It has been reported that the addition of graphene oxide (GO) can increase the dispersion and heterogeneousnucleation of layered double hydroxide (LDH), thus providing more active sites, which is more conduciveto CO2 adsorption. Herein, we reported alkali metal nitrates ((Li0.3Na0.18K0.52)NO3) promoted LDHand GO composites (LDH/GO) as adsorbents for CO2 capture. The influence of mass ratio of LDH to GO, theimpregnation ratio of alkali metal nitrates, the calcination and adsorption temperature, as well as thecycling stability were investigated systematically. The results indicated that the CO2 capture capacityof LDH/GO composite with 30 mol% (Li0.3Na0.18K0.52)NO3 could reach 4.51 mmol g 1, which was 5.86times higher than LDH/GO1 without loading alkali metal nitrates. Moreover, it had outstanding CO2adsorption capacity in the range from 200 C to 320 C. In addition, the cyclic adsorption and desorptiontest manifested that the CO2 uptake of the material can reach 3.07 mmol g 1 after 22 cycles. We believethat this study will give a significant contribution to fabrication of LDH based composites as CO2 adsorbentsin future study.

1 S. -Y. Oh, 216 : 311-322, 2018

2 C. Hou, 7 : 13460-13472, 2019

3 A. Dong, 6 : 44-52, 2019

4 B. -S. Ge, 29 : 1334-1343, 2017

5 L. Huang, 68-72, 2017

6 A. Dong, 5 : 56-65, 2019

7 D. Maiti, 11 : 648-659, 2018

8 Q. Zheng, 4 : 12889-12896, 2016

9 V. Manovic, 42 : 4170-4174, 2008

10 Q. He, 194 : 207-, 2018

11 H. Wu, 3 : 68-73, 2019

12 J. Pellessier, 13 : 66-75, 2021

13 J. Wang, 68 : 424-431, 2012

14 P. Peng, 2 : 9-20, 2018

15 Y. Fu, 4 : 66-73, 2019

16 Z. Cai, 5 : 22-36, 2019

17 C. Yin, 360-370, 2021

18 X. Liu, 592 : 124588-125499, 2020

19 Y. Gao, 1 : 12782-12790, 2013

20 C. I. Ezeh, 39 : 330-343, 2017

21 M. J. Lashaki, 334 : 1260-1269, 2018

22 M. H. Halabi, 37 : 4516-4525, 2012

23 B. Ficicilar, 115 : 274-278, 2006

24 A. Hanif, 236 : 91-99, 2014

25 A. Garcia-Gallastegui, 24 : 4531-4539, 2012

26 J. Wang, 18 : 2956-2964, 2018

27 P. M. Kakade, 12 : 63-71, 2021

28 J. Cai, 6 : 68-74, 2019

29 D. Zhang, 10 : 35-50, 2020

30 C. Hou, 596 : 396-407, 2021

31 Q. M. Al-Bataineh, 12 : 2954-, 2020

32 J. Wang, 24 : 127-137, 2015

33 Q. Wang, 1 : 298-303, 2011

34 S. Li, 27 (27): 5352-5358, 2013

35 J. M. Lee, 26 (26): 18788-18797, 2010

36 D. Iruretagoyena, 54 : 11610-11618, 2015

37 Y. -J. Wu, 36 (36): 567-574, 2013

38 T. Harada, 27 : 8153-8161, 2015

39 Q. Qin, 26 : 346-353, 2017

40 J. Wang, 1734-1744, 2019

41 J. Wang, 19 : 1933-1948, 2015

42 J. Wang, 24 : 127-137, 2015

43 M. Zhang, 11 : 377-390, 2021

44 Z. Peng, 14 : 27-38, 2021

45 X. Kou, 32 : 5313-5320, 2018

46 A. A. -E. Sakra, 160 : 263-269, 2018

47 G. B. B. Varadwaj, 9 (9): 3598-3621, 2016

48 S. Kim, 8 : 5763-5767, 2016

49 Y. Qiao, 56 : 1509-1517, 2017

50 N. N. A. H. Meis, 49 : 1229-1235, 2010

51 G. B. B. Varadwaj, 9 (9): 3598-3621, 2016

52 L. K. G. Bhatta, 30 (30): 4244-4250, 2016

53 X. Zhu, 40 : 9244-9253, 2015

54 L. K. G. Bhatta, 54 (54): 10876-10884, 2015

55 Y. Qiao, 5 : 82777-82780, 2015

56 Y. -P. Chang, 5 (5): 1249-1257, 2012

57 Junya Wang, "Layered double hydroxides/oxidized carbon nanotube nanocomposites for CO2 capture" 한국공업화학회 36 : 255-262, 2016

58 김종남, "Hydrotalcites for adsorption of CO2 at high temperature" 한국화학공학회 23 (23): 77-80, 2006

59 Yoon Jae Min, "High-temperature CO2 sorption on Na2CO3-impregnated layered double hydroxides" 한국화학공학회 31 (31): 1668-1673, 2014