Monodispersed Co@C nanoparticles anchored on reclaimed carbon black toward high-performance electromagnetic wave absorption

doi:10.1016/j.jmst.2022.03.004

Abstract

Abstract:

Recently, developing carbon-based hybrid materials loaded with magnetic components has been generally regarded as a promising and practically feasible strategy when it comes to constructing lightweight electromagnetic wave absorbers. In the current work, reclaimed carbon black (CB) nanopowder was firstly produced by simple burning of wheat straw, which was then employed as sustainable carbon-based host materials (carrier) and successfully decorated Co@C nanoparticles via a simple thermal reduction process. Remarkably, both the as-fabricated nanocomposites and corresponding electromagnetic wave absorption performances could be effectively tuned by tailoring the dosage of the Co@C nanoparticles. The minimum reflection loss (RL_min) of -53.989 dB was achieved for CB/Co@C-2# at 2.28 mm thickness, meanwhile, CB/Co@C-3# was featured by a wide effective absorption band (EAB) of 6 GHz (6.72-12.72 GHz) at a 2.73 mm matching thickness, which covered the entire X band, suggesting that the CB/Co@C nanocomposites were an attractive candidate for electromagnetic wave absorber. According to the synergistic influence of dielectric loss and magnetic loss from CB and Co@C, respectively, as well as the properly matched impedance, a reasonable electromagnetic wave attenuation mechanism was illustrated. It is noteworthy that the preparation process of CB is a facile, recycled, and low-cost strategy for achieving nanoscale carbon-based absorbing materials, moreover, the CB/Co@C nanocomposites provide a reference for constructing lightweight dielectric-magnetic products with superb electromagnetic wave absorption performances.

Key words: Reclaimed carbon black, Microwave absorption, Attenuation mechanism, Preparation technique, CB/Co@C nanocomposites

Zhenjiang Li, Hui Lin, Yuxin Xie, Laibin Zhao, Yuying Guo, Tingting Cheng, Hailong Ling, Alan Meng, Shaoxiang Li, Meng Zhang. Monodispersed Co@C nanoparticles anchored on reclaimed carbon black toward high-performance electromagnetic wave absorption[J]. J. Mater. Sci. Technol., 2022, 124: 182-192.

Figures/Tables 12

Fig. 1. Schematic of the preparation process of the CB/Co@C nanocomposites.

Fig. 2. (a) XRD patterns and (b) Raman spectra of CB and CB/Co@C nanocomposites.

Fig. 3. (a-d) SEM images, (e-i) TEM images, and (j, k) HRTEM images of CB at different magnifications. The typical SAED pattern is inserted in Fig. 3(f).

Fig. 4. SEM images of the (a-c) CB/Co@C-1#, (d-f) CB/Co@C-2#, and (g-i) CB/Co@C-3#.

Fig. 5. TEM images of (a) CB/Co@C -1#, (b) CB/Co@C -2#, (c) CB/Co@C -3# and typical HRTEM images of (d-g) CB/Co@C nanocomposites.

Fig. 6. XPS characterization of (a, b) C 1s, (c) O 1s, and (d) Co 2p patterns of CB and various CB/Co@C nanocomposites.

Fig. 7. Field-dependent magnetization curves of the CB/Co@C nanocomposites.

Fig. 8. RL values of four paraffin-based composites (a) CB, (b) CB/Co@C-1#, (c) CB/Co@C-2#, and (d) CB/Co@C-3# at 2-18 GHz. (e-h) 2D color-mapping of RL for CB and CB/Co@C. (i) Maximum RL and EAB for CB/Co@C-2# with different sample thicknesses.

Table 1. RLmin and EABmax of the corresponding thickness of Co@C composites reported recently.

Sample	Filler content (%)	Minimum RL		RL		Refs.
Empty Cell	Empty Cell	RL_min (dB)	d_m (mm)	EAB (GHz)	d_m	Empty Cell
Co@C nanotubes	30	-48	2.0	5.2	1.8	[55]
Porous Co/C	10	-34.2	2.4	5.0	1.8	[56]
Co@C@NPC	10	-57.2	3	5.7	3	[57]
N-doped Co@C	40	-47.6	2.7	4.4	2.7	[58]
Co/C-500	60	-35.3	4.0	5.8	4.0	[59]
Porous carbon/Co	30	-40	5.0	2.5	1.8	[60]
Co@C nanofiber	50	-40	2.4	2.5	2.4	[61]
FeCo@C	50	-67.8	1.75	5.3	2.0	[62]
Co/C	20	-56	3.5	3.6	2.3	[63]
Co/CNTs	30	-35	2.5	4.7	2.5	[64]
CB/Co@C-2#	30	-53.989	2.28	4.08	2.28	This work
CB/Co@C-3#	30	-28.483	2.28	6	2.73	This work

Fig. 9. (a) Real and (b) imaginary parts for complex permittivity. (c) Real and (d) imaginary parts for complex permeability. (e) tanδε and (f) tanδμ of CB and CB/Co@C nanocomposites at 2.0-18.0 GHz. (g) C0 cure, (h) attenuation constant, and (i) impedance matching of the CB and CB/Co@C nanocomposites.

Fig. 10. The Cole-Cole plots of (a) CB, (b) CB/Co@C-1#, (c) CB/Co@C-2#, and (d) CB/Co@C -3# nanocomposites.

Fig. 11. Schematic illustration of the possible electromagnetic absorption mechanism for the CB/Co@C nanocomposites.

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