N, P-codoped porous carbon derived from chitosan with hierarchical N-enriched structure and ultra-high specific surface Area toward high-performance supercapacitors

doi:10.1016/j.jmst.2021.02.014

Abstract

Abstract:

In this work, a facile “carbonization-activation” strategy is developed to synthesize N, P-codoped hierarchical porous carbon. Phosphoric acid is innovatively introduced during the hydrothermal process to achieve in-situ P doping as well as create abundant pores, and the employment of sodamide is of vital importance to simultaneously serve as activating agent and N-source to succeed a high-level N doping. Thus, the obtained samples exhibit a unique three-dimensional hierarchical structure with an ultra-high specific surface area (3646 m ² g^-1) and ultra-high N-doping level (9.81 at.%). Computational analyses confirm that N, P co-doping and higher N content can enhance active sites and widen potential differences of carbon materials to improve their capacitance. The as-prepared carbon materials demonstrate superior electrochemical performances, such as an ultra-high capacitance of 586 F g^-1 at 1 A g^-1, a superior rate capability of 409 F g^-1 at 20 A g^-1, and excellent long-term stability of 97 % capacitance retention after 10,000 cycles in 6 M KOH. Moreover, an assembled symmetric supercapacitor delivers a high energy density of 28.1 Wh kg^-1 at the power density of 450 W kg^-1 in 1 M Na₂SO₄, demonstrating a great potential for applications in supercapacitors.

Key words: facile and cost-effective strategy, Ultra-high specific surface area, High-level heteroatoms doping, High specific capacitance

Xipeng Xin, Na Song, Ruiming Jia, Bingnan Wang, Hongzhou Dong, Shuai Ma, Lina Sui, Yingjie Chen, Qian Zhang, Lifeng Dong, Liyan Yu. N, P-codoped porous carbon derived from chitosan with hierarchical N-enriched structure and ultra-high specific surface Area toward high-performance supercapacitors[J]. J. Mater. Sci. Technol., 2021, 88: 45-55.

Figures/Tables 10

Scheme 1. Schematic process for the preparation of NPC-X samples.

Fig. 1. SEM images of NPC-600 (a, d), NPC-700 (b, e), and NPC-800 (c, f); TEM images of NPC-700 (g-i) and EDS elemental mapping images for C, N, O, and P elements (j).

Fig. 2. XRD patterns (a) and Raman spectra (b) of all samples.

Fig. 3. (a-c) N2 adsorption/desorption isotherms of NPC-X samples (insets are the plots of pore size distributions calculated from NLDFT model), and (d) comparison of SSA for all samples.

Table 1 Pore structure parameters of all samples.

Sample	S_BET^a (m² g^-1)	S_micro^b (m² g^-1)	S_meso^c (m² g^-1)	S_meso/S_BET (%)	V_total ^d (cm³ g^-1)	V_micro^e (cm³ g^-1)	V_meso^f (cm³ g^-1)	D_a^g (nm)
NPC-600	2483	1319	1164	42.9	1.55	0.55	1.00	3.08
NPC-700	3646	1253	2393	65.6	2.87	0.56	2.31	3.86
NPC-800	3022	735	2287	75.6	2.67	0.35	2.32	4.25
@NPC-700	2545	1324	1221	48.0	1.96	0.76	1.20	2.71
NC-700	2248	1493	755	50.6	1.36	0.56	0.80	2.23

Fig. 4. (a) XPS survey of NPC-600, NPC-700, and NPC-800, (b-e) high-resolution XPS spectra of the C1s, O1s, N1s, and P2p of NPC-700, and (f) schematic of different N functionalities and P-containing functional groups in the carbon matrix.

Table 2 C, N, O, and P contents of carbon samples and their surface concentrations of N and P obtained from XPS.

Sample	XPS (at %)				% of total N1s				% of total P2p
Sample	C %	N %	O %	P %	N-6	N-5	N-Q	N-X	P-O	P-C
NPC-600	77.32	9.81	12.90	0.78	19.1	40.8	18.0	22.1	48.8	51.2
NPC-700	81.85	8.15	8.98	1.02	24.1	43.8	18.9	13.2	32.5	67.5
NPC-800	88.32	3.17	7.23	1.28	17.3	41.9	28.6	12.2	27.6	72.4
@NPC-700	86.39	3.14	9.73	0.74	22.1	38.6	20.9	18.4	42.3	57.7
NC-700	83.95	6.12	9.93	—	19.0	42.3	18.6	19.1	—	—

Fig. 5. Illustration (a) and electrostatic potential plots (b) of GR-N4, GR-N4P and GR-N5P, where carbon, hydrogen, oxygen, nitrogen and phosphorus atoms are colored in gray, white, red, blue and orange, respectively.

Fig. 6. Electrochemical performance of all samples in a three-electrode system (6 M KOH): (a) CV curves of all samples at a scan rate of 20 mV s-1; (b) GCD curves of all samples at a current density of 1 A g-1; (c) CV curves of NPC-700 at different scan rates (5-100 mV s-1); (d) GCD curves of NPC-700 at different current densities (0.5-20 A g-1); (e) Specific capacitance of all samples calculated from GCD curves at various current densities; (f) The correlation among specific capacitance, specific surface area, and heteroatom contents of as-prepared samples; (g) Nyquist plots of all samples (inset is the magnified plots); (h) Bode plots for all samples; (i) Cycle life and coulombic efficiency of NPC-700 electrode (the inset presents the GCD curves for the first five cycles and the last five cycles).

Fig. 7. (a) Schematic diagram of the assembled NPC-700//NPC-700 symmetric supercapacitor; (b) CV curves at different voltages; (c) CV curves at various scan rates; (d) GCD curves at various current densities; (e) specific capacitance of the supercapacitor calculated at various current densities; (f) Nyquist plots of the supercapacitor before and after 10,000 cycles (the inset is the amplified high-frequency region); (g) Ragone plots of the NPC-700//NPC-700 symmetric supercapacitor in comparison with some previously reported results; (h) Cycling stability after 10,000 cycles at a current density of 5 A g-1 (the inset shows a red LED light powered by three symmetric supercapacitors in series connection).

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