure 7 shows the 29 Si NMR spectra of the NaY-LDX, NaY-SW and commercial NaY zeolites. It can be seen from the results of the deconvolution of each material that there are five peaks at chemical shifts of −80 to −90 ppm, −85 to −95 ppm, −90 to −100 ppm, −95 to −105 ppm and −100 to −110 ppm that are observed, which respectively attributes to Q 0 Si (4Al), Q 1 Si (3Al), Q 2 Si (2Al), Q 3 Si (1Al) and Q 4 Si (0Al) that describes all types of -Si-O-Al-O-in the framework of zeolites [33]. In NaY-LDX, the highest intensity is shown by Q 2 which indicates that the SiO4 4− surrounded by two AlO4 5− are the dominating species in NaY-LDX framework, while Q 0 and Q 4 species are the lowest intensity, while both in NaY-SW and commercial NaY, Q 3 has the highest and Q 1 , Q 4 have similar intensities.
The 27 Al NMR spectra of all NaY zeolites show strong peak with chemical shifts between 50 and 70 ppm as an evidence of tetrahedral Al species in the framework [29]. However, a small peak at 0 ppm chemical shift, attributed to octahedral Al species, was observed in NaY-SW spectrum. This indicates that NaY-SW contains not only framework-Al species but also Al on the surfaces so NaY-SW has poorer structure compared to NaY-LDX. The NMR data analysis supports the XRD result to use NaY-LDX as seed in NaY synthesis. So, in this research, NaY LDX was chosen as seed for the next NaY synthesis. The 27 Al NMR spectra of all NaY zeolites show strong peak with chemical shifts between 50 and 70 ppm as an evidence of tetrahedral Al species in the framework [29]. However, a small peak at 0 ppm chemical shift, attributed to octahedral Al species, was observed in NaY-SW spectrum. This indicates that NaY-SW contains not only framework-Al species but also Al on the surfaces so NaY-SW has poorer Crystals 2019, 9, 404 8 of 14 structure compared to NaY-LDX. The NMR data analysis supports the XRD result to use NaY-LDX as seed in NaY synthesis. So, in this research, NaY LDX was chosen as seed for the next NaY synthesis.

Synthesis NaY Zeolite
Two batches of NaY were synthesized using NaY-LDX as seed 5% (w/w) and silica sources from treated natural Belitung kaolin, i.e., extracted silica (labelled as NaY-SE) and extracted silica with metakaolin (named as NaY-MKSE). The characterization on the two as-synthesized materials are explained below.
SEM images in Figure 8 shows from NaY-LDX has a cuboid shape and sharp edges. Both of NaY-MKSE and NaY-SE also showed similar structure with NaY-LDX. However, the crystal habits of NaY-MKSE and NaY-SE are smaller and not as well-developed as those from NaY-LDX. This is due to defects that were caused by impurities from metakaolin or extracted silica. . 29 Si MAS NMR data (top) and 27 Al MAS NMR data (bottom) of (a) NaY-LDX; (b) NaY-SW and (c) commercial NaY.

Synthesis NaY Zeolite
Two batches of NaY were synthesized using NaY-LDX as seed 5% (w/w) and silica sources from treated natural Belitung kaolin, i.e., extracted silica (labelled as NaY-SE) and extracted silica with metakaolin (named as NaY-MKSE). The characterization on the two as-synthesized materials are explained below.
SEM images in Figure 8 shows from NaY-LDX has a cuboid shape and sharp edges. Both of NaY-MKSE and NaY-SE also showed similar structure with NaY-LDX. However, the crystal habits of NaY-MKSE and NaY-SE are smaller and not as well-developed as those from NaY-LDX. This is due to defects that were caused by impurities from metakaolin or extracted silica.  Table 2 shows the chemical composition of NaY, measured with XRF. Overall, the SiO2/Al2O3 ratio of the three NaY zeolites are within the range of the SiO2/Al2O3 ratio for Y zeolite [9], in which the value was increased from NaY-LDX, NaY-MKSE to NaY-SE. The latter has the highest ratio due to the use of extracted silicate as silica source.  As a supporting data, the measurement using FTIR was also performed. As seen in the Figure 9, the FTIR spectra of the NaY zeolite shows the bands in the range of 3560-3200 cm −1 are due to hydrogen-bonded silanol groups on the surface (~Si-OH) and bands in the region of 1140-450 cm −1 are due to the lattice Si-O-Si or Si-O-Al vibrations.  Table 2 shows the chemical composition of NaY, measured with XRF. Overall, the SiO 2 /Al 2 O 3 ratio of the three NaY zeolites are within the range of the SiO 2 /Al 2 O 3 ratio for Y zeolite [9], in which the value was increased from NaY-LDX, NaY-MKSE to NaY-SE. The latter has the highest ratio due to the use of extracted silicate as silica source. As a supporting data, the measurement using FTIR was also performed. As seen in the Figure 9, the FTIR spectra of the NaY zeolite shows the bands in the range of 3560-3200 cm −1 are due to hydrogen-bonded silanol groups on the surface (~Si-OH) and bands in the region of 1140-450 cm −1 are due to the lattice Si-O-Si or Si-O-Al vibrations. As seen, Figure 10 shows XRD Pattern for as-synthesized NaY that both NaY-SE and NaY-MKSE have all typical peaks of NaY zeolites and in agreement with the pattern from commercially available NaY. Crystallinity of zeolite have been calculated by taking the sum total of relatives intensities of characteristic peaks (2 6.2°; 15.6°; 22.1°) following Equation (1). In this research, NaY-LDX is used as the standard.

Crystallinity Index = Sum Total of Relatives Intensities of NaY Observed Sum Total of Relatives Intensities of NaY Standard × 100%
(1) Table 3 summarizes the degree of crystallinity of all as-synthesized zeolites. The calculation on NaY-SW shows that it has low crystallinity (0.51%) while commercial NaY has the highest crystallinity (45.00%). As for NaY-MKSE and NaY-SE, their degree of crystallinity is 18.22% and 35.80%, respectively.  As seen, Figure 10 shows XRD Pattern for as-synthesized NaY that both NaY-SE and NaY-MKSE have all typical peaks of NaY zeolites and in agreement with the pattern from commercially available NaY. As seen, Figure 10 shows XRD Pattern for as-synthesized NaY that both NaY-SE and NaY-MKSE have all typical peaks of NaY zeolites and in agreement with the pattern from commercially available NaY. Figure 10. XRD data of as-synthesized NaY zeolites from natural and synthetic precursor materials: NaY-SE (top), NaY-MKSE (middle) and NaY-LDX (bottom).
Crystallinity of zeolite have been calculated by taking the sum total of relatives intensities of characteristic peaks (2 6.2°; 15.6°; 22.1°) following Equation (1). In this research, NaY-LDX is used as the standard.
Crystallinity Index = Sum Total of Relatives Intensities of NaY Observed Sum Total of Relatives Intensities of NaY Standard × 100% (1) Table 3 summarizes the degree of crystallinity of all as-synthesized zeolites. The calculation on NaY-SW shows that it has low crystallinity (0.51%) while commercial NaY has the highest crystallinity (45.00%). As for NaY-MKSE and NaY-SE, their degree of crystallinity is 18.22% and 35.80%, respectively.  Crystallinity of zeolite have been calculated by taking the sum total of relatives intensities of characteristic peaks (2θ 6.2 • ; 15.6 • ; 22.1 • ) following Equation (1). In this research, NaY-LDX is used as the standard.
Crystallinity Index = Sum Total of Relatives Intensities of NaY Observed Sum Total of Relatives Intensities of NaY Standard × 100% (1) Table 3 summarizes the degree of crystallinity of all as-synthesized zeolites. The calculation on NaY-SW shows that it has low crystallinity (0.51%) while commercial NaY has the highest crystallinity (45.00%). As for NaY-MKSE and NaY-SE, their degree of crystallinity is 18.22% and 35.80%, respectively.
Surface area analyses were carried out on the three crystalline as-synthesized NaY zeolites and the results are shown in Figure 11 and Table 4. Figure 11a showing the adsorption-desorption isotherm from all zeolites confirms that all zeolites are microporous materials [22]. This is proofed further by Figure 11b displaying that the distribution of pore radii (r pore ) lies at 1.14 nm. Furthermore, the NaY-LDX has the highest surface, followed by NaY-MKSE and NaY-SE, respectively.  Surface area analyses were carried out on the three crystalline as-synthesized NaY zeolites and the results are shown in Figure 11 and Table 4. Figure 11a showing the adsorption-desorption isotherm from all zeolites confirms that all zeolites are microporous materials [22]. This is proofed further by Figure 11b displaying that the distribution of pore radii (rpore) lies at 1.14 nm. Furthermore, the NaY-LDX has the highest surface, followed by NaY-MKSE and NaY-SE, respectively. Table 4. The surface area analysis results of the as-synthesized NaY preparations.

Materials
Surface Area Pore Volume (V) rpore SBET (m 2 /g) SEXT (m 2 /g) Smikro (m 2 /g) Vtotal (cm 3 /g) Vmeso (cm 3 /g) Vmikro (cm 3 /g) (nm) NMR analysis in Figure 12 shows the comparison of 29 Si and 27 Al NMR spectra of NaY-MKSE and NaY-SE. It can be seen that the dominant species in both as-synthesized NaY is Q 3 Si (1Al), followed by equal amount of Q 2 Si (2Al) and Q 1 Si (3Al) species and weaker peak for Q 0 Si (4Al) at −80 to −90 ppm. Interestingly, only a shoulder peak was observed at −100 to −110 ppm, assigned for Q 4 Si (0Al). No peaks were observed in CP MAS Si NMR, indicating no significant amount of ~Si-OH exist on the surface of the zeolites.  NMR analysis in Figure 12 shows the comparison of 29 Si and 27 Al NMR spectra of NaY-MKSE and NaY-SE. It can be seen that the dominant species in both as-synthesized NaY is Q 3 Si (1Al), followed by equal amount of Q 2 Si (2Al) and Q 1 Si (3Al) species and weaker peak for Q 0 Si (4Al) at −80 to −90 ppm. Interestingly, only a shoulder peak was observed at −100 to −110 ppm, assigned for Q 4 Si (0Al). No peaks were observed in CP MAS Si NMR, indicating no significant amount of~Si-OH exist on the surface of the zeolites.
The 27 Al NMR spectra of the as-synthesized NaY zeolites show a strong peak with chemical shifts between 50 and 70 ppm as an evidence of tetrahedral Al species in the framework [29]. However, a small peak at 0 ppm chemical shift, attributed to octahedral Al species, was also observed, indicating that the zeolites have defective Al species to form an extended-framework on the surfaces.
NMR analysis in Figure 12 shows the comparison of 29 Si and 27 Al NMR spectra of NaY-MKSE and NaY-SE. It can be seen that the dominant species in both as-synthesized NaY is Q 3 Si (1Al), followed by equal amount of Q 2 Si (2Al) and Q 1 Si (3Al) species and weaker peak for Q 0 Si (4Al) at −80 to −90 ppm. Interestingly, only a shoulder peak was observed at −100 to −110 ppm, assigned for Q 4 Si (0Al). No peaks were observed in CP MAS Si NMR, indicating no significant amount of ~Si-OH exist on the surface of the zeolites.

Preparation of HY Zeolites as Cracking Catalysts
In general, cracking reaction of long chain alkane requires Brønsted acid catalyst, in which zeolite can be used as so that heterogeneous acid catalyst as the silanol groups (-SiOH) play a role as acidic sites, providing H + ions [34]. NaY zeolites were exchanged to NH 4 Y then calcined to remove NH 3 and providing mobile H + balancing the charge in the framework of zeolite. The H-type zeolites were labeled as HY-LDX, HY-MKSE, HY-SE, respectively. Figure 13 shows XRD pattern of HY zeolites which very much resemble their parent NaY zeolites, while the SiO 2 /Al 2 O 3 ratio (for brevity, the XRF results are not shown) of each zeolite stays in the same range of NaY zeolites (3.53-3.98). Thus, it can be concluded that the structure of Y zeolites is not damaged during preparation of HY zeolites. The 27 Al NMR spectra of the as-synthesized NaY zeolites show a strong peak with chemical shifts between 50 and 70 ppm as an evidence of tetrahedral Al species in the framework [29]. However, a small peak at 0 ppm chemical shift, attributed to octahedral Al species, was also observed, indicating that the zeolites have defective Al species to form an extended-framework on the surfaces.

Preparation of HY Zeolites as Cracking Catalysts
In general, cracking reaction of long chain alkane requires Brønsted acid catalyst, in which zeolite can be used as so that heterogeneous acid catalyst as the silanol groups (-SiOH) play a role as acidic sites, providing H + ions [34]. NaY zeolites were exchanged to NH4Y then calcined to remove NH3 and providing mobile H + balancing the charge in the framework of zeolite. The H-type zeolites were labeled as HY-LDX, HY-MKSE, HY-SE, respectively. Figure 13 shows XRD pattern of HY zeolites which very much resemble their parent NaY zeolites, while the SiO2/Al2O3 ratio (for brevity, the XRF results are not shown) of each zeolite stays in the same range of NaY zeolites (3.53-3.98). Thus, it can be concluded that the structure of Y zeolites is not damaged during preparation of HY zeolites.

n-Hexadecane Catalytic Cracking
The modified HY zeolites are tested as catalysts in the cracking reaction using n-hexadecane as the model compound. The catalytic activities were analyzed from the percentage conversion (%X), yield (%Y) and selectivity (%Y) toward C5-C12 compounds representing gasoline that is described in Figures 14 and 15. Figure 14 shows that the highest catalytic activity in n-hexadecane cracking reaction is given by HY-LDX, followed by HY-SE and HY-MKSE.

n-Hexadecane Catalytic Cracking
The modified HY zeolites are tested as catalysts in the cracking reaction using n-hexadecane as the model compound. The catalytic activities were analyzed from the percentage conversion (%X), yield (%Y) and selectivity (%Y) toward C 5 -C 12 compounds representing gasoline that is described in Figures 14 and 15. Figure 14 shows that the highest catalytic activity in n-hexadecane cracking reaction is given by HY-LDX, followed by HY-SE and HY-MKSE.  Figure 15 compares the selectivity to each gasoline product (C5-C12) when using the three catalysts. It can be seen that the product with the highest percentage of selectivity is C5 compound (n-pentane and iso-pentane). Interestingly, HY-SE is also selective to C8 (n-octane and iso-octane) while other HY catalysts are less selective.

Discussion
The results presented above shows that the transformation from layered structure kaolin to three-dimensional NaY zeolites is successfully performed. Pre-treatment procedure, in which the kaolin structure was fragmented to become metakaolin as well as the extraction of silica becomes an important step to prepare adequate silicate and aluminate precursors for the next step, building the NaY framework. The characterization on the starting materials, the kaolin-based precursors as well as the as-synthesized NaY have been able to prove almost the entire steps. The crystallinity and physical-chemical properties of kaolin based-NaY are also comparable to that of pro analysis-NaY. As an implication, their catalytic activity as cracking catalyst, in HY-form, are also comparable compared to the pristine pro analysis-NaY. This finding could be taken into account when alternative sources of precursors for materials synthesis that meet the green chemistry concept yet affordable, are required. Further study has to be carried out to improve the pre-treatment techniques to obtain much smaller fragment of silicate and aluminate from kaolin also with higher purity.  Figure 15 compares the selectivity to each gasoline product (C5-C12) when using the three catalysts. It can be seen that the product with the highest percentage of selectivity is C5 compound (n-pentane and iso-pentane). Interestingly, HY-SE is also selective to C8 (n-octane and iso-octane) while other HY catalysts are less selective.

Discussion
The results presented above shows that the transformation from layered structure kaolin to three-dimensional NaY zeolites is successfully performed. Pre-treatment procedure, in which the kaolin structure was fragmented to become metakaolin as well as the extraction of silica becomes an important step to prepare adequate silicate and aluminate precursors for the next step, building the NaY framework. The characterization on the starting materials, the kaolin-based precursors as well as the as-synthesized NaY have been able to prove almost the entire steps. The crystallinity and physical-chemical properties of kaolin based-NaY are also comparable to that of pro analysis-NaY. As an implication, their catalytic activity as cracking catalyst, in HY-form, are also comparable compared to the pristine pro analysis-NaY. This finding could be taken into account when alternative sources of precursors for materials synthesis that meet the green chemistry concept yet affordable, are required. Further study has to be carried out to improve the pre-treatment techniques to obtain much smaller fragment of silicate and aluminate from kaolin also with higher purity.  Figure 15 compares the selectivity to each gasoline product (C 5 -C 12 ) when using the three catalysts. It can be seen that the product with the highest percentage of selectivity is C 5 compound (n-pentane and iso-pentane). Interestingly, HY-SE is also selective to C 8 (n-octane and iso-octane) while other HY catalysts are less selective.

Discussion
The results presented above shows that the transformation from layered structure kaolin to three-dimensional NaY zeolites is successfully performed. Pre-treatment procedure, in which the kaolin structure was fragmented to become metakaolin as well as the extraction of silica becomes an important step to prepare adequate silicate and aluminate precursors for the next step, building the NaY framework. The characterization on the starting materials, the kaolin-based precursors as well as the as-synthesized NaY have been able to prove almost the entire steps. The crystallinity and physical-chemical properties of kaolin based-NaY are also comparable to that of pro analysis-NaY. As an implication, their catalytic activity as cracking catalyst, in HY-form, are also comparable compared to the pristine pro analysis-NaY. This finding could be taken into account when alternative sources of precursors for materials synthesis that meet the green chemistry concept yet affordable, are required. Further study has to be carried out to improve the pre-treatment techniques to obtain much smaller fragment of silicate and aluminate from kaolin also with higher purity.

Conclusions
It can be concluded that transformation from layer structured kaolin to tectosilicate structure of NaY was successful. Kaolin can be utilized as aluminate and silicate sources through metakaolinization and silica extraction process. The presence of crystalline NaY seeds is important in NaY zeolite synthesis using either synthetic or natural precursor. Furthermore, the kaolin-based HY has shown high performance as an active catalyst in the cracking reaction of n-hexadecane.