Smart adsorbents for CO2 capture: Making strong adsorption sites respond to visible light

Wu, Qiurong; Tan, Peng; Gu, Chen; Zhou, Rui; Qi, Shi‐Chao; Liu, Xiaoqin; Jiang, Yao; Sun, Lin

doi:10.1007/s40843-020-1423-8

Cited by 17 publications

(19 citation statements)

References 47 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…On the industrial scale, the majority CO 2 emission from flue gas into the atmosphere has been mostly captured by aqueous amine scrubbing due to the mature process and low cost . However, its widespread implementation has been inhibited by the parasitic energy consumption through solvent regeneration, high toxicity together with equipment corrosion in the regeneration process. , To overcome those issues, the CO 2 capture using solid adsorbents is an attractive alternative thanks to its low energy consumption, facile operation, and ease for practical applications. , Therefore, the scientific and industrial communities have focused on the advancement of solid-state adsorbents with low energy requirements and easy reversibility for efficient CO 2 adsorption. For this purpose, numerous adsorbents such as porous carbons, ,− zeolites, porous polymers, − covalent organic frameworks (COFs), and metal–organic frameworks (MOFs) , have been widely investigated in the past decades.…”

Section: Introductionmentioning

confidence: 99%

Efficient N-Doped Porous Carbonaceous CO₂ Adsorbents Derived from Commercial Urea-Formaldehyde Resin

et al. 2022

View full text Add to dashboard Cite

The porous carbons have attracted tremendous interest for CO2 capture application thanks to their abundant availability and tunable physical properties. However, they suffer from insufficient CO2 utilization performance due to the poor active sites on their surface. Herein, we report for the first time the fabrication of urea-formaldehyde resin-derived N-rich porous carbon via two-step synthetic routes with physical carbonization followed by KOH activating. The optimized sample included 9.87 wt % N exhibit notable CO2 uptake capacities (5.42 and 3.53 mmol g–1 at 0 and 25 °C at 1 bar) and high selectivity efficiency of 23 between CO2 and N2 at ambient pressure. Overall, on the basis of the in-depth characterization techniques, the advanced textural properties and incorporation of nitrogen into carbon surfaces contribute to increasing the CO2 uptake capacity and selectivity efficiency.

show abstract

Section: Introductionmentioning

confidence: 99%

Efficient N-Doped Porous Carbonaceous CO₂ Adsorbents Derived from Commercial Urea-Formaldehyde Resin

et al. 2022

View full text Add to dashboard Cite

show abstract

“…In this regard, novel smart adsorbents were synthesized by modification of target-specific chemical active sites (that avoid the employment of ultraviolet light) through introduction of primary and secondary amines into azobenzene functionalized metal-organic frameworks for tunable carbon capture [27,[29][30][31]. The target-specific amine sites render the adsorbent significantly selective in carbon capture from gas mixtures, and the azobenzene groups act as light-responsive switches to influence the adsorbent-adsorbate interactions.…”

Section: Methodsmentioning

confidence: 99%

Evaluation of adsorbent materials for carbon dioxide capture

Shamiri¹,

Shafeeyan

2022

Materialwissenschaft Werkst

View full text Add to dashboard Cite

Global warming has in recent years become a cause for serious concern. It is believed to result from the release of greenhouse gases into the atmosphere, particularly carbon dioxide. Upon assessing the recent developments, it can be learnt that attempts in relation to the reduction of anthropogenic carbon dioxide content and decreasing the emission of greenhouse gases appear to be among the key issues. Despite a range of technologies and approaches established over the years, the issue of separating carbon dioxide from gas streams still cannot be addressed. Notwithstanding having developed new methods, another substantial challenge identified in the area is the growth of adsorbents with relatively higher performance. It is worthy of note that they help balance an array of optimization‐needed factors which include efficiency, engineering feasibility and costs. Zeolites, metal‐organic frameworks, silica and activated carbon are among the adsorption materials which are widely discussed in the literature. Accordingly, recent studies focusing on such materials are comprehensively discussed and summarized in this review. Besides, the cost, carbon capture capacity and selectivity which are among the major concerns with respect to selecting adsorbents are compared in this paper. Furthermore, both the privileges and drawbacks of each type of adsorbent are presented in this manuscript. Despite the encouraging results achieved in this study, developing more effective adsorbents to capture carbon dioxide remains a fundamental challenge. Therefore, further innovations regarding the design and synthesis of adsorbents are essential for future applications.

show abstract

“…DFT calculations indicate that the adsorption behavior originates from the interplay between azobenzene and amine within the pores of the adsorbent. Such adsorption behavior also appears in the POSAs modified with azobenzene and different amines. − Consequently, by utilizing the synergistic interaction between azobenzenes and amines, selective adsorption for CO 2 is achieved, and moreover, the energy consumption of desorption is reduced as well.…”

Section: Posas With Controllable Adsorption Sitesmentioning

confidence: 96%

Process-Oriented Smart Adsorbents: Tailoring the Properties Dynamically as Demanded by Adsorption/Desorption

et al. 2021

Self Cite

View full text Add to dashboard Cite

Metrics & MoreArticle Recommendations CONSPECTUS: Adsorptive separation plays a critical role in chemical, food, pharmaceutical, and environmental industries, as well as in many other industrial areas. Adsorbents are most important for adsorptive separation and undergo adsorption and desorption processes to accomplish the specific tasks of separation. In the process of adsorption, adsorbates diffuse into the pore spaces of adsorbents through pore openings, adsorb on active sites via physical or chemical interactions, and subsequently are regenerated by temperature or pressure swings during desorption. In the process of adsorption and desorption, however, the requirements for pore structures and surface properties of adsorbents are different. In general, adsorbents with small pore openings can realize selective adsorption and do not favor desorption; on the other hand, adsorbents with large pore openings are efficient in desorption but at the expense of adsorption selectivity. Remarkably, active sites possessing strong interactions with adsorbates contribute to high selectivity for adsorption, while desorption becomes difficult. The trade-off between adsorption and desorption presents an enormous challenge to develop high-efficiency adsorbents. Restricted by their fixed structures and surface properties, conventional adsorbents are unable to meet the demands of adsorption and desorption processes simultaneously.To confront the obstacles, the development of advanced adsorbents to meet the demand of adsorptive separation are urgent. A key strategy to address such issues lies in dynamically adjusting the pore structures or the surface properties of adsorbents with controllability according to the demands of adsorption/desorption. For instance, pursuant to the requirements of varying pore structures during adsorption/desorption, the pore openings of adsorbents can be customized through dynamic structural change of the decorated stimuli-sensitive motifs by suitable external intervention. In addition, the active sites within the adsorbents can be exposed to enhance the adsorption selectivity or sheltered to accelerate the desorption through stimuli-triggered adsorbent− adsorbate interactions. Hence, we proposed a concept of process-oriented smart adsorbents (POSAs) on the basis of the requirements of the adsorption/desorption processes. The design and development of such POSAs are based on three aspects, namely, pore openings, pore spaces, and adsorption sites of adsorbents.In this Account, we present the progress in the development of POSAs according to the demands of adsorption/desorption processes. A series of POSAs with incorporated stimuli-sensitive motifs were successfully achieved. The versatility of incorporated motifs allows them to tune the pore structures and surface properties of adsorbents dynamically and further to enhance the adsorption and desorption efficiency simultaneously. Based on the concept of POSAs, we hope that this Account could contribute to the development of high-efficiency adsorbents and ul...

show abstract

Smart adsorbents for CO2 capture: Making strong adsorption sites respond to visible light

Cited by 17 publications

References 47 publications

Efficient N-Doped Porous Carbonaceous CO₂ Adsorbents Derived from Commercial Urea-Formaldehyde Resin

Efficient N-Doped Porous Carbonaceous CO₂ Adsorbents Derived from Commercial Urea-Formaldehyde Resin

Evaluation of adsorbent materials for carbon dioxide capture

Process-Oriented Smart Adsorbents: Tailoring the Properties Dynamically as Demanded by Adsorption/Desorption

Contact Info

Product

Resources

About

Smart adsorbents for CO2 capture: Making strong adsorption sites respond to visible light

Cited by 17 publications

References 47 publications

Efficient N-Doped Porous Carbonaceous CO2 Adsorbents Derived from Commercial Urea-Formaldehyde Resin

Efficient N-Doped Porous Carbonaceous CO2 Adsorbents Derived from Commercial Urea-Formaldehyde Resin

Evaluation of adsorbent materials for carbon dioxide capture

Process-Oriented Smart Adsorbents: Tailoring the Properties Dynamically as Demanded by Adsorption/Desorption

Contact Info

Product

Resources

About

Efficient N-Doped Porous Carbonaceous CO₂ Adsorbents Derived from Commercial Urea-Formaldehyde Resin

Efficient N-Doped Porous Carbonaceous CO₂ Adsorbents Derived from Commercial Urea-Formaldehyde Resin