The utilization of nuclear power will persist as a prominent energy source in the foreseeable future.However,it presents substantial challenges concerning waste disposal and the potential emission of untreated radioac...The utilization of nuclear power will persist as a prominent energy source in the foreseeable future.However,it presents substantial challenges concerning waste disposal and the potential emission of untreated radioactive substances,such as radioactive 129I and 131I.The transportation of radioactive iodine poses a significant threat to both the environment and human health.Nevertheless,effectively,rapidly removing iodine ion from water using porous adsorbents remains a crucial challenge.In this work,three kinds of multiple sites porous organic polymers(POPs,POP-1,POP-2,and POP-3)have been developed using a monomer pre-modification strategy for highly efficient and fast I_(3) absorption from water.It is found that the POPs exhibited exceptional performance in terms of I3 adsorption,achieving a top-performing adsorption capacity of 5.25 g g^(-1) and the fastest average adsorption rate(K_(80%)=4.25 g g^(-1) h^(-1))with POP-1.Moreover,POP-1 exhibited exceptional capacity for the removal of I3 fromflowing aqueous solutions,with 95%removal efficiency observed even at 0.0005 mol L^(-1).Such results indicate that this material has the potential to be utilized for the emergency preparation of potable water in areas contaminated with radioactive iodine.The adsorption process can be effectively characterized by the Freundlich model and the pseudo-second-order model.The exceptional I_(3) absorption capacity is primarily attributed to the incorporation of a substantial number of active adsorption sites,including bromine,carbonyl,and amide groups.展开更多
The Wireless Sensor Network(WSN)is a network of Sensor Nodes(SN)which adopt radio signals for communication amongst themselves.There is an increase in the prominence of WSN adaptability to emerging applications like t...The Wireless Sensor Network(WSN)is a network of Sensor Nodes(SN)which adopt radio signals for communication amongst themselves.There is an increase in the prominence of WSN adaptability to emerging applications like the Internet of Things(IoT)and Cyber-Physical Systems(CPS).Data secur-ity,detection of faults,management of energy,collection and distribution of data,network protocol,network coverage,mobility of nodes,and network heterogene-ity are some of the issues confronted by WSNs.There is not much published information on issues related to node mobility and management of energy at the time of aggregation of data.Towards the goal of boosting the mobility-based WSNs’network performance and energy,data aggregation protocols such as the presently-used Mobility Low-Energy Adaptive Clustering Hierarchy(LEACH-M)and Energy Efficient Heterogeneous Clustered(EEHC)scheme have been exam-ined in this work.A novel Artificial Bee Colony(ABC)algorithm is proposed in this work for effective election of CHs and multipath routing in WSNs so as to enable effective data transfer to the Base Station(BS)with least energy utilization.There is avoidance of the local optima problem at the time of solution space search in this proposed technique.Experimentations have been conducted on a large WSN network that has issues with mobility of nodes.展开更多
Highly sensitive stimuli-responsive luminescent materials are crucial for appli-cations in optical sensing,security,and anticounterfeiting.Here,we report two zero-dimensional(0D)copper(I)halides,(TEP)_(2)Cu_(2)Br_(4),...Highly sensitive stimuli-responsive luminescent materials are crucial for appli-cations in optical sensing,security,and anticounterfeiting.Here,we report two zero-dimensional(0D)copper(I)halides,(TEP)_(2)Cu_(2)Br_(4),(TEP)_(2)Cu_(4)Br_(6),and 1D(TEP)_(3)Ag_(6)Br_(9),which are comprised of isolated[Cu_(2)Br_(4)]^(2-),[Cu_(4)Br_(6)]^(2-),and[Ag_(6)Br_(9)]3-polyanions,respectively,separated by TEP^(+)(tetraethylphosphonium[TEP])cations.(TEP)_(2)Cu_(2)Br_(4) and(TEP)_(2)Cu_(4)Br_(6) demonstrate greenish-white and orange-red emissions,respectively,with near unity photoluminescence quantum yields,while(TEP)_(3)Ag_(6)Br_(9) is a poor light emitter.Optical spectroscopy mea-surements and density-functional theory calculations reveal that photoemissions of these compounds originate from self-trapped excitons due to the excited-state distor-tions in the copper(I)halide units.Crystals of Cu(I)halides are radioluminescence active at room temperature under both X-andγ-rays exposure.The light yields up to 15,800 ph/MeV under 662 keVγ-rays of ^(137)Cs suggesting their potential for scintillation applications.Remarkably,(TEP)_(2)Cu_(2)Br_(4) and(TEP)_(2)Cu_(4)Br_(6) are inter-convertible through chemical stimuli or reverse crystallization.In addition,both compounds demonstrate luminescence on-off switching upon thermal stimuli.The sensitivity of(TEP)_(2)Cu_(2)Br_(4) and(TEP)_(2)Cu_(4)Br_(6) to the chemical and thermal stimuli coupled with their ultrabright emission allows their consideration for applications such as solid-state lighting,sensing,information storage,and anticounterfeiting.展开更多
基金support from the National Natural Science Foundation of China(No.22273016,22273017,22233006)Plan for Henan Province University Science and Technology Innovation Team(No.25IRTSTHN002)+1 种基金Young Backbone Teacher Training Program of Henan Province(2023GGJS036)the 111 project(No.D17007).
文摘The utilization of nuclear power will persist as a prominent energy source in the foreseeable future.However,it presents substantial challenges concerning waste disposal and the potential emission of untreated radioactive substances,such as radioactive 129I and 131I.The transportation of radioactive iodine poses a significant threat to both the environment and human health.Nevertheless,effectively,rapidly removing iodine ion from water using porous adsorbents remains a crucial challenge.In this work,three kinds of multiple sites porous organic polymers(POPs,POP-1,POP-2,and POP-3)have been developed using a monomer pre-modification strategy for highly efficient and fast I_(3) absorption from water.It is found that the POPs exhibited exceptional performance in terms of I3 adsorption,achieving a top-performing adsorption capacity of 5.25 g g^(-1) and the fastest average adsorption rate(K_(80%)=4.25 g g^(-1) h^(-1))with POP-1.Moreover,POP-1 exhibited exceptional capacity for the removal of I3 fromflowing aqueous solutions,with 95%removal efficiency observed even at 0.0005 mol L^(-1).Such results indicate that this material has the potential to be utilized for the emergency preparation of potable water in areas contaminated with radioactive iodine.The adsorption process can be effectively characterized by the Freundlich model and the pseudo-second-order model.The exceptional I_(3) absorption capacity is primarily attributed to the incorporation of a substantial number of active adsorption sites,including bromine,carbonyl,and amide groups.
文摘The Wireless Sensor Network(WSN)is a network of Sensor Nodes(SN)which adopt radio signals for communication amongst themselves.There is an increase in the prominence of WSN adaptability to emerging applications like the Internet of Things(IoT)and Cyber-Physical Systems(CPS).Data secur-ity,detection of faults,management of energy,collection and distribution of data,network protocol,network coverage,mobility of nodes,and network heterogene-ity are some of the issues confronted by WSNs.There is not much published information on issues related to node mobility and management of energy at the time of aggregation of data.Towards the goal of boosting the mobility-based WSNs’network performance and energy,data aggregation protocols such as the presently-used Mobility Low-Energy Adaptive Clustering Hierarchy(LEACH-M)and Energy Efficient Heterogeneous Clustered(EEHC)scheme have been exam-ined in this work.A novel Artificial Bee Colony(ABC)algorithm is proposed in this work for effective election of CHs and multipath routing in WSNs so as to enable effective data transfer to the Base Station(BS)with least energy utilization.There is avoidance of the local optima problem at the time of solution space search in this proposed technique.Experimentations have been conducted on a large WSN network that has issues with mobility of nodes.
文摘Highly sensitive stimuli-responsive luminescent materials are crucial for appli-cations in optical sensing,security,and anticounterfeiting.Here,we report two zero-dimensional(0D)copper(I)halides,(TEP)_(2)Cu_(2)Br_(4),(TEP)_(2)Cu_(4)Br_(6),and 1D(TEP)_(3)Ag_(6)Br_(9),which are comprised of isolated[Cu_(2)Br_(4)]^(2-),[Cu_(4)Br_(6)]^(2-),and[Ag_(6)Br_(9)]3-polyanions,respectively,separated by TEP^(+)(tetraethylphosphonium[TEP])cations.(TEP)_(2)Cu_(2)Br_(4) and(TEP)_(2)Cu_(4)Br_(6) demonstrate greenish-white and orange-red emissions,respectively,with near unity photoluminescence quantum yields,while(TEP)_(3)Ag_(6)Br_(9) is a poor light emitter.Optical spectroscopy mea-surements and density-functional theory calculations reveal that photoemissions of these compounds originate from self-trapped excitons due to the excited-state distor-tions in the copper(I)halide units.Crystals of Cu(I)halides are radioluminescence active at room temperature under both X-andγ-rays exposure.The light yields up to 15,800 ph/MeV under 662 keVγ-rays of ^(137)Cs suggesting their potential for scintillation applications.Remarkably,(TEP)_(2)Cu_(2)Br_(4) and(TEP)_(2)Cu_(4)Br_(6) are inter-convertible through chemical stimuli or reverse crystallization.In addition,both compounds demonstrate luminescence on-off switching upon thermal stimuli.The sensitivity of(TEP)_(2)Cu_(2)Br_(4) and(TEP)_(2)Cu_(4)Br_(6) to the chemical and thermal stimuli coupled with their ultrabright emission allows their consideration for applications such as solid-state lighting,sensing,information storage,and anticounterfeiting.
