One-Pot Synthesis of Rubber Seed Shell-Derived N-Doped Ultramicroporous Carbons for Efficient CO2 Adsorption

In this work, a series of novel rubber seed shell-derived N-doped ultramicroporous carbons (NPCs) were prepared by one-step high-temperature activation (500–1000 °C), using melamine as the nitrogen source and KOH as the activator. The effects of the melamine dosage and the activation temperatures on the surface chemical properties (doped N contents and N species), textural properties (surface area, pore structure, and microporosity), CO2 adsorption capacities, and CO2/N2 selectivity were thoroughly investigated and characterized. These as-prepared NPCs demonstrate controllable BET surface areas (398–2163 m2/g), ultramicroporosity, and doped nitrogen contents (0.82–7.52 wt%). It was found that the ultramicroporosity and the doped nitrogens significantly affected the CO2 adsorption and the separation performance at low pressure. Among the NPCs, highly microporous NPC-600-4 demonstrates the largest CO2 adsorption capacity of 5.81 mmol/g (273 K, 1.0 bar) and 3.82 mmol/g (298 K, 1.0 bar), as well as a high CO2/N2 selectivity of 36.6, surpassing a lot of reported biomass-based porous carbons. In addition, NPC-600-4 also shows excellent thermal stability and recycle performance, indicating the competitive application potential in practical CO2 capture. This work also presents a facile one-pot synthesis method to prepare high-performance biomass-based NPCs.


Introduction
With the rapid development of global industrialization and frequent human activity, excessive CO 2 has been emitted into the atmosphere, causing the ever-increasing atmospheric CO 2 concentration and triggering worsening global warming, the melting of polar ice, the rise of the sea level, and serious natural disasters [1][2][3][4]. Thus, carbon capture and sequestration (CCS) have been proposed and regarded as an effective tool to mitigate global CO 2 emissions. Currently, the mainstream CO 2 capture technologies mainly include chemical amine absorption, membrane separation, and adsorption [5,6]. Among these technologies, adsorption via solid porous adsorbents has become a promising solution and a research hotspot due to the merits of a reduced regeneration energy penalty, the freedom from corrosion, the easy operation, and the low cost.
Typically, N-doped porous carbons are obtained from a two-step chemical activation process: the carbonization of precursors and further chemical activation in the presence

Materials and Pretreatment
Rubber seed shell was obtained from Huakun Biotechnology Co., Ltd. (Xishuangbanna, China). The fresh rubber seed shell was washed and then dried in an oven at 80 • C until the water content was less than 3 wt%. The dried rubber seed shell was pulverized with a pulverizer and passed through a 60-mesh sieve to obtain a raw material of rubber seed shell powder, which was used for later use. Melamine (99%), potassium hydroxide (KOH, AR), and hydrogen chloride (HCl, AR) were purchased from Beijing Chemical Works (Beijing, China). Other solvents and reagents were used as received.

Preparation of RSS-Derived NPCs
The pretreated powdered RSS was chemically activated using a mixture of KOH and melamine at high temperatures. The influence of nitrogen source addition was investigated first. The RSS (3.0 g) was thoroughly mixed with KOH (6.0 g) and a varied dosage of melamine powder (melamine/RSS weight ratio = 0.2, 0.4, 0.6, 0.8, 1) in a mortar. Then, the mixture was placed in a porcelain crucible and subjected to a high temperature at 700 • C (5 • C/min) in a tube furnace under nitrogen flow (50 mL/min) and held at the desired temperature for 60 min. Additionally, the obtained products were denoted as NPC-700-x (x = 1~5). After the carbonization was completed, the tube furnace was cooled to room temperature naturally. The obtained carbonized samples were soaked in hydrochloric acid aqueous solution (1 mol/L) for 6 h to remove excessive inorganic salt residue, filtered, and washed repeatedly with deionized water until the pH was neutral. The products were further dried in an oven at 80 • C for 12 h under high vacuum. In addition, the effect of the activation temperatures (500 • C, 600 • C, 800 • C, 900 • C, 1000 • C) was also investigated at the optimized melamine addition (NPC-700-4), and the obtained products were denoted as NPC-y-4 (y = 500~1000).

Instrumentation
Fourier transform infrared spectra (FT-IR, Transmission mode, 400-4000 cm −1 ) of the NPCs were measured on a Thermo Nicolet 8700 (Thermo Fisher, Waltham, MA, USA) by compressing the mixture of samples and KBr into a disk. Additionally, the mass ratio of a sample to KBr was controlled to be 1: 100. Powder X-ray diffraction patterns (PXRD) of NPCs were recorded on a UItima IV diffractometer (Rigaku Corporation, Matsubara-cho. Akishima-shi, Tokyo, Japan) with Cu Kα at 40 kV and 30 mA. Field emission scanning electron microscope (FE-SEM) of the samples was observed on a ZEISS Gemini 300 (Carl Zeiss Microscopy GmbH, Oberkochen, Germany) operated at 10 kV. CHNS elemental analysis was determined by Vario EL cube (Elementar Analysensysteme GmbH, Langenselbold, Germany). X-ray photoelectron spectroscopy (XPS) of the samples was measured on an ESCALAB 250Xi spectrometer (Thermo Fisher, Waltham, MA, USA). The 77 K N 2 adsorption and adsorption isotherms were measured using an Autosorb-iq gas sorption analyzer (Quantachrom, Boynton Beach Station, FL, USA). All the samples were degassed at 120 • C for 12 h under high vacuum prior to the gas adsorption measurement. The specific surface area, pore size and micropore volume, and pore volume of NPCs were calculated from the obtained 77 K N 2 adsorption isotherms via different models and conditions.

Gas Adsorption Tests
The static adsorption and desorption isotherms of N 2 and CO 2 were measured by using an Autosorb-iq gas sorption analyzer. The CO 2 (99.999%) and N 2 (99.999%) gases were utilized for the adsorption and desorption measurements. The adsorption and desorption isotherms at 273 K were measured in an ice-water bath, and isotherms at 298 K were measured in a circulating water bath.

Chemical Structures and Morphology
The rubber seed shell was converted to black carbon via one-step activation at a high temperature (500-1000 • C) for 1 h (displayed in Scheme 1). The chemical compositions and surface chemical properties of the NPCs were investigated by FTIR, elemental analysis and XPS. Figure 1 displays the FTIR spectra of NPC-700-x and NPC-y-4. For all the NPC-700-x and NPC-y-4 (y ≥ 700 • C) samples, their FTIR spectra are similar. The absorption band at 1180 cm −1 can be attributed to the stretching vibration of C-N [33]. The bands at 3430 cm −1 and 1634 cm −1 can be associated with both the stretching vibration and the bending vibration of -OH (hydroxyl, carboxyl) and -NH x (amino group, amide) [33][34][35]. It should be noted that NPC-500-4 and NPC-600-4 demonstrate obviously different absorption peaks at 1395 cm −1 and 809 cm −1 . The band at 809 cm −1 is a characteristic out-of-plane ring bending of the triazine ring [36]. Additionally, the sharp absorption peak at 1395 cm −1 should be related to the stretching vibration of the melem unit [37,38]. It can be reasonably inferred that melamine gradually decomposes into NH 3 , melem, and graphite-like carbon nitrides. These NH 2 -containing intermediates will further react with KOH-related intermediates, carboxyl, hydroxyl, or carbonyl of the RSS precursor. At a lower activation temperature (500, 600 • C), these NH 2 -containing groups may be well incorporated in the carbon skeleton. However, these NH 2 -containing groups will convert to other N-containing groups such as pyridine, pyrrole, and graphitic N under very high activation temperature (>700 • C) [39]. In addition, this is also supported by the gradually weakened absorption band at 1395 cm −1 with the activation temperature increase. were utilized for the adsorption and desorption measurements. The adsorption and desorption isotherms at 273 K were measured in an ice-water bath, and isotherms at 298 K were measured in a circulating water bath.

Chemical Structures and Morphology
The rubber seed shell was converted to black carbon via one-step activation at a high temperature (500-1000 °C) for 1 h (displayed in Scheme 1). The chemical compositions and surface chemical properties of the NPCs were investigated by FTIR, elemental analysis and XPS. Figure 1 displays the FTIR spectra of NPC-700-x and NPC-y-4. For all the NPC-700-x and NPC-y-4 (y ≥ 700 °C) samples, their FTIR spectra are similar. The absorption band at 1180 cm −1 can be attributed to the stretching vibration of C-N [33]. The bands at 3430 cm −1 and 1634 cm −1 can be associated with both the stretching vibration and the bending vibration of -OH (hydroxyl, carboxyl) and -NHx (amino group, amide) [33][34][35]. It should be noted that NPC-500-4 and NPC-600-4 demonstrate obviously different absorption peaks at 1395 cm −1 and 809 cm −1 . The band at 809 cm −1 is a characteristic out-of-plane ring bending of the triazine ring [36]. Additionally, the sharp absorption peak at 1395 cm −1 should be related to the stretching vibration of the melem unit [37,38]. It can be reasonably inferred that melamine gradually decomposes into NH3, melem, and graphite-like carbon nitrides. These NH2-containing intermediates will further react with KOH-related intermediates, carboxyl, hydroxyl, or carbonyl of the RSS precursor. At a lower activation temperature (500, 600 °C), these NH2-containing groups may be well incorporated in the carbon skeleton. However, these NH2-containing groups will convert to other N-containing groups such as pyridine, pyrrole, and graphitic N under very high activation temperature (>700 °C) [39]. In addition, this is also supported by the gradually weakened absorption band at 1395 cm −1 with the activation temperature increase. The obtained XPS spectra of NPC-700-x and NPC-y-4 are shown in Figure S1 and Figure 2a. It is easily observed that the N1s XPS signal increases with the increasing melamine addition and drops with the increasing activation temperature. Combing the above FTIR spectra analysis of the NPCs, it can be concluded that the doped N content and the N species in the NPCs should be different. Additionally, it is also confirmed by the elemental analysis data and the XPS-derived elemental analysis data (Table 1). From the data shown in Table 1, the C and N contents obtained from the two methods are basically consistent. After high-temperature N-doped activation, the C and N contents of the NPCs were significantly increased, and the O content was greatly reduced. As expected, the doped N contents in the NPC-700-x samples increased with the enhancing melamine addition and the maximum value reached 7.52 wt%. However, the doped N content data of the NPC-y-4 samples show that the activation temperature gradually improved the doped N contents in the range of 500~700 • C ( Figure 2a). As the activation temperatures increased to 1000 • C, the doped N contents sharply decreased to 0.82 wt%, suggesting that high activation temperatures will cause the loss of nitrogens during the pyrolysis [15]. The obtained XPS spectra of NPC-700-x and NPC-y-4 are shown in Figures S1 and 2a. It is easily observed that the N1s XPS signal increases with the increasing melamine addition and drops with the increasing activation temperature. Combing the above FTIR spectra analysis of the NPCs, it can be concluded that the doped N content and the N species in the NPCs should be different. Additionally, it is also confirmed by the elemental analysis data and the XPS-derived elemental analysis data (Table 1). From the data shown in Table 1, the C and N contents obtained from the two methods are basically consistent. After high-temperature N-doped activation, the C and N contents of the NPCs were significantly increased, and the O content was greatly reduced. As expected, the doped N contents in the NPC-700-x samples increased with the enhancing melamine addition and the maximum value reached 7.52 wt%. However, the doped N content data of the NPCy-4 samples show that the activation temperature gradually improved the doped N contents in the range of 500~700 °C ( Figure 2a). As the activation temperatures increased to 1000 °C, the doped N contents sharply decreased to 0.82 wt%, suggesting that high activation temperatures will cause the loss of nitrogens during the pyrolysis [15].     To figure out the N species of the as-prepared N-doped carbons, the N1s XPS spectra are analyzed and shown in Figure 2b-e, Figures S1 and S2b-f. The N1s spectra of four peaks at 398.4, 400.2, 400.6, and 402.8 eV were attributed to pyridine/triazine nitrogen (N-6), pyrrole nitrogen (N-5), amine (-NH x ), and graphitic nitrogen (N-Q), respectively [13,15,39]. All the NPC-700-x samples show similar N1s spectra and N species. As can be observed from Figure 2f, the N species vary significantly among the NPC-y-4. With the increasing activation temperature (500-700 • C), amine decreased and pyrrolic-N and graphitic-N increased. As the activation temperature reached over 800 • C, the amine species disappeared, and the pyrrolic-N and pyridine/triazine nitrogen obviously decreased. The different doped N contents and N species should play an important role in determining the CO 2 adsorption and selectivity. The C1s XPS spectra of NPC-700-x and NPC-y-4 are displayed in Figure S3 and Figure 3. All the samples show similar C species, the C1s spectra of three peaks at 284.8, 286.1, and 289.9 eV can be relative to C-C/C=C, C=N/C-N/C-O and O=C-O, respectively [40,41]. This means that some -COOH and -OH can be preserved in the resultant NPCs.  [40,41]. This means that some -COOH and -OH can be preserved in the resultant NPCs.  Figure 4 shows the SEM morphology and structures of NPC-700-x and NPC-y-4. All the NPCs samples demonstrate an irregular shape with some obvious pores/cavities on the surface, confirming the pore-forming ability of KOH chemical activation [14]. The Xray diffraction patterns of NPC-700-x and NPC-y-4 are displayed in Figure 5. All the NPC-700-x and NPC-y-4 samples demonstrate two weak broad diffraction peaks near 23° and  Figure 4 shows the SEM morphology and structures of NPC-700-x and NPC-y-4. All the NPCs samples demonstrate an irregular shape with some obvious pores/cavities on the surface, confirming the pore-forming ability of KOH chemical activation [14]. The X-ray diffraction patterns of NPC-700-x and NPC-y-4 are displayed in Figure 5. All the NPC-700-x and NPC-y-4 samples demonstrate two weak broad diffraction peaks near 23 • and 43 • , corresponding to the (002) and (100) plane, respectively [34]. These weak peaks indicate the amorphous structures of the NPCs. Additionally, the increased intensities of peak (100) at 43 • imply the presence of graphitized carbon and a higher degree of graphitization with the increasing activation temperature [42].   Figures 6 and S4 display the Raman spectra of NPC-700-x and NPC-y-4. Two characteristic peaks at around 1596 cm −1 (G band) and 1320 cm −1 (D band) are associated with the E2g model of the graphite layer and the vibrations of carbons with dangling bonds, respectively [42]. The intensity ratio of the D band and G band (ID/IG) is indicative of the defects and disorder degree of the carbon materials. The ID/IG values of NPC-700-x and NPC-y-4 exceed or reach 1.0 (Table S1), suggesting the amorphous carbon structure with a high content of lattice edges or defects [43]. Additionally, the ID/IG ratios of NPC-y-4 decrease with the activation temperature (from 1.23 to 0.97), showing that a higher acti-      Figure S4 display the Raman spectra of NPC-700-x and NPC-y-4. Two characteristic peaks at around 1596 cm −1 (G band) and 1320 cm −1 (D band) are associated with the E2g model of the graphite layer and the vibrations of carbons with dangling bonds, respectively [42]. The intensity ratio of the D band and G band (I D /I G ) is indicative of the defects and disorder degree of the carbon materials. The I D /I G values of NPC-700-x and NPC-y-4 exceed or reach 1.0 (Table S1), suggesting the amorphous carbon structure with a high content of lattice edges or defects [43]. Additionally, the I D /I G ratios of NPCy-4 decrease with the activation temperature (from 1.23 to 0.97), showing that a higher activation temperature can promote the degree of graphitization of the NPCs.

Textural Properties
The textural properties of the NPCs and RSS were investigated by 77 K N2 analysis (Figures 7 and S5), and the derived specific surface areas, pore volumes, and porosity data were summarized in Table 2. The RSS shows the characteristic type-IV adsorption isotherms [44,45], indicating its mesoporous structure. The BET specific surface area (SBET) and total pore volume (Vtotal) of RSS are only 40 m 2 /g and 0.049 cm 3 /g. As shown in Figure  7a,c, all the NPC-700-x and NPC-y-4 samples demonstrate a steep N2 uptake increase at a very low relative pressure region (P/P0 < 0.01), which is indicative of the abundant micropores in these resultant N-doped carbons [44,45]. In addition, the gradual N2 uptake increase at the higher relative pressure region suggests the presence of some mesopores. Furthermore, the pore size distribution curves (Figure 7b,d) show that the as-obtained NPCs possess a large number of ultramicropores (<0.7 nm), implying that NPCs are promising for the adsorption of CO2 with a molecular kinetic diameter of 0.33 nm [11,25,46].

Textural Properties
The textural properties of the NPCs and RSS were investigated by 77 K N 2 analysis (Figure 7 and Figure S5), and the derived specific surface areas, pore volumes, and porosity data were summarized in Table 2. The RSS shows the characteristic type-IV adsorption isotherms [44,45], indicating its mesoporous structure. The BET specific surface area (S BET ) and total pore volume (V total ) of RSS are only 40 m 2 /g and 0.049 cm 3 /g. As shown in Figure 7a,c, all the NPC-700-x and NPC-y-4 samples demonstrate a steep N 2 uptake increase at a very low relative pressure region (P/P 0 < 0.01), which is indicative of the abundant micropores in these resultant N-doped carbons [44,45]. In addition, the gradual N 2 uptake increase at the higher relative pressure region suggests the presence of some mesopores. Furthermore, the pore size distribution curves (Figure 7b,d) show that the as-obtained NPCs possess a large number of ultramicropores (<0.7 nm), implying that NPCs are promising for the adsorption of CO 2 with a molecular kinetic diameter of 0.33 nm [11,25,46].     As can be seen from Figure 7a and Table 2, the increase in the melamine dosage can greatly improve the porosity of NPC-700-x. Among the NPC-700-x samples, NPC-700-4 possesses the largest S BET (1190 m 2 /g), S micro (1010 m 2 /g), V micro (0.411 cm 3 /g), V ultramicro (0.21 cm 3 /g), and micropore volume ratio V micro /V total (0.682). These apparent sharp increases in porosity are attributed to the introduction of melamine during pyrolysis (Figure 4a-e) [47,48]. In addition, the trend of increasing porosity is basically consistent with the order of the doped nitrogen content. However, the porosity of NPC-700-5 decreases at a higher melamine addition. Thus, the optimum mass ratio of RSS, KOH, and melamine is 1:2:0.8.

RSS
On the other hand, activation temperature also plays an important role in tuning the porosity and chemical properties of NPC-y-4. As the activation temperatures increase, the S micro , V micro , micropore volume ratio V micro /V total , and doped N content increase continuously. This is because the increased high temperatures favor KOH in etching the carbon skeletons to generate a porous network [14]. NPC-800-4 has the highest S BET (2163 m 2 /g), S micro (1209 m 2 /g), V micro (0.544 cm 3 /g), and V total (1.323 cm 3 /g), far surpassing all previously reported RSS-based PCs [28][29][30][31][32]49]. However, as the activation temperatures surpass 800 • C, the adsorption isotherms show an obvious hysteresis loop, suggesting the formation of mesoporous pore structures. Notably, the doped nitrogen content and the ultramicropore volumes drastically decrease due to the higher activation temperature.

CO 2 Adsorption and Selectivity
Motivated by both the high microporosity and the doped nitrogen content, the CO 2 adsorption performance of the RSS-derived NPCs were investigated at 273 K and 298 K, respectively. Additionally, the corresponding CO 2 adsorption-desorption isotherms at both temperatures are displayed in Figure 8. All the NPCs samples demonstrate a continuous increase in CO 2 uptakes with the increasing pressure and have not yet reached saturation, suggesting that larger CO 2 uptakes can be achieved at higher pressures [17,50]. Additionally, these completely reversible adsorption and desorption isotherms also confirm that the CO 2 adsorption of the NPCs is physisorption in nature. Additionally, this is also evidenced by the obviously decreased CO 2 uptakes at a higher temperature of 298 K (Figure 8b,d). Among the NPC-700-x, NPC-700-4 has the highest CO 2 uptake of 4.45 mmol/g (273 K, 1.0 bar, Table 3), which is due to its large microporosity and high doped N content. The abundant polar N sites (amine, pyrrole N, and pyridine N) on the wall of micropores can strongly enhance the interaction between CO 2 and the NPCs through quadrupole-dipole interaction. Interestingly, the CO 2 adsorption performance of NPC-700-3 surpasses NPC-700-5. The doped N content, S BET , S micro , and V micro values of NPC-700-5 are even slightly higher than those of NPC-700-3, which should be attributed to its higher ultramicropore volume (Table 2). Additionally, the ultramicropores (<0.7 nm) are conducive to a greatly improved CO 2 adsorption capacity and selectivity at low partial pressure [11,25].    NPC-600-4 shows much higher CO 2 uptakes than other NPC-y-4 and NPC-700-x; the maximum CO 2 uptakes can reach 5.81 mmol/g and 3.82 mmol/g at 1.0 bar, 273 K and 298 K (Table 3), respectively. This is mainly due to its simultaneous high doped nitrogen content (6.60 wt%), second largest S micro (1144 m 2 /g), the largest V micro (0.452 cm 3 /g), and the micropore volume ratio. In particular, the CO 2 uptakes of NPC-600-4 can reach 2.29 mmol/g and 1.23 mmol/g at 0.15 bar, which is a typical CO 2 partial pressure of flue gas. These values surpass some typical solid sorbents under identical measurement conditions, such as MOFs [7], covalent organic framework [10], zeolites [8] and N-rich porous organic polymer [51]. Interestingly, NPC-500-4 has the second largest CO 2 uptake at low pressure (P < 0.4 bar, 273 K and P < 1 bar, 298 K), which is due to its higher amine content and large ultramicropore volume. The amine group and ultramicropores can significantly improve the CO 2 adsorption capacity via molecular sieving and quadrupole-dipole interaction.
To further understand the interaction between the CO 2 molecules and the NPCs, the isosteric heat of adsorption (Q st ) was calculated from the obtained adsorption isotherms (273 K, 298 K) in terms of the Clausius-Clapeyron equation [52]: where P is the pressure, Q st (kJ/mol) is the isosteric heat of adsorption, R is the gas constant, T (K) is the temperature, and C is the equation constant. The dependencies of the Q st and CO 2 adsorption capacity are shown in Figure 9. For each sample, the Q st values greatly decrease with the CO 2 uptake, suggesting that the interaction between the CO 2 molecules and the porous N-doped carbon surface is much stronger than that between the CO 2 molecules [50,51]. Moreover, the ranking order of the Q st values is basically consistent with the order of the CO 2 uptakes. It can be observed that the Q st values of NPC-700-x, NPC-500-4, and NPC-600-4 surpass 40 kJ/mol, implying that the interaction intensity is much stronger. This is mainly attributed to the higher basicity resulting from these basic N species, which can provide lone-pair electrons of N atoms. These polar N sites can promote CO 2 affinity through dipole-quadrupole interaction. Among all the NPCs, NPC-600-4 has the highest Q st values. To further understand the interaction between the CO2 molecules and the NPCs, the isosteric heat of adsorption (Qst) was calculated from the obtained adsorption isotherms (273 K, 298 K) in terms of the Clausius-Clapeyron equation [52]: where P is the pressure, Qst (kJ/mol) is the isosteric heat of adsorption, R is the gas constant, T (K) is the temperature, and C is the equation constant. The dependencies of the Qst and CO2 adsorption capacity are shown in Figure 9. For each sample, the Qst values greatly decrease with the CO2 uptake, suggesting that the interaction between the CO2 molecules and the porous N-doped carbon surface is much stronger than that between the CO2 molecules [50,51]. Moreover, the ranking order of the Qst values is basically consistent with the order of the CO2 uptakes. It can be observed that the Qst values of NPC-700-x, NPC-500-4, and NPC-600-4 surpass 40 kJ/mol, implying that the interaction intensity is much stronger. This is mainly attributed to the higher basicity resulting from these basic N species, which can provide lone-pair electrons of N atoms. These polar N sites can promote CO2 affinity through dipole-quadrupole interaction. Among all the NPCs, NPC-600-4 has the highest Qst values. The limiting adsorption enthalpies of the NPCs at zero surface coverage (Q0) were also calculated from the CO2 adsorption isotherms at different temperatures, using the Virial equation and the Vant Hoff equation [53]. The plotted Viral curves and the k0, A0 data for NPC-700-x and NPC-y-4 are shown in Figure S6 and Table S2. The calculated Q0 values of NPC-700-x and NPC-y-4 are in the range of 33.9-36.4 kJ/mol and 21.8-37.4 kJ/mol (Table 3), respectively. The apparent Q0 decrease with the activation temperature increase should be ascribed to the loss of nitrogens at a higher activation temperature. The limiting adsorption enthalpies of the NPCs at zero surface coverage (Q 0 ) were also calculated from the CO 2 adsorption isotherms at different temperatures, using the Virial equation and the Vant Hoff equation [53]. The plotted Viral curves and the k 0 , A 0 data for NPC-700-x and NPC-y-4 are shown in Figure S6 and Table S2. The calcu-lated Q 0 values of NPC-700-x and NPC-y-4 are in the range of 33.9-36.4 kJ/mol and 21.8-37.4 kJ/mol (Table 3), respectively. The apparent Q 0 decrease with the activation temperature increase should be ascribed to the loss of nitrogens at a higher activation temperature. These further evidence the importance of N doping on enhancing the CO 2 adsorption of NPCs. Thus, for efficient low-pressure CO 2 capture, a moderate activation temperature (<700 • C) should be adopted.
In order to evaluate the practical separation property of the NPCs, the adsorption isotherms of N 2 at 298 K were measured and compared with those of CO 2 in Figure S7 and Figure 10. It can be seen that the CO 2 uptakes of all the NPCs samples are considerably larger than the N 2 in the whole measured pressure range, indicating the high CO 2 /N 2 adsorption selectivity. The ideal solution adsorption solution (IAST) was adopted to calculate the CO 2 /N 2 adsorption selectivity from the simulated flue (15% CO 2 /85% N 2 ) at 298 K. Figure 11 displays that the IAST CO 2 /N 2 selectivities of the NPCs drop with the pressure increase. At 298 K and 1.0 bar, NPC-500-4 also exhibits a highest CO 2 /N 2 selectivity of 44.6 ( Table 3), resulting from its large ultramicropore volume and abundant doped nitrogens (amine, pyrrolic-N, pyridine-N, and graphitic-N). Compared with the N 2 molecules, the CO 2 molecules have a smaller molecular kinetic diameter and a larger quadrupole moment. These ultramicropores and polar N-containing sites can strongly improve the interaction between the CO 2 molecules and the pore surface via the molecular sieving effect and the quadrupole-dipole interaction. NPC-800-4 possesses the largest micropore volume and BET surface area, while the CO 2 /N 2 selectivity is only 10.8. This is mainly due to the low doped N content, confirming that higher polar nitrogen doping is the key factor for improving CO 2 /N 2 selectivity. The CO 2 /N 2 selectivity of NPC-600-4 is high up to 36.6, surpassing a large number of N-doped porous carbons under identical measurement conditions (Table 4) [17,18,[54][55][56][57][58][59][60][61][62]. The high CO 2 /N 2 adsorption selectivity and large CO 2 uptakes under ambient conditions can be attributed to the ultramicroporosity and abundant doped N species. selectivity. The ideal solution adsorption solution (IAST) was adopted to calculate the CO2/N2 adsorption selectivity from the simulated flue (15% CO2/85% N2) at 298 K. Figure  11 displays that the IAST CO2/N2 selectivities of the NPCs drop with the pressure increase. At 298 K and 1.0 bar, NPC-500-4 also exhibits a highest CO2/N2 selectivity of 44.6 ( Table  3), resulting from its large ultramicropore volume and abundant doped nitrogens (amine, pyrrolic-N, pyridine-N, and graphitic-N). Compared with the N2 molecules, the CO2 molecules have a smaller molecular kinetic diameter and a larger quadrupole moment. These ultramicropores and polar N-containing sites can strongly improve the interaction between the CO2 molecules and the pore surface via the molecular sieving effect and the quadrupole-dipole interaction. NPC-800-4 possesses the largest micropore volume and BET surface area, while the CO2/N2 selectivity is only 10.8. This is mainly due to the low doped N content, confirming that higher polar nitrogen doping is the key factor for improving CO2/N2 selectivity. The CO2/N2 selectivity of NPC-600-4 is high up to 36.6, surpassing a large number of N-doped porous carbons under identical measurement conditions (Table 4) [17,18,[54][55][56][57][58][59][60][61][62]. The high CO2/N2 adsorption selectivity and large CO2 uptakes under ambient conditions can be attributed to the ultramicroporosity and abundant doped N species.    [55] In addition to the high CO2 adsorption capacity and the CO2/N2 selectivity, the recycle performance of the adsorbents also matters in practical applications. Figure 12 presents the five consecutive CO2 adsorption-desorption cycles of NPC-600-4 at 273 K. After each adsorption process, the adsorbent is regenerated by high-vacuum desorption, and it is directly used for another adsorption cycle. After five cycles, the CO2 adsorption capacity of NPC-600-4 merely drops, suggesting the excellent recycle performance. Given the superior CO2 adsorption capacity, CO2/N2 selectivity, and good recycle performance, NPC-600-4 is promising in CO2 capture applications.   [55] In addition to the high CO 2 adsorption capacity and the CO 2 /N 2 selectivity, the recycle performance of the adsorbents also matters in practical applications. Figure 12 presents the five consecutive CO 2 adsorption-desorption cycles of NPC-600-4 at 273 K. After each adsorption process, the adsorbent is regenerated by high-vacuum desorption, and it is directly used for another adsorption cycle. After five cycles, the CO 2 adsorption capacity of NPC-600-4 merely drops, suggesting the excellent recycle performance. Given the superior CO 2 adsorption capacity, CO 2 /N 2 selectivity, and good recycle performance, NPC-600-4 is promising in CO 2 capture applications. Nanomaterials 2022, 12, x FOR PEER REVIEW 16 of 19

Conclusions
In summary, a series of rubber seed shell-based N-doped porous carbons were prepared by one-pot high-temperature activation. The obtained NPCs demonstrated tunable microporosity and doped nitrogen content by adjusting the nitrogen source dosage and the activation temperature. The BET surface areas and doped nitrogen contents of the NPCs were in the range of 398-2163 m 2 /g and 0.82-7.52 wt%, respectively. It was found that the ultramicroporosity and polar nitrogens significantly affected the CO2 adsorption performances at low pressure. Among the RSS-based NPCs, highly microporous NPC-600-4 possesses the largest CO2 uptakes of 5.81 mmmol/g (273 K,1.0 bar) and 3.82 mmol/g (298 K, 1.0 bar), as well as the high CO2/N2 selectivity of 36.6, far exceeding a variety of reported biomass-based porous carbons. In addition, NPC-600-4 also shows excellent thermal stability and recycle performance, confirming the competitive application potential in practical CO2 capture.
Author Contributions: X.Z.: methodology, investigation, writing-original draft; M.R.: conceptualization, methodology, resources, writing-original draft, writing-review and editing; H.C.: formal analysis, writing-review and editing, funding acquisition, project administration; T.T.: conceptualization, project administration, funding acquisition, resources, supervision, writing-review and editing. All authors have read and agreed to the published version of the manuscript.

Conclusions
In summary, a series of rubber seed shell-based N-doped porous carbons were prepared by one-pot high-temperature activation. The obtained NPCs demonstrated tunable microporosity and doped nitrogen content by adjusting the nitrogen source dosage and the activation temperature. The BET surface areas and doped nitrogen contents of the NPCs were in the range of 398-2163 m 2 /g and 0.82-7.52 wt%, respectively. It was found that the ultramicroporosity and polar nitrogens significantly affected the CO 2 adsorption performances at low pressure. Among the RSS-based NPCs, highly microporous NPC-600-4 possesses the largest CO 2 uptakes of 5.81 mmmol/g (273 K,1.0 bar) and 3.82 mmol/g (298 K, 1.0 bar), as well as the high CO 2 /N 2 selectivity of 36.6, far exceeding a variety of reported biomass-based porous carbons. In addition, NPC-600-4 also shows excellent thermal stability and recycle performance, confirming the competitive application potential in practical CO 2 capture.
Author Contributions: X.Z.: methodology, investigation, writing-original draft; M.R.: conceptualization, methodology, resources, writing-original draft, writing-review and editing; H.C.: formal analysis, writing-review and editing, funding acquisition, project administration; T.T.: conceptualization, project administration, funding acquisition, resources, supervision, writing-review and editing. All authors have read and agreed to the published version of the manuscript.