Amorphous Alloy: Promising Precursor to Form Nanoflowerpot

Nanoporous copper is fabricated by dealloying the amorphous Ti 2 Cu alloy in 0.03MHF electrolyte.The pore and ligament sizes of the nanoporous copper can be readily tailored by controlling the dealloying time.The as-prepared nanoporous copper provides fine and uniform nanoflowerpots to grow highly dispersed Au nanoflowers. The blooming Au nanoflowers in the nanoporous copper flowerpots exhibit both high catalytic activity and stability towards the oxidation of glucose, indicating that the amorphous alloys are ideal precursors to form nanoflowerpot which can grow functional nanoflowers.


Backgrounds
Owing to the unique combination of physical, chemical, and mechanical properties, amorphous alloys have been posed as promising new materials for structural and functional utilizations [1,2].One of the most attractive applications is to use the amorphous alloys in nanotechnology.If the amorphous alloy is in a glassy state, the supercooled liquid region where the Newton's flow can take place may provide fascinating fabrication capability for the alloys.Nanorods, nanobars, and even mircogears have been successfully prepared by nanoimprinting in the supercooled liquid region of Zr-based and Pt-based amorphous alloys [3,4].However, the amorphous alloys which have large supercooled liquid region are quite limited.Dealloying, on the other hand, can be performed on most of the amorphous alloys to form uniform nanostructure, no matter the alloy exhibits supercooled liquid region or not.During dealloying, the less noble elements are selectively dissolved and noble element keeps self-assembling through surface diffusion, leaving behind a bicontinuous nanoporous (NP) structure [5].Usually, dealloying is applied on crystalline alloys composed by a single phase, such as intermetallic compounds or solid solutions, to form NP metals which have various functional applications in catalysis, chemical sensors, and electrochemistry [6][7][8][9].Recently, there are some attempts to form nanoporous alloy by dealloying amorphous alloys and the results show that the nanoporous structure obtained by dealloying amorphous alloy was finer and more uniform than that obtained by dealloying crystalline alloys.Therefore, there are intensive interests in the catalytic, thermal, and optical applications of the NP materials prepared by dealloying amorphous alloys.For instance, Yu et al. synthesized NPPd by electrochemically dealloying the Pd 30 Ni 50 P 20 amorphous alloy [10] and Lang et al. prepared NPAu by dealloying the Au-based amorphous alloy [11].These NP materials exhibited high catalytic activity towards the oxidation of formic acid.Luo et al. obtained NP copper (NPC) by dealloying AlCuMg amorphous alloys.The NPC had extremely high specific surface area and could be used as low-temperature heat exchanger [12].However, to our knowledge, there is no report on growing functional nanoflowers on the fine and uniform NP structures which are prepared by dealloying amorphous alloys.
In this study, we use Ti 2 Cu amorphous alloy as the dealloying precursor to form "nanoflowerpot" to grow Au nanoflowers.Au in a nanoarchitecture form, such as NPAu, Au nanoflower, and Au nanoparticle, is an ideal material for enzyme-free electrochemical glucose sensor due to the high catalytic activity towards the oxidation of glucose [13,14].However, most of the Au nanomaterials suffer from the structure degradation [15].For instance, nanopores and ligaments in NPAu will get coarsened and finally lose the catalytic activity during catalysis.It is expected that when NPC is used as the flowerpots to grow Au nanoflowers, that NPC dealloyed from amorphous alloy can provide homogenous dispersed growing sites for Au and stabilize the catalytic activity of the Au nanoflowers.

Experimental Methods
The Ti 2 Cu amorphous alloy ribbon was prepared by arc melting Ti and Cu metals in a high-purity argon gas atmosphere, followed by melt spinning with a copper wheel velocity of about 40 ms −1 .The as-prepared amorphous ribbon is about 20 um in thickness and 1 mm in width.The XRD pattern of the ribbon was recorded using an X-ray diffractometer with Cu Ka radiation.NPC samples are fabricated by selective etching of the Ti 2 Cu amorphous ribbons in 0.03 M HF solutions.The dealloyed samples were firstly rinsed in pure water more than three times to remove the residual chemical substances and then were dried by freeze drier.With the aim of growing Au nanoflowers with tunable size, the dried NPC was immersed into a 0.5 mM HAuCl 4 solution in a three-neck flask at 0 ∘ C under Ar-protected magnetic stirring conditions.
The microstructures of the NPC as well as the NPC-G were observed by field-emission scanning electron microscope (SEM) and the compositions were characterized by energy dispersive X-ray spectrometer (EDS).The electrochemical performance of the NPC-G towards the oxidation of d-glucose is tested by electrochemical workstation CHI760D, where the NPC-G was used as the working electrode, saturated calomel electrode was used as a reference electrode, and a Pt foil was used as the counter electrode.The electrolyte is mixed with 0.01 M PBS and 50 mM glucose.

Results and Discussion
The XRD pattern of the ribbon in Figure 1 shows only a broad diffraction maximum without any observable crystalline peaks, demonstrating the formation of a homogenous amorphous structure in the ribbon sample.When the Ti 2 Cu amorphous alloy is used as the precursor, the morphology development with the dealloying time is observed by SEM and the corresponding images are shown in Figure 2. Three-dimensional, interpenetrating ligamentchannel nanoporous structure can be seen after 1 h of etching (Figure 2(a)).The ligaments are in a size ranging within 50-100 nm and the nanopores are about 5-20 nm. 10 h of etching leads to the formation of a fine continuous nanoporous structure.The ligaments are about 50-100 nm in size and the pores are in a bimodal distribution; that is, small pores are about 5 nm and large pores are about 15 nm.After 96 h of dealloying, ligaments increase up to about 200-500 nm and collapse occurs in many areas, resulting in the formation of large pores (100-200 nm).Visible nanoporous structure coarsening can be seen with the increase of dealloying time, indicating that the nanoflowerpot size can be readily tailored by controlling the dealloying time.
The chemical compositions of the dealloyed samples are measured by EDS and the results are summarized in Table 1.The Ti content first decreases from 66.7 at% to 14.7 at% after 1 h of dealloying, then goes down to 1.0 at% after 10 h of dealloying.Finally, it decreases to 0.5 at% after 96 h of corrosion.The gradually decrease of the Ti content and the coarsening of the NPC structure with the dealloying time suggest that the selective dissolving of Ti and the uphill diffusion of Cu carry through simultaneously the whole dealloying process.
Due to the fine and uniform structure, the NPC prepared by dealloying the Ti 2 Cu amorphous alloys for 10 h was chosen as the flowerpot to grow Au flowers.The NPC was immersed into a 0.5 mM HAuCl 4 solution for 20, 40, and 60 min and the samples are named as NPC-G 1 number, NPC-G 2 number, and NPC-G 3 number, respectively.The SEM images of the NPC-G samples are shown in Figure 3 and the corresponding EDS results are summarized in Table 2.As shown in Figures 3(a  Au(OH) ads ), takes place on the surface of the NPC-G samples.The peak position is at about 0.2 V, agreeing with the reported data on NPG and Au nanoparticles [13][14][15][16][17].The current density value of the peak is 9.8 mA/cm 2 , 7.6 mA/cm 2 a, and 3.2 mA/cm 2 for NPC-G 1 number, NPC-G 2 number, and NPC-G 3 number, respectively.The current peak density of NPC-G 1 number higher than that of the other NPC-G samples indicates that NPC-G 1 number has the highest catalytic activity.Therefore, NPC-G 1 number is chosen for the stability test and the result is shown in Figure 5. CV curves of a NPG sample with a characteristic pore size of 10 nm are also involved for comparison.In the case of NPG, the oxidation peak current value drops rapidly, decreasing to 85.7% after one hundred cycle.Meanwhile, the oxidation peak (potential) shift with the increasing scans can be vividly seen.For NPC-G 1 number, neither peak shift nor peak current density decrease can be observed, indicating that NPC-G has both high catalytic activity and high stability.nanoflowers.The NPC-G structure exhibits both high catalytic activity and stability towards the oxidation of d-glucose, indicating that the amorphous alloys are ideal precursors to form nanoflowerpot which can grow functional nanoflowers.

Figure 5 :
Figure 5: CV curves of NPC-G2 number before and after 100 potential cycles in 0.1 mol/L KOH alkaline aqueous solutions with 50 mmol/L glucose, scan rate 0.05 V/min.The inset is the CV curves of NPG during 100 potential cycles in the same conditions, versus SCE.

Table 1 :
Chemical compositions of the NPC samples test by EDS.

Table 2 :
Chemical compositions of the NPC-G samples test by EDS.