As examples, Si microwire arrays of lengths of 80 and 130 μm are shown in Figure  3 a and b, respectively.To produce anodes of different areas, also the main parameter to be varied is the etching current. The necessary etching current can be

known by multiplying the current density (described in Figure  2) by a constant factor scaled according to the desired size of BLZ945 order the anode. The scalability of the area may sound trivial, but it requires intense engineering work. Special care has to be taken about the temperature of the etching system when etching for large anodes, since a big portion of the consumed power is transformed into heat. The electrochemical etching process is temperature sensitive. Two examples of anodes of different sizes are shown in Figure  4. In principle, anodes as big as the size of the precursor Si wafers can be obtained. The rest of the steps for check details the production

of anodes remains unaltered for longer/shorter anodes or for up/down scaling. Just the current for the electrochemical deposition of Cu has also to be scaled up/down in direct proportion to the size of the anodes. JNJ-26481585 chemical structure Figure 3 Si microwires produced with different lengths: (a) 80 μm and (b) 130 μm. Figure 4 Si microwire anodes produced in different areas. Anodes with diameters of 2.4 and 1 cm are shown. Scalable capacity The capacity of the anodes scales with the length of the wires. Figure  5 shows the lithiation capacity of anodes with wires of 70 and 130 μm over 40 cycles, cycling at a C rate of C/10 (the charging current is calculated so that the total capacity is reached in 10 h) for 4 cycles, and of C/2 afterwards, in galvanostatic/potentiostatic mode (see Methods section). To the side of the current collector, 10 μm of the anodes are embedded in Cu; this portion is not lithiated, since volume expansion is not allowed [11]. In this way, the active portion

of the wires is of 60 and 120 μm, respectively. As expected, it can be observed in Figure  5 that the areal capacity Fluorouracil in vitro (capacity per unit of area) of the anode with wires of 130 μm is around double the one of the anode with wires of 70 μm, before capacity fading. The areal capacity is directly proportional to the length of the wires. Figure 5 Curve of areal capacity versus cycle number for anodes with wires of 70 and 130 μm. The capacity of the anode with longer wires is two times the one with the shorter ones and is stable over 22 cycles. The first four cycles were performed at a cycling rate of C/10 and the rest at C/2. Performance limitations after scaling The increase of capacity after up-scaling has, however, a cost in the cyclability. The capacity of the longer wires fades monotonically after 22 cycles, as can be observed in Figure  5. The decrease of the capacity occurs most probably due to an increment in the series resistance.