Journal of Radiation Research and Radiation Processing
Co-Editors-in-Chief
Guozhong WU
2024
Volume: 42 Issue 4
10 Article(s)
Jin ZHANG, Yanglin ZHANG, Kun LIU, Shizhong ZHOU, Yuesheng LI, and Huangqin CHEN

Fingerprints are an important trace material evidence for police to identify criminal. Cadmium sulfide quantum dots (CdS QDs) are fluorescent-labeled nanomaterials that can be used to improve the clarity and resolution of fingerprints. In this study, thioglycollic acid (TGA) was successfully modified to CdS QDs using the in-situ radiation reduction method, and synthetic TGA-CdS QDs were combined with polyvinyl acetate (PVAc) to form a TGA-CdS QDs/PVAc gel fingerprint film for fingerprint development. The structure and properties of the TGA-CdS QDs were characterized and tested using Fourier transform infrared (FTIR) spectroscopy, fluorescence spectrum, X-ray diffraction (XRD), and scanning electron microscopy (SEM). The effects of temperature, concentration of TGA-CdS QDs, pH, and mass fraction of the PVAc gel fingerprint film on fingerprint development were investigated. The results showed that a combination of 6 mg/mL TGA-CdS QDs solution with 20% PVAc gel fingerprint film at room temperature (25 ℃) and pH of 9.0 resulted in the clearest, most complete, and high-resolution fingerprint patterns of fluorescence display. The carboxylic acid group formed by TGA-CdS QDs in an alkaline solution completely combined with the amino acids, proteins, fats, urea, and other components of the fingerprint residue attached to the PVAc gel film. Under ultraviolet irradiation, the fingerprint lines were clearly displayed in the form of fluorescence. The fingerprint display method can be effectively used in criminal investigation.

Aug. 20, 2024
  • Vol. 42 Issue 4 040201 (2024)
  • Maojiang ZHANG, Yanfu WU, Kexin CUI, Xinwei ZHANG, Jinghua WANG, Chunlei DONG, Jie GAN, and Guozhong WU

    This study investigated the impact of low-dose electron beam irradiation on the structure-property correlation of linear low-density polyethylene (LLDPE), ternary copolymer polypropylene (co-PP), and their blends. Effects of the absorbed dose on the rheological properties, strength, crystallization behavior, crystal structure, and mechanical properties of LLDPE/co-PP blended polyolefins with various blending ratios were examined. The melt index test results indicate that, for LLDPE: co-PP ratios of 3∶1 and 1∶1, the melt index of each prepared polyolefin decreases and its crosslinking degree increases as the absorbed dose increases. However, for a LLDPE: co-PP ratio of 1∶3, the crosslinking degree of the polyolefin decreased with increasing absorbed dose. The crystal structure and crystallization behavior of the polyolefins were minimally affected by their absorbed doses, however, varying the ratios of blended LLDPE and co-PP affected the crystallization of both LLDPE and co-PP. For a blend with 1: 1 ratio, an absorbed dose greater than 2 kGy resulted in a sample elongation at break exceeding 890% and a fracture strength of 25.4 MPa those of both LLDPE and co-PP. Additionally, the stress-strain curves of the prepared polyolefins indicated that the absorbed dose enhanced the compatibility between LLDPE and co-PP. Thus, low-dose irradiation of LLDPE/co-PP polyolefins would offer a new avenue of research on polyolefin product development.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040203 (2024)
  • Lili FU, Zhijun WANG, Kun LIU, Dongxu TANG, Jinyu YANG, Huangqin CHEN, and Yuesheng LI

    Trichloroacetic acid is a common nonvolatile byproduct of drinking water disinfection and poses carcinogenic risks to the human body. In this study, four types of nano-oxide@microcrystalline-cellulose-based adsorbents (P25@microcrystalline cellulose, SiO?@microcrystalline cellulose (MCC-g-GMA@SiO2), Fe3O4@microcrystalline cellulose, and Fe2O3@microcrystalline cellulose) were successfully prepared by the pre-radiation grafting-embedding method. Subsequently, their ability to remove trichloroacetic acid from drinking water was investigated. The micro zonation morphology and surface properties of the materials were characterized and tested using Fourier transform infrared spectroscopy (FTIR), X-ray diffraction spectroscopy (XRD), Thermogravimetric (TG) analysis, and Scanning electron microscopy (SEM) characterization methods. The effects of monomer concentration, embedding concentration, and absorbed dose on the weight gain rate were systematically investigated. A complete static adsorption equilibrium curve was obtained on the basis of the results of adsorption experiments of four buried nano-oxides. The performance of SiO2@microcrystalline cellulose was found to be significantly higher than that of the other three adsorbents. When the volum percentage of monomer concentration was 30%, the mass percentage of embedding concentration was 4%, and the absorbed dose was 60 kGy, the removal rate of trichloroacetic acid in drinking water reached 83.27%. This series of adsorbent materials present significant potential for practical application in drinking water purification.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040204 (2024)
  • Lijun HU, Xuanzhi MAO, Xinxin FENG, Hongwei HAN, Jiangtao HU, and Guozhong WU

    Fiber absorbents are among the most economical materials for uranium extraction from seawater. Marine organisms are prone to fouling while being deployed in the sea, severely impairing the adsorption properties of the fiber. In this study, a novel antimicrobial adsorbent (UHMWPE-g-GEAO) was prepared by grafting guanidino and amidoxime groups onto ultra-high molecular weight polyethylene (UHMWPE) using radiation-induced graft polymerization technique. The guanidino groups endowed the fiber with excellent resistance to biofouling, enabling it to kill 99.9% of Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus). UHMWPE-g-GEAO fibers exhibited a fast uranium adsorption rate and high adsorption capacity, reaching 156.00 mg/g in aqueous solution and 1.39 mg/g in real seawater within 14 days. Additionally, the adsorbent exhibited superior reusability, preserving more than 94.5% of its adsorption efficiency and 96.2% of its desorption efficiency after five adsorption-desorption cycles. In this study, a reusable UHMWPE antimicrobial adsorbent fiber with promising potential for uranium extraction from seawater was developed.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040205 (2024)
  • Dan ZHAO, Junfang ZHANG, Minghua LYU, Yu LI, and Duoxin ZHAO

    During the normal operation of cooling towers in nuclear power plants, water vapor with a certain temperature is discharged through the outlet of the cooling tower, which mixes with the surrounding air. A portion of this vapor condenses and forms visible plumes. This paper uses Computational fluid dynamics (CFD) numerical simulation software to simulate six nuclear power units and their supporting cooling towers at a nuclear power plant site, and studies the impact of plumes emitted from the six cooling towers under different wind directions on the radioactive diffusion of the nuclear power plant discharge. The research results indicate that when the arrangement direction of the cooling towers is consistent with the wind direction,the influence of the cooling towers on the environmental flow field extends to a distance of approximately 1 500 m in the downwind direction. When the cooling towers are located in the downwind direction of the reactor unit, the emission from the cooling towers increases the pollution diffusion factor within a 1 000 m range of the chimney. As the environmental wind speed increases, the impact of the cooling tower emissions on the diffusion of pollutants from the chimney decreases.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040701 (2024)
  • Songke YU, Dong WANG, and Julan XIAO

    Diamond is considered a promising detector in radiobiological studies. However, the difference in densities between diamond and tissue imply that their energy deposition spectra are not identical, even for diamond and tissues of the same size. The energy deposition spectrum in diamond was converted to match a tissue sample of the same size. A method based on a mathematical model of energy deposition distribution and the Fourier transform was proposed. The results indicate that the spectra converted from diamond to tissue align closely with those of the tissue. Nevertheless, the applicability of this method is constrained by the mathematical model of energy deposition distribution. Thus, developing a mathematical model that describes the energy deposition spectrum under various conditions can enhance the applicability of this conversion method.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040702 (2024)
  • Yan WANG, Ailian MENG, Xin JIA, Jiawei YE, Pan XU, Yanjun ZHANG, Yalu QIU, Jiang HE, Tengxiao MAO, and Peng GAO

    Volatile components are one of the main active components of Ligusticum chuanxiong Hort and are important indicators for evaluating the medicinal quality of Ligusticum chuanxiong. To explore the effects of 60Co-γ irradiation on the volatile components of Ligusticum chuanxiong,thesamples were treated with different irradiation doses, and the changes of the volatile components before and after irradiation were analyzed using an electronic nose combined with headspace solid-phase microextraction and gas chromatography-mass spectrometry. Principal component analysis (PCA), linear discriminant analysis (LDA), orthogonal partial least squares discriminant analysis (OPLS-DA), and cluster statistical analysis were used to elucidate changes in the volatile components of Ligusticum chuanxiongbefore and after irradiation. The electronic nose detection results and gas chromatography–mass spectrometry detection results indicated that ketone alkanes, alcohols, aldehydes, and ketones contributed to the odor of Ligusticum chuanxiong. Irradiation treatments at doses ≤10 kGy had no significant effect on the odor of Ligusticum chuanxiong. The results demonstrated that after irradiation at 0 kGy (control group), 3 kGy, 7 kGy, and 10 kGy, 60 compounds were identified in Ligusticum chuanxiong, including 23 hydrocarbons, 12 alcohols, 10 lipids, and 4 aldehydes or ketones, and 11 others. There were mainly 21 volatile substances that changed after irradiation, accounting for approximately 12.92% of the volatile components in Ligusticum chuanxiong; however, they were not the main volatile components of Ligusticum chuanxiong. No new compounds were identified in Ligusticum chuanxiongafter irradiation treatment within a dose of 10 kGy. The results provide a theoretical basis and reference for the influence of 60Co-γ irradiation on the quality of Ligusticum chuanxiong samples and also lay a certain foundation for the application of irradiation in Ligusticum chuanxiong pieces and traditional Chinese medicine and simple preparation resources. The results indicate that the treatment of 60Co-γ irradiation on the Ligusticum chuanxiong samples with doses ?10 kGy does not affect its main volatile components.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040401 (2024)
  • Chao ZHOU, Zhen LI, Lingxi LI, Wenbao JIA, and Yongsheng LING

    Polylactic acid (PLA) plastic waste has significant potential for methane production in anaerobic digestion, but its slow degradation rate hinders efficient fermentation. Pre-treatment of PLA plastic waste can enhance anaerobic fermentation efficiency, promoting resource utilization. PLA plastic cup sample was pre-treated by irradiation with 60Co-γ ray to study the changes of PLA molecular structure and soluble substance content under the irradiation with absorbed doses of 0, 20, 40 and 60 kGy. And the effect of ionizing irradiation on the anaerobic fermentation performance of PLA samples was investigated by the proteolytic enzyme enzymatic digestion experiments and the changes of anaerobic fermentation gas production. The results showed that the lactic acid content in the supernatant of PLA samples irradiated by 60Co-γ ray increased slightly with the increase of absorbed dose in the range of 0~60 kGy. The molecular structure of the samples did not change significantly, but their crystallinity and molecular weight decreased significantly. The lactate concentration and mass loss of the irradiated samples increased significantly during the enzymatic digestion process compared to the unirradiated samples. Specifically, The PLA sample with an absorbed dose of 60 kGy reached its maximum lactate concentration on the 4th day, which was 17.4% higher than that of non irradiated samples. The mass loss increased over time, which was 68.7% higher than that of non irradiated samples on the 7th day. The irradiated samples took significantly less time to reach gas production equilibrium in anaerobic fermentation, and the total gas production increased by 3.0%. The results indicate that γ-ray irradiation has potential application as a pretreatment technology for PLA plastics, and this study can provide a theoretical reference for the resourceful disposal of PLA plastics.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040402 (2024)
  • Tianyi ZHANG, Pengfei YANG, Jufang WANG, and Heng ZHOU

    We investigated the effects of mitochondrial damage via carbon ion irradiation on the proliferation of human non-small cell lung cancer (A549) cells by monitoring mitochondrial morphological changes, mitochondrial membrane potential transformation, release of membrane-associated proteins, and mitophagy. A549 cell proliferation and activity were monitored by CCK-8 and colony formation assays. Changes in mitochondrial morphology and mitochondrial membrane potential were detected by mitochondrial membrane-specific fluorescence staining. Expression of associated proteins was detected by western blot and real-time quantitative PCR. Annexin V-FITC and PI staining were used to detect cell apoptosis. Mitophagy was detected by immunofluorescence co-localization and western blot. The apoptosis rate of mitochondria-lacking A549 cells after carbon ion irradiation was also quantitated. Irradiation with carbon ions at dose of 4 Gy significantly depressed the proliferation capacity of A549 cells, and induced mitochondrial shrinkage and decreased mitochondrial membrane potential. Levels of mitochondrial membrane protein Bax/Bak, and intermembrane proteins Cyto-C and SMAC were elevated, with increased apoptosis and mitophagy. In cells depleted of mitochondria, carbon ion irradiation exerted no significant effect on A549 cell apoptosis. Carbon ion irradiation can inhibit A549 cell proliferation. The half maximal inhibitory exposure dose is 4 Gy. Carbon ions lose their anti-proliferative function in mitochondria-free A549 cells. In summary, carbon ion irradiation can decrease mitochondrial membrane potential and induce the release of pro-apoptotic proteins, thereby inhibiting A549 cell proliferation.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040301 (2024)
  • Xuming CHEN, Yi LIU, Shengyu YAO, Bing XU, Zhekai HU, Zhiwei CHEN, Zijie WANG, Guoqi ZHAO, Tingfeng CHEN, Liping WAN, Xianmin SONG, Yi XU, and Yong LIU

    Total body irradiation (TBI) is a technique that irradiates the entire body of the patient. It serves as a conditioning regimen prior to hematopoietic stem cell transplantation for hematological diseases. Its primary functions include killing residual tumor cells, immunosuppression, and creating space in the bone marrow for hematopoietic stem cell transplantation. Currently, the main methods of implementing TBI include extended distance fixed field irradiation, volumetric modulated arc therapy (VMAT-TBI), and segmented irradiation. In this paper, based on our clinical experience, we review the technical characteristics and relevant research progress of these three methods.

    Aug. 20, 2024
  • Vol. 42 Issue 4 040101 (2024)
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