energy-densities

Journal Pre-proof Construction of the Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 Sodium-Ion Cathode with Balanced High-Power/Energy-Densities Changchun Sun, Shaowen Li, Miao Bai, Weiwei Wu, Xiaoyu Tang, Wenyu Zhao, Min Zhang, Yue Ma PII:

S2405-8297(20)30046-5

DOI:

https://doi.org/10.1016/j.ensm.2020.02.007

Reference:

ENSM 1089

To appear in:

Energy Storage Materials

Received Date: 12 August 2019 Revised Date:

23 December 2019

Accepted Date: 5 February 2020

Please cite this article as: C. Sun, S. Li, M. Bai, W. Wu, X. Tang, W. Zhao, M. Zhang, Y. Ma, Construction of the Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 Sodium-Ion Cathode with Balanced HighPower/Energy-Densities, Energy Storage Materials, https://doi.org/10.1016/j.ensm.2020.02.007. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier B.V.

1

Construction of the Na0.92Li0.40Ni0.73Mn0.24Co0.12O2

2

Sodium-Ion Cathode with Balanced

3

High-Power/Energy-Densities

4 5

Changchun Sun, Shaowen Li, Miao Bai, Weiwei Wu, Xiaoyu Tang, Wenyu Zhao, Min

6

Zhang and Yue Ma*

7 8

State Key Laboratory of Solidification Processing, Center for Nano Energy Materials,

9

School of Materials Science and Engineering, Northwestern Polytechnical University

10

and Shaanxi joint Laboratory of Graphene (NPU), Xi’an 710072, China

11

*Corresponding Author

12

E-mail: [email protected] (Y. Ma)

13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30

1

1

Construction

of

the

2

Sodium-Ion

3

High-Power/Energy-Densities

Cathode

Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 with

Balanced

4 5

Abstract

6

Layered P2 type transition metal oxides (TMOs) are considered as the promising

7

cathode candidates for the sodium ion batteries (SIBs). However, the high operating

8

voltage of the P2 cathodes always involves the irreversible phasic transition, which thus

9

compromises the structural stability and practical applications. Through the sustainable

10

recycling of biomass carbon as the sacrificial precursor framework, herein, a

11

Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 cathode with the coexisting P2/O3 phases is reported.

12

By the aid of transmission-mode operando X-ray diffraction, the real-time phasic

13

transition upon the solid-state reaction is precisely tracked. Furthermore, a full cell

14

prototype by pairing the as-fabricated cathode with the anode that developed via a

15

similar sacrificial templating strategy is established. The full cell model renders the

16

simultaneous robust stability, the high energy density of ~218.5 Wh kg-1 at a power

17

density of 83 W kg-1 (0.5C). This biomass-templated strategy demonstrates a precise

18

control over the structural and compositional features of electrodes for the SIBs.

19 20

Keywords

21

Sodium ion batteries; Hybrid layered cathode structure; Operando X-ray diffraction;

22

Full cell prototype; High operating voltage

23 24

1. Introduction

25

To cater to the market needs of the emerging electric vehicles and utility-scale

26

energy storage applications, the key performance metrics of the rechargeable batteries,

27

for instance, the raw material cost, energy/power densities and operation safety become

1

increasingly demanding that far beyond current lithium ion batteries (LIBs)

2

technologies.[1–6] Besides, the finite lithium reserve and its spatially localized

3

distribution mismatch with the rapid growing requirements for the sustainable

4

deployment of energy storage systems.[7] In this context, the development of the

5

alternative sodium ion batteries (SIBs), attracts more attention due to the merits of

6

unlimited sodium resources, low environment foot-print and the low operating voltage

7

(-2.71 V vs. standard hydrogen electrode (SHE)). [8–14] Among the cathode

8

candidates for SIBs, transitional metal oxides (TMOs) with layered host for sodium

9

ions, such as the binary (NaNixMnyO2, NaFexMnyO2) and ternary layered derivatives,

10

i.e. NaNixMnyCozO2 (NaNMC) have been extensively investigated due to the high

11

gravimetric capacities of ~120-130 mAh g-1 and the possible operating voltage up to 4.5

12

V, which render the SIBs comparable energy density of ~250-300 Wh/kg as

13

LIBs.[1,12,15,16] However, the performance optimization of the layered TMOs

14

cathodes is rather challenging, especially in consideration of the precise control over

15

the compositional and structural parameters, i.e. crystallinity, particle size, cation

16

distribution as well as the synergistic coupling of coexisting phases.

17

The Delmas’ notation designates two main types of polymorph for the TMOs

18

derivatives as SIBs cathodes: The O3 type structure arranges the crystal layers in a

19

manner of ABCABC stacking, which possesses the higher reversible capacity upon the

20

high voltage charge. However, the Na+ migration in the O3 structure requires more

21

energy during the high voltage range, which unfortunately induces the retarded Na+

22

migration and the compromised rate behaviors. While P2 type structure possesses the

23

close-packed oxygen atoms with ABBA stacking, the enlarged interplanar spacing of

24

which favors the fast diffusion of sodium in the structures with a limited reversible

25

capacity.[10,17–21]

26

O3-NaNi1/3Mn1/3Co1/3O2 cathode delivered a high capacity ~120 mAh g−1 at 0.1C, yet

27

only ~80 mAh g−1 at 1C.[22] The P2-Na2/3Ni1/3Mn2/3O2 layered cathode, as reported in

28

pioneer studies by Li. Y et.al and Liu. Y et.al, delivered an enhanced level of rate

29

behaviors ~100 mAh g−1 at 1C and ~120 mAh g−1 at 0.2C within the voltage charge

For

instance,

M.Sathiya

et.al

reported

that

1

range of 2.0-4.4 V.[23,24] However, the complete extraction of the Na ions during the

2

high voltage range would induce the lattice distortion of P2 structure and thus the

3

irreversible phasic transition to O2 phase, preventing the reinsertion of Na+ with the

4

deteriorated cycling reversibility.[17,24–28] Thus the rational design of cathode

5

materials and the facile electrode kinetics of the P2 type composites will be the feasible

6

route to realize the simultaneous high energy/power densities and long cycle life,

7

especially upon the high operating voltage. Although the similar design rationale of the

8

intergrowth biphasic structure has been proposed, the precise compositional

9

manipulation of the layered cathodes as well as their practical use in the full cell models

10

are yet to be further explored.

11

The elucidation of the dynamic phasic transition of the NaNMC phase is

12

considered as the prerequisite for the rational optimization of the layered cathodes.

13

Thus far, pioneer studies have investigated the feasible modification strategies to

14

improve the reversibility of the sodiation process. Chen et.al introduced the Cu doping

15

to enhance the lattice spacing, thereby reducing the internal resistance of the electrode

16

and improving the cycle performance within the voltage range of 1.5-4.0 V. [29] Dang

17

et.al. investigated the suppression effect of the oxide coating layer which effectively

18

avoided the unfavorable side reaction and the exfoliation of the transition metal (TM)

19

layers.[25] Luo et.al proposed the quasi-solid-solution reaction for the sodium

20

extraction process within the voltage range of 2.2–3.9 V.[30] Xu et.al investigated the

21

effect

22

Na0.80[Li0.12Ni0.22Mn0.66]O2, stabilizing the P2 structure through inhibition of the Mn

23

dissolution above 4.0 V.[31] However, the dynamic phasic transition of the ternary

24

oxide derivatives, especially during the high operating voltage, is yet to be further

25

elucidated, so as to simultaneously realize the high operating voltage and structural

26

stabilization.

of

lithium

substitution

of

Mn

sites

in

the

P2

structure

of

27

Herein, we propose a coherent modification strategy to ameliorate the

28

electrochemical performance of the layered P2/O3 NaLiNMC structure at the high

29

operating voltage range. The deliberate control over the compositional stoichiometry

1

(Li occupancy) and microstructural features (P2/O3 mixture nanocrystallines with

2

optimal particle size) was realized via the sustainable recycling of the biomass as the

3

sacrificial framework. The transmission-mode operando X-ray diffraction (XRD)

4

documented the dynamic phasic transformation in the voltage region of 2.5-4.4 V,

5

suggesting the trace lithium doping has introduced the intergrowth O3 phase, and thus

6

enhanced the reversibility of the P2-O2 phasic transition upon the continued cycling.

7

The as-fabricated Fatsia Japonica- Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 (FJ-NaLiNMC, the

8

default calcining time set as 10h) cathode exhibited a reversible capacity of ~120.6

9

mAh g-1 at 0.5C, high rate behavior and average coulombic efficiency (CE) of ~99% for

10

100 cycles. To deliver a more informative demonstration, the FJ-NaLiNMC cathode

11

was paired with an as-developed ternary metal oxide anode and assembled into a full

12

cell prototype: a stable reversible capacity, high energy density of ~152.65 Wh kg-1 at a

13

power density of ~827 W kg-1 (5C) could be realized. Noted that the biomass carbon

14

(Fatsia Japonica) was introduced as a generic sacrificial framework for both the cathode

15

and anode synthesis with the precise control over the stoichiometric ratio, particle size,

16

phase purity, uniform cation distribution and microstructure. We hope this synthetic

17

strategy will promote the low cost, scalable production of multinary oxide electrode

18

materials in the practical application of SIBs.

19 20

2. Experimental Section

21

2.1 Synthesis of FJ-NaLiNMC hybrid composite

22

Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 precursors were synthesized by co-precipitation

23

and calcination method. The cation ratio of Na/Li/Ni/Mn/Co in the as-designated

24

product of Fatsia Japonica- Na0.92Li0.40Ni0.73Mn0.24Co0.12O2 (FJ-NaLiNMC, the default

25

calcining time set as 10h) was maintained as 0.92:0.40:0.73:0.24:0.12. Briefly,

26

Ni(NO3)2 (99%, Sigma-Aldrich), Co(NO3)2 (99%, Sigma-Aldrich) and Mn(NO3)2

27

(99%, Sigma-Aldrich) were titrated into a 2 mol L-1 Na2CO3 (99%, Sigma-Aldrich)

28

solution. At the same time, the Fatsia Japonica (FJ) biomass carbon template was

1

added. After stirring for 12h, the resultant product was collected, thoroughly washed

2

and dried at 60°C overnight. The precursor was then grounded with Na2CO3 and LiNO3

3

(99%, Sigma-Aldrich) at the predetermined stoichiometric ratios. The mixture was

4

annealed in a muffle furnace at 530°C for 5h and then annealed 900°C for 10h with a

5

ramping rate of 5°C min-1. The reaction is depicted in Equation (1).

6

0.39 Na2CO3+0.40 LiNO3+ 1.22Na0.2Ni0.6Mn0.2Co0.1CO3+O2

(1)

7

Na0.92Li0.40Ni0.73Mn0.24Co0.12O2+1.61CO2+0.2N2+1.40O2

8

In the control experiments, the samples were fabricated without sacrificial

9

template framework (denoted as Pure-NaLiNMC) and without any lithium dopant

10

(denoted as FJ-NaNMC) while kept all other calcination parameters identical as

11

FJ-NaLiNMC Additionally, the samples fabricated at the different calcination time (5h,

12

10h and 20h) also were developed to investigate the influence on the morphology.

13

2.2 Synthesis of FJ-FeNiMnOx composite

14

The Fatsia Japonica-FeNiMnOx electrode was synthesized by a very simple

15

immersion-calcining process. The precursor metal nitrate was dissolved in deionized

16

water to obtain 0.5mol L-1 solution, then biomass template obtained in the previous step

17

was soaked in this solution for 12h. After being taken out, it was placed in a tube

18

furnace under argon atmosphere with 550°C calcined 2h, the final product designated

19

as FJ-FeNiMnOx.

20

2.3 Characterizations

21

The cation ratios in the composite was measured by inductively coupled plasma-optical

22

emission spectroscopy (ICP-OES), which was performed on Agilent 5110. Powder

23

X-ray diffraction (XRD) patterns were tested by transmission-mode X-ray

24

diffractometer (STADIP STOE) with a position-sensitive detector and Cu Kα1

25

radiation (1.5405 Å) scanning in the 2-Theta range of 10-70°, operating at 40 kV and 40

26

mA. Transmission-mode Operando XRD analysis was carried out by the same

27

equipment. Rietveld refinement was performed using GSAS-II. The particle size and

28

morphology of the samples were tested by field emission scanning electron microscopy

29

(SEM, Quanta 600 FEG) at 15 kV with energy-dispersive X-ray spectroscopy (EDS).

30

Transmission electron microscope (TEM, FEI Talos F200X) characterizations were

1

conducted at 200 kV. The X-ray photoelectron spectroscopy (XPS) spectra were

2

recorded with a spectrometer (Thermo escalab 250XI) having Al Kα radiation

3

(hv=1486.6 eV), the peak areas were integrated by a weighed least-squares fitting of

4

model curves. 7Li MAS NMR (I) 3 /2, 92.6% abundance) spectra were recorded on a

5

Chemagnetics Infinity operating at 155.4 and 233.2 MHz, respectively. The ex-situ XPS

6

measurements were performed using a PHI5500 spectrometer operated using a

7

monochromatic Al Kα radiation and an electron emission angle of 45°. For the ex-situ

8

XPS characterization of the FJ-NaLiNMC electrode at different potential stages,

9

Ar+-ion beam sputtering was performed for 20 mins for each sample at pressure of 20 ×

10

10−3 Pa with an emission current of 25 µA and beam energy of 4 kV. Raman spectrums

11

were taken on a Raman spectrometer (HORIBA, France) with 532 nm line of a

12

helium-neon as the excitation beam.

13

2.4 Electrochemical Measurements

14

Both the cathode and anode slurries were made by mixing the electrode material (90

15

wt.%) with acetylene black (5 wt.%) and polyvinylidene fluoride (PVDF) binder (5

16

wt.%) in an appropriate amount of 1-methyl-2-pyrrolidinone (NMP). After

17

homogenous mixing, the cathode and anode slurries were spread onto an aluminum and

18

copper foil separately, and then dried at 120°C overnight in a vacuum oven. Circular

19

slices with a diameter of 12 mm were punched from the dried foil as the working

20

electrode. CR2016 type half coin cells were assembled in a glove box with argon gas,

21

using sodium metal and glass fiber (GF/D Whatman) as reference electrode and

22

separator respectively. The electrolyte is 1M NaClO4 in propylene carbonate (PC) with

23

2 vol% fluorinated ethylene carbonate (FEC) as additive. The galvanostatic

24

charge/discharge tests were performed by Neware instrument (Shenzhen, China) at

25

room temperature within the voltage of 2.5-4.4 V (V versus Na+/Na). The Cyclic

26

voltammograms (CV) were performed on a CHI660e electrochemical workstation

27

(ChenHua Instrument Co., China) at a scan rate of 0.1 mV s−1 from 2.0 V to 4.4 V.

28

Electrochemical impedance spectroscopy (EIS) was tested on the same electrochemical

29

workstation in the frequency range between 100 kHz and 0.1 Hz. CR2016 type full coin

30

cells were prepared under the same condition, the mass ratio between cathode and

1

anode is about 1.2:1. Electrolyte and separator were the same as those used in the half

2

cells. The test was conducted between 4.4 V and 1.4 V (V versus Na+/Na).

3

Galvanostatic intermittent titration technique (GITT) was conducted on the Gamry

4

instruments (Interface 1000) with the cell charged/discharged at the current density of

5

10 mA g-1 for a pulse of 30 mins followed by a relaxation of 60 mins to approach the

6

steady state value. 1C corresponds to 110 mA g-1 for all the cell tests.

7 8

3. Results and Discussion

9

It has been a hot direction to synthesize the anode and cathode materials of SIBs

10

with excellent performance. We use biomass templating strategy to synthesize the

11

excellent cathode materials for SIBs. To validate the generic applicability of this

12

biomass templating strategy for regulating the pre-designed structural and

13

compositional features, we intentionally developed the Fatsia Japonica-FeNiMnOx

14

(FJ-FeNiMnOx) anode by optimizing the cation ratios in the precursor solution. We

15

further established a full cell prototype by paring FJ-NaLiNMC and FJ-FeNiMnOx. The

16

Schematic illustration was shown in Figure 1. The synthesis of the hybrid P2/O3

17

structure of FJ-NaLiNMC cathode began with the co-precipitation process of the

18

cation precursors with the aid of macroporous biomass framework (Figure S1). The

19

biomass precursor was sustainably recycled from the Fatsia Japonica (FJ) stem.

20

Acting as the sacrificial template, the hydroxyl groups that abundantly present on the

21

biomass framework anchored the various metal cations onto the surface, forming

22

“metal hydroxides” in a hydrocarbon matrix. During the ensuing solid-state reactions,

23

the metal hydroxides were converted into the sodiated ternary oxide with trace lithium

24

incorporation, at the same time the oxidative decomposition of the biomass

25

framework occurred. The morphology of the FJ- NaLiNMC hybrid composite was

26

approximately the reverse replication of the microporous structure of FJ biomass

27

carbon whereas the particle growth of the sodiated oxide was restrained by the gas

28

released from the thermal decomposition of the biomass template, which enabled the

29

particle size control of NaLiNMC under 800 nm with good crystallinity.

1

The cation ratio of Na/Li/Ni/Mn/Co in the as-prepared FJ-NaLiNMC hybrid

2

composite was determined as 0.90:0.40:0.72:0.24:0.12 by Inductively Coupled Plasma-

3

Optical Emission Spectroscopy (ICP-OES), which is in good accordance with the target

4

stoichiometry ratio. ICP-OES results of the control samples are shown in Table S1. The

5

X- ray diffraction (XRD) pattern of the as-synthesized FJ-NaLiNMC hybrid composite

6

is shown in Figure S2, in which most of the diffraction peaks clearly display the P2

7

phase. As compared to the sample prepared without lithium doping, namely the

8

FJ-NaNMC, the FJ-NaLiNMC hybrid composite shows the additional peak located in

9

18.4° that indexed to the O3 structure due to the lithium incorporation into the

10

lattice.[31,32] By comparing the crystallization degree and particle size (Figure S3),

11

we optimized the time duration of the calcination process as 10h. On the other hand, the

12

transmission- mode in-situ XRD was also conducted to document the real time phasic

13

transition of the solid-state reaction of the FJ-NaNMC composite upon the pre-set

14

ramping program, the result shows the onset crystallization temperature of the P2 phase

15

occurred at around ~530°C (Figure S4), in this sense, we purposely extended the

16

duration of the nucleation process at 530°C for 5h, thereby precisely promoting the

17

uniform distribution of the P2 nanocrystallines.

18

The layered P2 and O3 structures are schematically illustrated in Figure 2a-b.

19

Noted the MO2 (M=Ni, Mn, Co and Li) stacked layers arrange in the ABBA order of P2

20

structure, while the Na ions locate at the 2b sites in the trigonal prism of oxygen ions,

21

sharing the faces with two MO6 octahedrons.[33] However, O3 structure consists of a

22

cubic close-packed oxygen array in which sodium ions are accommodated at distinct

23

octahedral sites.[34] Based on the Rietveld refinement results of the XRD pattern of the

24

P2 FJ-NaNMC composite and the P2/O3 FJ-NaLiNMC hybrid composite (Figure 2c-d

25

and corresponding crystallographic lattice parameters in Table S2), the majority of the

26

doped lithium ions are positioned at the transition metal (TM) sites in the crystal

27

structure to maintain the P2 majority.[35] In comparison with the lattice parameters of

28

the P2 FJ-NaNMC, the parameters of both a and c decrease to the lower values (a from

29

2.8735(2) Å to 2.8639(1) Å, c from 11.0735(8) Å to 11.0336(3) Å), generating reduced

30

TMO2 units in c axis. As a result, the stabilization effect for the TM cations maintains the

1

structural robustness of the P2 phase. This observation is consistent with previous studies

2

including both the XRD refinement results, neutron diffraction and lithium nuclear

3

magnetic resonance.[31,34] Meanwhile, the trace amount of lithium ions occupies the

4

Na sites to generate a coexisting O3 structure (the relative mass content is estimated as

5

4.33% based on the refinement results), thereby slightly improving the retrievable

6

specific capacity for the hybrid composite without sacrificing the electrode kinetics.

7

To elucidate the doping effect on the structural features, the morphology of FJ-

8

NaLiNMC and FJ-NaNMC composites were compared in Figure 3. The transmission

9

electron microscope (TEM) image of the FJ-NaLiNMC hybrid composite, shown in

10

Figure 3a as an example, demonstrates the uniformly distributed nanoparticles ranging

11

from 500 to 800 nm. A scrutiny of the representative particle, as revealed by high

12

resolution transmission electron microscope (HRTEM) in Figure 3b-c, suggests the

13

interplanar lattice fringes spaced by 0.23 nm and 0.56 nm apart, corresponding to the

14

d-spacing values of (012) and (002) planes respectively, in the P2 structure. The

15

NaLiNMC composite synthesized without FJ as the sacrificial template (Pure-

16

NaLiNMC), in stark contrast, shows the obviously enlarged particles of ~5 um in

17

diameter (Figure S3c). This comparison clearly indicates the oxidative decomposition

18

of the biomass framework has delayed the particle growth rate. Energy dispersive

19

spectroscopy (EDS) mapping of the FJ-NaLiNMC hybrid composite, as shown in

20

Figure 3d-f, demonstrates the uniform distribution of Na, Ni, Mn and Co elements

21

across the particles, implying that the hydroxyl functional groups that abundant present

22

on the sacrificial biomass framework provide an effective anchoring effect for the

23

multinary cations.

24

The survey X-ray photoelectron spectroscopy (XPS) spectrum in Figure 4a reveals

25

the coexistence of O, Co, Na, Li, Ni and Mn elements in the FJ-NaLiNMC hybrid

26

composite. The core-level Na 1s spectrum exhibits the peak at the binding energy of

27

1071.0 eV that assignable to Na-O bond (Figure 4b). For the core-level O 1s spectrum as

28

shown in Figure 4c, the peak could be deconvoluted into the bimodal envelopes at 528.67

29

eV and 531.0 eV, assignable to the lattice oxygen and the coordinative interfacial oxygen

30

atoms, respectively.[36] As shown in the core-level Ni 2p (Figure 4d), the binding

1

energies of Ni 2p3/2 and Ni 2p1/2 position at 854.0 eV and 871.8 eV respectively,

2

corresponding to the existence of Ni2+.[25] The Mn 2p3/2 and Mn 2p1/2 peaks (Figure

3

4e) are fitted to the characteristic peaks of the tetravalent Mn with binding energy values

4

positioned at 641.6 eV and 653.4 eV, respectively.[37] The core-level Co 2p spectrum

5

exhibits the Co 2p3/2 and Co 2p1/2 (Figure 4f) peaks at the binding energies of 780.8 eV

6

and 795.1 eV, suggesting the existence of trivalent Co in the as-synthesized oxide

7

cathode.[33]

8

Figure 5a exhibits the cyclic voltammograms (CV) curves of FJ-NaLiNMC

9

cathode during the 1st, 2nd (pristine electrode after battery assembly) and 80th

10

(post-cycled electrode after 80th galvanostatic charge/discharge cycles) at a scan rate of

11

0.1 mV s-1 within the voltage range of 2.5-4.4 V. The CV curves show multiple redox

12

peaks and superimposable curves upon the cycling. The redox peak couple, within the

13

range of 2.5-3.2 V (Square I), involves the reversible faradic reaction of Mn4+/Mn3+

14

couple.[38,39] Reversible peaks between 3.2 and 4.1 V can be attributed to the redox

15

reaction of Ni2+/Ni3+ and Ni3+/Ni4+ couples (Square Ⅱ), at the same time the partially

16

vacancy ordering process via the Na+ occupancy is also involved within this

17

process.[25,27,30] Whereas the faradic process at the high-voltage range (4.1-4.4 V,

18

Square ⅡI) can be attributed to the oxygen loss and structure rearrangement process

19

from P2 to O2 phase.[39] Meanwhile, some Li ions migrate from the TM layer to the

20

Na layer at high voltage, and yet this process is highly reversible.[31] In order to ensure

21

the electrochemical reaction during charge/discharge process, ex-situ XPS and ex-situ

22

MAS NMR were applied to evaluate the different charge/discharge voltage. Ex-situ

23

MAS NMR spectra was shown in Figure S5, we can assign the resonances of ca. 1688

24

ppm and 1450 ppm to Li sites within the TMO2 layer; while the NMR resonances

25

positioned at 543, 563 and 715 ppm can be assigned to octahedrally distorted sites in

26

the Na layer. Therefore , the 7Li MAS NMR spectrum of the FJ-NaLiNMC cathode at

27

pristine state confirm the two types of the spatial occupancy of Li+; Upon the charge

28

process till 4.4 V, the resonances which represent the Li sites within the TMO2 layer

29

disappear, while the dominant resonances at ca. 0 and 95 ppm indicate the migration of

30

Li ions to the tetrahedrally distorted sites in the Na layer instead. (Chemistry of

1

Materials, 2014, 26, 1260-1269; Journal of the American Chemical Society, 2001, 123,

2

11454-11461.) [31,41] Figure S6 exhibits the ex-situ XPS spectra of Mn 2p and Ni 2p

3

at the selected discharge and charge potentials. The electrochemically reduced trivalent

4

manganese appears (BE value negatively shifted from 641.8 to 641.1 eV) when the

5

electrode was reduced from 2.8 V (Figure S6, point Ⅱ) to 2.0 V (Figure S6, point

6

Ⅱ).Afterwards, the Mn3+ species in the electrode were re-oxidized to tetravalent

7

valence during the anodic sweep from 2.0 V (Figure S6, point Ⅱ) to 2.9 V (Figure S6,

8

point Ⅱ) and maintained till 3.9 V (Figure S6, point Ⅱ). On the other hand, tetravalent

9

nickel only appears (BE value positioned at 854.8 eV) during the anodic sweep to 3.9 V

10

(from point Ⅱ to point Ⅱ), while the divalent nickel retains the valence state from point

11

Ⅱ to point Ⅱ. These reversible Mn3+/Mn4+ and Ni2+/Ni4+ redox reactions in the different

12

voltage ranges are consistent with the above CV analysis results.

13

The rate capability of FJ-NaLiNMC and FJ-NaNMC cathode were evaluated at

14

the rates ranging from 0.2C to 5C with the sodium foil as the reference electrode. As

15

shown in Figure 5b, the FJ-NaLiNMC cathode exhibits the reversible capacities are

16

133.5, 121.7, 104.4, 92.5 and 80.7 mAh g-1, at 0.2C, 0.5C, 1C, 2C and 5C, respectively.

17

Even as the C rate returns to 0.2C, the discharge capacity could deliver the initial value

18

of 129.3 mAh g-1 and maintain stable capacity in the subsequent cycles, suggesting the

19

satisfactory rate behaviors of the FJ-NaLiNMC cathode. In comparison, the

20

FJ-NaNMC cathode exhibits the reversible capacities as 120.5, 105.7, 84.8, 59.0 and

21

32.3 mAh g-1, at 0.2C, 0.5C, 1C, 2C and 5C, respectively. On the contrary, the

22

FJ-NaNMC cathode exhibits the reversible capacities are 120.5, 105.7, 84.8, 59.0 and

23

32.3 mAh g-1, at 0.2C, 0.5C, 1C, 2C and 5C, respectively. Figure 5c shows the

24

overlapped charge/discharge curves of the FJ-NaLiNMC cathode during the 1st, 50th

25

and 100th cycles, suggesting the structural robustness of the cathode upon the cycling.

26

As indicated in Figure 5d, the FJ-NaLiNMC cathode maintains the discharge capacity

27

of ~120.6 mAh g-1 for 100 cycles at 0.5C, with the CE kept higher than 98% from the 3rd

28

cycle onwards. The FJ-NaNMC cathode delivers an initial capacity of 110.6 mAh g-1

29

with the capacity retention maintained as ~54% only after 50 cycles. The lower

30

reversible capacity and serious the capacity fading can be ascribed to the irreversible

1

P2-O2 phasic transition during high operating voltage, as the integrated O3 phase is

2

absent. For comparison purpose, the as-fabricated samples under the different synthetic

3

parameters (at the different calcination durations, varied compositional ratios and

4

synthesis without FJ biomass as the sacrificial precursor) were electrochemically

5

compared in Figure S7 and Figure S8. As shown in Figure S7, the FJ-NaLiNMC-5h

6

cathode (5h represents the calcination duration at 900°C) with the poor crystallinity

7

only shows the limited initial discharge capacity of 77.8 mAh g-1 with 43% capacity

8

retention after 100 cycles. FJ-NaLiNMC-20h cathode (20h represents the calcination

9

duration at 900°C) with the enlarged particle size, in stark contrast, also demonstrates

10

the interior retrievable capacity of 82.3 mAh g-1 and unsatisfactory capacity retention

11

for 100 cycles. Figure S8 shows the cycling performance of the Pure-NaLiNMC

12

cathode at 0.5C. Without FJ biomass as the sacrificial framework, the Na+ transport is

13

retarded due to the increased solid-state diffusion range that derived from the large

14

particle size, therefore the Pure-NaLiNMC cathode shows the initial discharge capacity

15

of 81.4 mAh g-1 with a compromised capacity retention of 48% after 100 cycles.

16

Previous studies investigated the effect of the upper limit voltage on the cycling

17

stability of the electrode. As shown in Figure S9, the cycling performance of both the

18

FJ-NaLiNMC and Pure-NaLiNMC cathodes were also evaluated within the voltage

19

range of 2.5-3.9 V at 0.5C to avoid the high voltage operation. The result shows that the

20

FJ-NaLiNMC cathode demonstrates a stable reversible capacity of 90 mAh g-1 for 100

21

cycles with an initial CE value of 93%. And the Pure-NaLiNMC cathode also remains a

22

stable capacity of 80 mAh g-1 for 100 cycles with an initial CE value of 87%.

23

Obviously, the reduced upper limit voltage has ruled out the capacity contribution that

24

stems from the P2-O2 phasic transition at the voltage higher than 4 V. Therefore, the

25

better cycling stability was realized at the penalty of the reduced retrievable capacity. In

26

this sense, the FJ-NaLiNMC cathode realizes the robust cycling performance and rate

27

behaviors at the high operating voltage range, suggesting the harmony balance of the

28

optimal particle size, crystallinity and mutually beneficial phasic coupling that derived

29

from the deliberate optimization of the calcination time and the compositional

30

stoichiometric ratio of the hybrid composite.

1

The improved rate capability in FJ-NaLiNMC electrode suggests faster charge

2

transport kinetics, thus, we conducted Galvanostatic intermittent titration technique

3

(GITT) to investigate the Na+ diffusion coefficient of cycled FJ-NaLiNMC and

4

FJ-NaNMC electrodes. During the single galvanostatic titration process (Figure S10a

5

and S10c, Figure S11a and S11c), the obvious linear relationship can be observed

6

between the voltage and the square root of the galvanostatic time (Figure S10b and S10d,

7

Figure S11b and S11d). The plot of Na+ diffusivity as a function of voltage during the

8

charge and discharge process is shown in Figure 6 (Details of GITT analysis can be found

9

in the Supporting Information). Overall, the values of D for FJ-NaLiNMC is higher than

10

FJ-NaNMC in general. These results reveal the lithium incorporation will facilitate

11

electrode kinetics and enhance the rate capability performance.

12

Figure S12 shows the electrochemical impedance spectra (EIS) results of

13

FJ-NaLiNMC and Pure-NaLiNMC cathodes both after the initial cycle and

14

post-mortem (after 50 cycles). The Nyquist plots consist of 1) a semicircle which

15

suggests the charge transfer resistance (Rct) and 2) a quasi-straight line, with the slope

16

positively correlating with the Warburg diffusion coefficient in the solid state.[42] As

17

shown in Figure S12a, the Pure-NaLiNMC cathode demonstrates the obvious enlarged

18

semicircle after 50 cycles, suggesting the increase of Rct, while the reduced slope of

19

Warburg diffusion region also indicates the retarded ion diffusion in the solid-state.

20

Compared to the Pure-NaLiNMC electrode, the FJ-NaLiNMC cathode does not

21

demonstrate the obvious change for either the Rct or the slope of Warburg diffusion

22

region, as illustrated in Figure S12b. This comparison indicates the lithium

23

incorporation in the structural lattice has enhanced the charge transfer kinetics at the

24

electrode/electrolyte interface and eased the solid-state lithium diffusion.

25

To track the dynamic structural evolution of the FJ-NaLiNMC cathode upon the

26

sodiation and desodiation process, transmission-mode operando XRD tests were

27

conducted to document the real-time phasic changes of the cathode structures,

28

especially upon the high operating voltage as shown in Figure 7. The FJ-NaLiNMC

29

cathode exhibits the (002) diffraction peak of the P2 phase positioned at 15.3°. Upon

30

the initial desodiation process until the high voltage of 4.2 V, this diffraction peak does

1

not exhibit obvious variation in terms of the peak intensity and the 2-Theta position

2

(Figure 7a-b), with the further sodium extraction from the structural lattice above 4.2

3

V, the peak intensity of (002) diffraction peak suddenly declined, involving the

4

structural transition from P2 phase to O2 phase. Upon the sodiation process, the peak

5

intensity of (002) diffraction peak gradually restored as the electrode discharge below

6

4.2 V. This phasic transition involving the P2-O2 phasic transition remained reversible

7

even after 60 cycles with the reappearance of the identifiable (002) diffraction peak

8

(Figure 7c). The transmission-mode operando XRD results suggest the highly

9

reversible P2-O2 phasic transition upon the high operating voltage of the FJ-NaLiNMC

10

cathode. In comparison, the FJ-NaNMC cathode without the lithium doping

11

demonstrates the obvious mitigated (002) peak upon the cycling. As shown in Figure

12

7d-e, this diffraction peak almost disappeared as the FJ-NaNMC cathode was charged

13

higher than 4.0 V. This observation clearly implies the compromised structural

14

robustness upon the continuous cycling, accounting for the drastic structural distortion

15

of P2 phase upon the high voltage cycling. After 60 cycles within the range of 2.5-4.4

16

V, we clearly observe the mitigated (002) diffraction peak with the gradually reduced

17

peak intensity (Figure 7f). Therefore, the FJ-NaNMC cathode demonstrates the

18

irreversibility of the P2-O2 phasic transition upon the high operating voltage, and this

19

reversible process accompanies with the compromised capacity retention for the

20

cathode.

21

The post-cycling TEM analysis was also conducted as the FJ-NaLiNMC cathode

22

was disassembled from the half cell at the fully discharged state (2.5 V). As shown in

23

Figure 8a, the formation of a well-crystallized region of the fully discharged electrode

24

(2.5 V) was observed on the cathode particle with the lattice fringes spaced by 0.333

25

nm, corresponding to (002) planes of the P2 structure. As shown in Figure 8b, the

26

selected area electron diffraction (SAED) pattern further demonstrates the diffraction

27

points that are indexed to (100), (010) and (110) of the P2 structure. This observation

28

suggests the well preservation of the robust P2 structure after 60 cycles of reversible

29

P2-O2 phasic transition, which is consistent with the operando XRD results. In

30

comparison, the HRTEM and SAED pattern of FJ-NaNMC cathode at the fully

1

discharged state (2.5 V) are shown in Figure 8c-d. Noted the spacing in-between the

2

crystal faces are not discernable, demonstrating an irreversible P2-O2 phasic transition

3

occurred after 60 cycles. Meanwhile, the SAED pattern of the post-cycled FJ-NaNMC

4

cathode indicates its polycrystalline characteristic due to the structure collapse.

5

Obviously, the heterophane was irreversibly generated after 60 cycles, leading to the

6

deterioration of the electrochemical performance.

7

The full cell prototype model through pairing the FJ-FeNiMnOx anode and

8

FJ-NaLiNMC cathode. The characterization and electrochemical measurements of the

9

FJ-FeNiMnOx oxide anode via half cells were elaborated in Figure S13-S14. Figure 9a

10

records the galvanostatic charge-discharge curves for the full cell measured at 0.5C.

11

The charge-discharge curves during the 1st, 50th, 100th cycles almost overlapped, while

12

the reversible charge and discharge capacities maintained at ~100 mAh g-1 for 100

13

cycles. The cycling performance of the full cell was evaluated at 0.5C (Figure 9b), the

14

first discharge and charge capacities were recorded as 105.4 mA h g−1 and 112.1 mA h

15

g−1, leading to an initial CE value as ~95%. Afterwards, the CE value maintained higher

16

than 98% during the subsequent 100 cycles. After a total 100 cycles, the reversible

17

capacity still recovered to 102.97 mAh g-1 with 98% capacity retention. As displayed in

18

Figure 9c, the full cell demonstrates an impressive rate behavior of 123.2, 103.4, 92.6,

19

83.5 and 72.3 mAh g-1 at 0.2, 0.5, 1, 2 and 5C, respectively. In sharp contrast, the full

20

cell assembled by paring the FJ-NaNMC cathode and FJ-FeNiMnOx anode

21

demonstrates an inferior cycling stability and rate capability, the capacity decayed from

22

107.8 to 29.8 mAh g-1 only after 30 cycles (Figure S15). Based on the calculation of the

23

supplementary note, the FJ-FeNiMnOx and FJ-NaLiNMC full cell prototype realizes a

24

gravimetric energy density of ~152.65 Wh kg-1 at a power density of ~827 W kg-1

25

(5C).[43] In this sense, our as-developed full cell model which derived from the

26

biomass framework realizes the simultaneous structural robustness, balanced

27

high-power/energy densities at a low production cost.

28 29

4. Conclusions

1

In summary, we have synthesized a layered oxide cathode of the P2/O3 hybrid

2

composite through the co-precipitation and subsequent solid reaction process. By the

3

aid of transmission-mode operando XRD technique, we could precisely document the

4

real-time phasic transition of the solid-state reaction and the dynamic peak shift upon

5

the galvanostatic cycling process, enabling our deliberate compositional engineering of

6

the lithium incorporation into both the TM sites and the Na sites to facilitate the

7

intergrowth of O3 phase. Electrochemical evaluations of the FJ-NaLiNMC cathode

8

prove the simultaneous realization of the high retrievable capacity, structural robustness

9

and rate behaviors in both the half and full cell models, validating the pivotal role of the

10

enhanced reversibility of the phasic transition upon the high operating voltage.

11

Moreover, the sustainable recycling of the biomass framework for the cathode/anode

12

designs in this study demonstrates the generic applicability of our synthetic protocol to

13

regulate the structural and compositional features of the multinary oxide, and thus

14

exhibits the tremendous potential in the developments of high-performance SIBs.

15 16 17

Appendix A. Supporting information Supplementary data associated with this article can be found in the online version

18 19

at……

20 21

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1

Figures and Figure Caption

2 3

Figure 1. Schematic illustration of (a) the design FJ-NaLiNMC and FJ-FeNiMnOx

4

composite and (b) the FJ-NaLiNMC||FJ-FeNiMnOx full cell prototype model.

5

1 2

Figure 2. Schematic illustration of the layered structure of (a) P2 and (b) O3. The

3

Rietveld refinement of the reference phases for the (c) FJ-NaNMC composite and (d)

4

FJ-NaLiNMC hybrid composite.

1 2

Figure 3. (a) TEM image, (b-c) HRTEM images of FJ-NaLiNMC hybrid

3

composite. (d) SEM images of FJ-NaLiNMC hybrid composite. The

4

energy-dispersive X-ray spectroscopy of FJ-NaLiNMC particle with the elemental

5

maps of (e) Na, (f) Ni, (g) Mn and (h) Co respectively.

6

1 2

Figure 4. (a) Survey XPS spectrum of FJ-NaLiNMC hybrid composite. (b) Na 1s and

3

(c) O 1s core-level XPS spectrum of FJ-NaLiNMC hybrid composite. (d) Ni 2p,

4

(e) Mn 2p and (f) Co 2p core-level XPS spectrum of FJ-NaLiNMC hybrid

5

composite fitted with multiple envelopes.

6

1 2

Figure 5. (a) The 1st, 2nd and 80th CV curves of the FJ-NaLiNMC cathode at a scan

3

rate of 0.1 mV s-1 within the voltage range of 2.5-4.4 V. (b) The rate capability at

4

different rates of 0.2C, 0.5C, 1C, 2C and 5C for FJ-NaLiNMC and FJ-NaNMC

5

cathodes. (c) The 1st, 50th, and 100th charge–discharge curves of the FJ-NaLiNMC

6

cathode at 0.5C within the voltage range of 2.5-4.4 V. (d) The cycling performance

7

and the CE of the FJ-NaLiNMC and FJ-NaNMC cathodes at 0.5C.

8 9 10 11 12 13 14

1 2

Figure 6. GITT profiles and Na+ diffusivity of FJ-NaLiNMC cathode for (a) charge and

3

(b) discharge process; GITT curves and Na+ diffusivity of FJ-NaNMC cathode for (c)

4

charge and (d) discharge process.

5

1 2

Figure 7. (a) The electrochemical load curves during operando XRD measurement of

3

the phasic changes of the FJ-NaLiNMC cathode and colour maps of the 2nd (after initial

4

charge/discharge on the battery testing system) complete electrochemical cycle. (b)

5

Operando XRD patterns of the 2nd and (c) 60th (after 60 cycles charge/discharge on the

6

battery testing system) of the FJ-NaLiNMC cathode during galvanostatic charge and

7

discharge within the range of 2.5-4.4 V at 0.2C. (d) The corresponding electrochemical

8

load curves during operando XRD measurement of the phasic changes of the FJ-

9

NaNMC cathode and color maps of the 2nd complete electrochemical cycle. (e)

10

Operando XRD patterns collected during the 2nd and (f) 60th of the FJ-NaNMC cathode

11

during galvanostatic charge and discharge within the range of 2.5-4.4 V at 0.2C.

1 2

Figure 8. (a) The HRTEM image and (b) SAED pattern of FJ-NaLiNMC cathode

3

at the fully discharge state (2.5 V) after 60 cycles. (c) The HRTEM image and (d)

4

SAED pattern of FJ-NaNMC cathode at the fully discharge state (2.5 V) after 60

5

cycles.

1 2

Figure 9. (a) The charge–discharge profiles of the FJ-NaLiNMC||FJ-FeNiMnOx

3

full cell in different 1st, 50th, and 100th cycles at 0.5C within the voltage range of

4

1.4–4.4 V. (b) The cycling performance at 0.5C and (c) The rate capability at

5

different rates of 0.2C, 0.5C, 1C, 2C and 5C of FJ-NaLiNMC||FJ-FeNiMnOx full

6

cell. (d) Ragone plot of the SIBs full cell models based on the cathode and anode

7

mass.

8 9

Conflict of interest statement The authors declare no competing financial interest.

Acknowledgements We acknowledged the financial support of this work by the National Natural Science Foundation of China (51602261 and 51711530037), the Research Fund of the State Key Laboratory of Solidification Processing (NWPU), China (Grant No.160-QP2016), the Natural Science Foundation of Shaanxi Province (2018JM5116), the Fundamental Research Funds for the Central Universities (3102019JC005), and Young Talent fund of University Association for Science and Technology in Shaanxi, China. Furthermore, we would like to thank the Analytical & Testing Center of Northwestern Polytechnical University for providing some test equipment.