Preparation of Various Nanomaterials via Controlled Gelation of a Hydrophilic Polymer Bearing Metal-Coordination Units with Metal Ions

We investigated the gelation of a hydrophilic polymer with metal-coordination units (HPMC) and metal ions (PdII or AuIII). Gelation proceeded by addition of an HPMC solution in N-methyl-2-pyrrolidone (NMP) to a metal ion aqueous solution. An increase in the composition ratio of the metal-coordination units from 10 mol% to 34 mol% (HPMC-34) increased the cross-linking rate with AuIII. Cross-linking immediately occurred after dropwise addition of an HPMC-34 solution to the AuIII solution, generating the separation between the phases of HPMC-34 and AuIII. The cross-linking of AuIII proceeded from the surface to the inside of the HPMC-34 droplets, affording spherical gels. In contrast, a decrease in the ratio of metal-coordination units from 10 mol% to 4 mol% (HPMC-4) decreased the PdII cross-linking rate. The cross-linking occurred gradually and the gels extended to the bottom of the vessel, forming fibrous gels. On the basis of the mechanism for the formation of gels with different morphologies, the gelation of HPMC-34 and AuIII provided nanosheets via gelation at the interface between the AuIII solution and the HPMC-34 solution. The gelation of HPMC-4 and PdII afforded nanofibers by a facile method, i.e., dropwise addition of the HPMC-4 solution to the PdII solution. These results demonstrated that changing the composition ratio of the metal-coordination units in HPMC can control the gelation behavior, resulting in different types of nanomaterials.


Introduction
Organic-inorganic hybrid materials, which consist of organic polymers containing inorganic metals dispersed at the nanometer scale, have generated a great deal of interest due to their unique properties such as flexibility, high transparency, high reactivity, and mechanical and thermal stabilities [1][2][3][4][5]. For example, nanofibers containing metal ions or nanoparticles are promising candidates for various applications including tissue engineering, blood vessels, drug delivery, protective clothing, filtration, catalysis, and sensors [6][7][8][9][10]. The most common method of fabricating such nanofiber is an electrospinning method using a polymer solution containing metal ions or nanoparticles. However, electrospinning requires expensive instruments, cumbersome operations, and high voltage, and thus it runs the risk of electrical shock. Dispersing metal nanoparticles in the polymer solution is also difficult [11][12][13]. Therefore, the development of a facile method for fabricating nanofibers is greatly desired. Nanosheet materials also have unique physical and chemical properties, which are derived from their two-dimensional nature [14][15][16][17][18]. Nanosheets can be synthesized with a bottom-up method [19][20][21][22][23], which occurs at the interface between an organic polydentate ligand and an aqueous layer containing metal ions. This approach has advantages compared to the top-down approach, which produces nanosheets by exfoliation of bulk layered materials such as graphene. First, the composition, structure, and other properties can be adjusted by selection of the ligand molecules and metal ions. Second, the produced nanosheets are not limited to layers of bulk materials. Therefore, a bottom-up synthesis broadens the diversity and utility of nanosheets.
We previously investigated the gelation behavior of a hydrophilic polymer bearing metal-coordination units (denoted as HPMC) with metal ions (Pd II or Au III ) upon addition of a dispersed aqueous solution of HPMC-8 to an aqueous solution of metal ions [24,25]. HPMC-8 consists of thiocarbonyl groups (8 mol%) for metal coordination and hydroxyl groups (92%) for hydrophilicity ( Figure 1a). The gelation of HPMC-8 with Pd II or Au III afforded spherical and fibrous gels, respectively (Figure 1b,c). Consequently, gels with different morphologies were found to be formed depending on the metal ions. The formation of different morphologies can be explained by the cross-linking rate. The cross-linking with Pd II occurred immediately after dropwise addition of the dispersed aqueous solution of HPMC-8 to the Pd II solution, generating the separation between aqueous phases of HPMC-8 and Pd II (Figure 1b). The cross-linking of Pd II proceeded from the surface to the inside of the droplets of HPMC, resulting in the formation of spherical gels. In contrast, the cross-linking with Au III occurred gradually and the gels extended to the bottom due to the slower cross-linking rate, forming fibrous gels (Figure 1c). On the basis of this mechanism for the formation of gels with different morphologies, the gelation of HPMC-8 with Au III provided nanofiber containing uniformly dispersed Au nanoparticles by a facile method, i.e., dropwise addition of a dispersed aqueous solution of HPMC-8 to an aqueous solution of Au III ions [24]. In contrast, the faster gelation of HPMC-8 with Pd II provided nanosheets containing uniformly dispersed Pd II ions via gelation at the interface between the aqueous phases of Pd II and HPMC-8 [25]. Nanosheets can be synthesized with a bottom-up method [19][20][21][22][23], which occurs at the interface between an organic polydentate ligand and an aqueous layer containing metal ions. This approach has advantages compared to the top-down approach, which produces nanosheets by exfoliation of bulk layered materials such as graphene. First, the composition, structure, and other properties can be adjusted by selection of the ligand molecules and metal ions. Second, the produced nanosheets are not limited to layers of bulk materials. Therefore, a bottom-up synthesis broadens the diversity and utility of nanosheets. We previously investigated the gelation behavior of a hydrophilic polymer bearing metal-coordination units (denoted as HPMC) with metal ions (Pd II or Au III ) upon addition of a dispersed aqueous solution of HPMC-8 to an aqueous solution of metal ions [24,25]. HPMC-8 consists of thiocarbonyl groups (8 mol%) for metal coordination and hydroxyl groups (92%) for hydrophilicity ( Figure 1a). The gelation of HPMC-8 with Pd II or Au III afforded spherical and fibrous gels, respectively (Figure 1b,c). Consequently, gels with different morphologies were found to be formed depending on the metal ions. The formation of different morphologies can be explained by the cross-linking rate. The crosslinking with Pd II occurred immediately after dropwise addition of the dispersed aqueous solution of HPMC-8 to the Pd II solution, generating the separation between aqueous phases of HPMC-8 and Pd II (Figure 1b). The cross-linking of Pd II proceeded from the surface to the inside of the droplets of HPMC, resulting in the formation of spherical gels. In contrast, the cross-linking with Au III occurred gradually and the gels extended to the bottom due to the slower cross-linking rate, forming fibrous gels ( Figure 1c). On the basis of this mechanism for the formation of gels with different morphologies, the gelation of HPMC-8 with Au III provided nanofiber containing uniformly dispersed Au nanoparticles by a facile method, i.e., dropwise addition of a dispersed aqueous solution of HPMC-8 to an aqueous solution of Au III ions [24]. In contrast, the faster gelation of HPMC-8 with Pd II provided nanosheets containing uniformly dispersed Pd II ions via gelation at the interface between the aqueous phases of Pd II and HPMC-8 [25].   Encouraged by these results, we attempted to control the gelation behavior and synthesize different types of nanomaterials by changing the composition ratio of the metal-coordination units in HPMC. An increase in the composition ratio increased the cross-linking rate with Au III , resulting in the formation of spherical gels and Au nanosheets instead of nanofibers. A decrease in the ratio decreased the cross-linking rate with Pd II , affording fibrous gels and Pd nanofiber instead of nanosheets. Thus, changing the composition ratio of the metal-coordination units can provide contrasting gelation behavior and nanomaterials. We expect that this procedure will become a controlled manufacturing method for various types of nanomaterials containing various metals.

Synthesis of HPMC and Its Gelation Behavior with Metal Ions
HPMC containing thiocarbonyl and hydroxyl groups was synthesized according to our previous report [24]. HPMC with metal-coordination unit content of 10% (denoted as HPMC-10) was synthesized by reacting poly(vinyl alcohol) and methyl isothiocyanate in dimethyl sulfoxide at 40 • C for 20 h (Scheme 1). HPMC with metal-coordination unit content of 34% (HPMC-34) and HPMC with metal-coordination unit content of 4% (HPMC-4) were synthesized by the above similar method. Encouraged by these results, we attempted to control the gelation behavior and synthesize different types of nanomaterials by changing the composition ratio of the metalcoordination units in HPMC. An increase in the composition ratio increased the crosslinking rate with Au III , resulting in the formation of spherical gels and Au nanosheets instead of nanofibers. A decrease in the ratio decreased the cross-linking rate with Pd II , affording fibrous gels and Pd nanofiber instead of nanosheets. Thus, changing the composition ratio of the metal-coordination units can provide contrasting gelation behavior and nanomaterials. We expect that this procedure will become a controlled manufacturing method for various types of nanomaterials containing various metals.

Synthesis of HPMC and Its Gelation Behavior with Metal Ions
HPMC containing thiocarbonyl and hydroxyl groups was synthesized according to our previous report [24]. HPMC with metal-coordination unit content of 10% (denoted as HPMC-10) was synthesized by reacting poly(vinyl alcohol) and methyl isothiocyanate in dimethyl sulfoxide at 40 °C for 20 h (Scheme 1). HPMC with metal-coordination unit content of 34% (HPMC-34) and HPMC with metal-coordination unit content of 4% (HPMC-4) were synthesized by the above similar method. The gelation behavior of HPMC-34 and Au III was compared to that of HPMC-10 and Au III to examine the effect of the increase in the composition ratio of the metal-coordination unit. N-Methyl-2-pyrrolidone (NMP) solutions of HPMC-10 or HPMC-34 (13 wt%, 0.2 mL) were added to 4.0 mM NaAuCl4 aqueous solutions (5 mL). In the gelation of HPMC-10, Au III ions gradually cross-linked from the surface to the inside phase of HPMC-10 and the gels extended to the bottom of the container, forming fibrous gels ( Figure 2a). In contrast, gelation of HPMC-34 with Au III generated instant separation between the phases of HPMC-34 and Au III (Figure 2b). The separation originated from the immediate cross-linking reaction at the interface and the higher hydrophobicity of the HPMC-34 phase than that of the Au III phase. The cross-linking with Au III ions proceeded from the surface to the inside of the HPMC-34 droplets, resulting in the formation of spherical gels. To observe a microscopic region of the resulting gels, scanning electron microscope (SEM) observations were conducted. Similar to the gel shapes in the photographs (Figure 2a The gelation behavior of HPMC-34 and Au III was compared to that of HPMC-10 and Au III to examine the effect of the increase in the composition ratio of the metal-coordination unit. N-Methyl-2-pyrrolidone (NMP) solutions of HPMC-10 or HPMC-34 (13 wt%, 0.2 mL) were added to 4.0 mM NaAuCl 4 aqueous solutions (5 mL). In the gelation of HPMC-10, Au III ions gradually cross-linked from the surface to the inside phase of HPMC-10 and the gels extended to the bottom of the container, forming fibrous gels (Figure 2a). In contrast, gelation of HPMC-34 with Au III generated instant separation between the phases of HPMC-34 and Au III (Figure 2b). The separation originated from the immediate crosslinking reaction at the interface and the higher hydrophobicity of the HPMC-34 phase than that of the Au III phase. The cross-linking with Au III ions proceeded from the surface to the inside of the HPMC-34 droplets, resulting in the formation of spherical gels. To observe a microscopic region of the resulting gels, scanning electron microscope (SEM) observations were conducted. Similar to the gel shapes in the photographs (Figure 2a,b), SEM analysis showed fibrous shapes from HPMC-10-Au and a rough surface from HPMC-34-Au (Figure 2c,d). To determine the coordination sites, the IR measurements of HPMC-34 and HPMC-34-Au were carried out (Figure 2e). The absorption peak around 1535 cm −1 assigned to the C=S stretching vibration shifted to 1555 cm −1 , and the peak intensity became smaller after the gelation. Therefore, it was found that different gelation behaviors and gel shapes were obtained depending on the composition ratio of the metal-coordination units. 1535 cm −1 assigned to the C=S stretching vibration shifted to 1555 cm −1 , and the peak intensity became smaller after the gelation. Therefore, it was found that different gelation behaviors and gel shapes were obtained depending on the composition ratio of the metalcoordination units. A kinetic study and the gel fraction were examined to explain the mechanism for the formation of the different shaped gels. Cross-linking rates of HPMC-34 and HPMC-10 with Au III ions were compared. Figure 2f shows the time course of the cross-linking amount determined by the method in the literature [24]. As shown in Figure 2f, the crosslinking rate of HPMC-34 was faster than that of HPMC-10 due to the increase in the metalcoordination units. The experimental kinetic data were fitted with a pseudo-first-order kinetic equation [26,27]: (1) where qe and qt are the amounts of metal ion cross-linked (gmetal/gpoly, metal amount adsorbed per gram of polymer) at equilibrium and at t, and k is the pseudo-first-order rate constant (min −1 ). In the case of cross-linking reaction of HPMC-34, k was estimated to be 10.8 × 10 −2 min −1 (R 2 = 0.9712), which was faster than that for HPMC-10 (7.02 × 10 −2 min −1 , R 2 = 0.9821). The gel fraction indicates the cross-linking density of the gels determined by removing soluble parts using Soxhlet extraction. Gel fractions of the gels from HPMC-34 A kinetic study and the gel fraction were examined to explain the mechanism for the formation of the different shaped gels. Cross-linking rates of HPMC-34 and HPMC-10 with Au III ions were compared. Figure 2f shows the time course of the cross-linking amount determined by the method in the literature [24]. As shown in Figure 2f, the cross-linking rate of HPMC-34 was faster than that of HPMC-10 due to the increase in the metal-coordination units. The experimental kinetic data were fitted with a pseudo-firstorder kinetic equation [26,27]: log(q e − q t ) = kt/2.303 (1) where q e and q t are the amounts of metal ion cross-linked (g metal /g poly , metal amount adsorbed per gram of polymer) at equilibrium and at t, and k is the pseudo-first-order rate constant (min −1 ). In the case of cross-linking reaction of HPMC-34, k was estimated to be 10.8 × 10 −2 min −1 (R 2 = 0.9712), which was faster than that for HPMC-10 (7.02 × 10 −2 min −1 , R 2 = 0.9821). The gel fraction indicates the cross-linking density of the gels determined by removing soluble parts using Soxhlet extraction. Gel fractions of the gels from HPMC-34 and HPMC-10 were 0.76 and 0.14, respectively, indicating that the cross-linking density of HPMC-34-Au was higher than that of HPMC-10-Au. On the basis of the results, a mechanism for the formation of the different morphologies was proposed. The cross-linking rate of HPMC-34 and Au III was faster than that of HPMC-10. In the cross-linking of HPMC-34, gelation with Au III occurred immediately at the surface of the droplets after the dropwise addition of the HPMC solution to the Au III solution. Gelation proceeded by immersing Au III inside of the droplets, forming the higher cross-linking density and spherical gels. Contrastingly, due to the slower cross-linking rate of HPMC-10, the cross-linking occurred gradually with the diffusion of Au III from the surface to the inside of the HPMC-10 phase, resulting in the formation of the lower cross-linking density and fibrous gels.
Next, to examine the effect of the decrease in the ratio of metal-coordination units on the gelation, the gelation behavior of HPMC-4 and Pd II was compared to that of HPMC-10 with Pd II . NMP solutions of HPMC-10 or HPMC-4 (13 wt%, 0.2 mL) were added to 4.0 mM Na 2 PdCl 4 aqueous solutions (5 mL). In the gelation of HPMC-10, immediate separation occurred between the HPMC-10 and Pd II phases (Figure 3a), whose separation originated from the fast cross-linking at the interface. The cross-linking with Pd II proceeded from the surface to the inside of the HPMC-10 droplets, affording the spherical gels. In contrast, gelation of HPMC-4 and Pd II occurred gradually from the surface to the inside of HPMC-4 phase, and the gels were extended to the bottom of the container, forming the fibrous gels. To observe a microscopic region, SEM analysis of the obtained gels was conducted. Similar to the gel shapes (Figure 3a,b), the SEM analysis revealed a rough surface from HPMC-10-Pd and fibrous shapes from HPMC-4-Pd (Figure 3c,d). To determine the coordination site, IR measurements of HPMC-4 and HPMC-4-Pd were conducted (Figure 3e). The absorption peak at 1550 cm −1 attributable to the C=S stretching vibration became smaller after cross-linking, indicating that the sulfur of the thiocarbonyl group was coordinated to Pd II . and HPMC-10 were 0.76 and 0.14, respectively, indicating that the cross-linking density of HPMC-34-Au was higher than that of HPMC-10-Au. On the basis of the results, a mechanism for the formation of the different morphologies was proposed. The cross-linking rate of HPMC-34 and Au III was faster than that of HPMC-10. In the cross-linking of HPMC-34, gelation with Au III occurred immediately at the surface of the droplets after the dropwise addition of the HPMC solution to the Au III solution. Gelation proceeded by immersing Au III inside of the droplets, forming the higher cross-linking density and spherical gels. Contrastingly, due to the slower cross-linking rate of HPMC-10, the cross-linking occurred gradually with the diffusion of Au III from the surface to the inside of the HPMC-10 phase, resulting in the formation of the lower crosslinking density and fibrous gels.
Next, to examine the effect of the decrease in the ratio of metal-coordination units on the gelation, the gelation behavior of HPMC-4 and Pd II was compared to that of HPMC-10 with Pd II . NMP solutions of HPMC-10 or HPMC-4 (13 wt%, 0.2 mL) were added to 4.0 mM Na2PdCl4 aqueous solutions (5 mL). In the gelation of HPMC-10, immediate separation occurred between the HPMC-10 and Pd II phases (Figure 3a), whose separation originated from the fast cross-linking at the interface. The cross-linking with Pd II proceeded from the surface to the inside of the HPMC-10 droplets, affording the spherical gels. In contrast, gelation of HPMC-4 and Pd II occurred gradually from the surface to the inside of HPMC-4 phase, and the gels were extended to the bottom of the container, forming the fibrous gels. To observe a microscopic region, SEM analysis of the obtained gels was conducted. Similar to the gel shapes (Figure 3a,b), the SEM analysis revealed a rough surface from HPMC-10-Pd and fibrous shapes from HPMC-4-Pd (Figure 3c,d). To determine the coordination site, IR measurements of HPMC-4 and HPMC-4-Pd were conducted (Figure 3e). The absorption peak at 1550 cm −1 attributable to the C=S stretching vibration became smaller after cross-linking, indicating that the sulfur of the thiocarbonyl group was coordinated to Pd II .   As shown in Figure 3f, the cross-linking rate of HPMC-4 was slower than that of HPMC-10 due to the decrease in the metal-coordination units. The pseudo-first-order kinetic rate constants, ks of HPMC-4 and HPMC-10 were estimated to be 6.38 × 10 −2 min −1 (R 2 = 0.9821) and 8.62 × 10 −2 min −1 (R 2 = 0.9712), respectively. The gel fractions of the gels from HPMC-4 and HPMC-10 were 0.01 and 0.17, respectively, indicating that the cross-linking density of HPMC-4 was lower than that of HPMC-10. Consequently, the crosslinking reaction of HPMC-4 gradually proceeded with the diffusion of Pd II from the surface to the inside of the HPMC phase due to the slower cross-linking rate, providing lower crosslinking density and fibrous gels as opposed to the gelation of HPMC-10 (spherical gels).

Synthesis of Nanosheets
As described above, the dropwise addition of the NMP solution of HPMC-34 to the Au III aqueous solution allowed instant separation of the HPMC-34 and Au III phases (Figure 2b). The liquid/liquid separation originated from the fast cross-linking at the interface and the higher hydrophobicity of the HPMC-34 phase than the Au III phase. The Au III ions cross-linked from the surface to the inside of the HPMC-34 droplets, affording spherical gels. This feature prompted us to utilize the cross-linking at the liquid-liquid interface between the HPMC-34 and Au III phases for the synthesis of nanosheets.
The synthesis of nanosheets was attempted by the generation of the interface using solutions with different specific gravities and fast cross-linking between thiocarbonyl groups of HPMC-34 and Au III ions (i.e., dropwise addition of an aqueous solution of Au III ions with a lower specific gravity (1.02 g/cm 3 ) to an NMP solution of HPMC-34 with a higher specific gravity (1.63 g/cm 3 )). When the Au III aqueous solutions (16 mmol/L, 0.4 mL) were gently added to the NMP solutions of HPMC-34 with different concentrations (13,23, and 27 wt%), the upper Au III solution was miscible with the lower HPMC-34 concentration due to the slow cross-linking rate. In contrast, the increase in the concentration of HPMC-34 to 31, 35, and 37 wt% allowed instant cross-linking leading to the liquid/liquid separation, resulting in the formation of film-shaped gels at the interface (Figure 4a). Next, to examine the effect of Au III concentration, aqueous solutions of Au III with different concentrations (12,16, and 20 mmol) were added to the HPMC-34 solutions (35 wt%). In every case, liquid/liquid separations were observed (Figure 4b). The thin film that formed at the interface between the Au III (20 mmol) and HPMC (35 wt%) phases was transferred onto a Petri dish using tweezers, followed by washing with NMP and drying under reduced pressure. SEM and transmission electron microscope (TEM) images revealed the formation of a sheet structure (Figure 4c,d). Atomic force microscopy (AFM) showed a thickness of approximately 203 nm (Figure 4e). These results demonstrate the successful formation of the nanosheets at the interface between the Au III and HPMC phases. The obtained nanosheet was characterized structurally. As shown in Figure 2c, the coordination site of Au was through the thiocarbonyl groups. The XPS wide-scan spectrum showed a peak of Au 4f around 84.0 eV and no peak of Cl 2p around 200 eV (see Supplementary Materials Figure S1a). The XPS narrow-scan spectrum showed Au 4f 7/2 and Au 4f 5/2 peaks at 83.9 and 87.6 eV, respectively, which are typical of Au 0 species [28][29][30]. (see Supplementary Materials Figure S1b). These results indicate that the Au III was reduced to Au 0 during gelation, similar to our previously proposed mechanism [24].

Synthesis of Nanofiber
As mentioned above, the gelation of HPMC-4 with Pd II ions provided fibrous gels with a lower cross-linking rate and the stretching force to the bottom of the container induced by the gel weight. Nanofibers containing metal ions are generally synthesized by the electrospinning method using a polymer solution containing metals. However, electrospinning has various problems, as described in Section 1. Thus, the synthesis of nanofibers was attempted by a facile method, i.e., dropwise addition of an NMP solution of HPMC-4 to an aqueous solution of Pd II ions. HPMC-4 solutions (6, 8, and 11 wt%) were added to a NaAuCl4 aqueous solution (4 mM) in a test tube. In all cases, elongated gels were obtained (Figure 5a-c). Elongation of gels increased with decreasing polymer concentration. The TEM observation of the gels obtained at 6 wt% of polymer concentration revealed the formation of fibrous gels of 100~200 nm diameter. The XPS narrow-scan spectrum of the nanofiber showed Pd 3d5/2 and Pd 3d3/2 peaks at 336.8 eV and 342.1 eV, respectively, which are typical of Pd II species ( Figure S2a) [28,31]. EDX/SEM measurement showed the presence of Pd and Cl species ( Figure S2b). The Cl species was ascribed to Na2PdCl4; therefore, Pd II Cl2 was contained in the nanofibers. Thus, nanofibers crosslinked with Pd II ions were successfully synthesized by this dropwise addition method.

Synthesis of Nanofiber
As mentioned above, the gelation of HPMC-4 with Pd II ions provided fibrous gels with a lower cross-linking rate and the stretching force to the bottom of the container induced by the gel weight. Nanofibers containing metal ions are generally synthesized by the electrospinning method using a polymer solution containing metals. However, electrospinning has various problems, as described in Section 1. Thus, the synthesis of nanofibers was attempted by a facile method, i.e., dropwise addition of an NMP solution of HPMC-4 to an aqueous solution of Pd II ions. HPMC-4 solutions (6, 8, and 11 wt%) were added to a NaAuCl 4 aqueous solution (4 mM) in a test tube. In all cases, elongated gels were obtained (Figure 5a-c). Elongation of gels increased with decreasing polymer concentration. The TEM observation of the gels obtained at 6 wt% of polymer concentration revealed the formation of fibrous gels of 100~200 nm diameter. The XPS narrow-scan spectrum of the nanofiber showed Pd 3d 5/2 and Pd 3d 3/2 peaks at 336.8 eV and 342.1 eV, respectively, which are typical of Pd II species ( Figure S2a) [28,31]. EDX/SEM measurement showed the presence of Pd and Cl species ( Figure S2b). The Cl species was ascribed to Na 2 PdCl 4 ; therefore, Pd II Cl 2 was contained in the nanofibers. Thus, nanofibers cross-linked with Pd II ions were successfully synthesized by this dropwise addition method.

Conclusions
In conclusion, we demonstrated the control of gelation behavior for the synthesis of different types of nanomaterials by changing the composition ratio of the metal-coordination unit in HPMC. An increase in the composition ratio of the metal-coordination unit from 10 mol% to 34 mol% increased the cross-linking rate with Au III , resulting in the formation of spherical gels and Au nanosheets. A decrease in the ratio of the metal-coordination unit from 10 mol% to 4 mol% decreased the cross-linking rate with Pd II , affording fibrous gels and Pd nanofibers. Changing the composition ratio of the metal-coordination unit allowed the contrasting gelation behavior to form various types of nanomaterials with metal ions. This procedure will enable the controlled synthesis of various types of nanomaterials containing various metals, which is now under investigation.

Instruments
1 H NMR spectra were measured with a JEOL JNM ECA-500 using tetramethylsilane (TMS) as an internal standard; δ values are given in parts per million (ppm). IR spectra were measured with a SHIMADZU FTIR IRPrestige-21 spectrometer, and the values are provided in cm −1 . Flame atomic absorption spectrometry was conducted with a Hitachi Z-

Conclusions
In conclusion, we demonstrated the control of gelation behavior for the synthesis of different types of nanomaterials by changing the composition ratio of the metal-coordination unit in HPMC. An increase in the composition ratio of the metal-coordination unit from 10 mol% to 34 mol% increased the cross-linking rate with Au III , resulting in the formation of spherical gels and Au nanosheets. A decrease in the ratio of the metal-coordination unit from 10 mol% to 4 mol% decreased the cross-linking rate with Pd II , affording fibrous gels and Pd nanofibers. Changing the composition ratio of the metal-coordination unit allowed the contrasting gelation behavior to form various types of nanomaterials with metal ions. This procedure will enable the controlled synthesis of various types of nanomaterials containing various metals, which is now under investigation.

Instruments
1 H NMR spectra were measured with a JEOL JNM ECA-500 using tetramethylsilane (TMS) as an internal standard; δ values are given in parts per million (ppm). IR spectra were measured with a SHIMADZU FTIR IRPrestige-21 spectrometer, and the values are provided in cm −1 . Flame atomic absorption spectrometry was conducted with a Hitachi Z-2310 polarized Zeeman atomic absorption spectrometer (AAS). X-ray photoelectron spectroscopy (XPS) was performed with a Kratos AXIS-NOVA instrument. Scanning electron microscopy