Studies on the Response of Orchid Roots to 2.4-dichlorophenoxyacetic Acid (2.4-d)

Studies were conducted to elucidate the nature of the response of orchid roots to 2, 4-dichlorophenoxyacatic acid [2, 4-D] by approaching it through morphological, anatomical, and fine-structural investigations. The roots of orchids [Dendrobium Lady Hay and Oendrobium J. Thomas] either attached to plantlets or excised from plants responded to 2,4-0 at 0.5-1.0 ppm level by forming tumorous growths at the tips. The sequence of tumor formation was observed under light and electron microscopes. During the first 3 days, root tips expanded radially and mitotis in meristematic area decreased drastically. Then, the enlarged cortical cells degenerated and the cortex collapsed. Although cells in the epidermis, root cap, and initial zones persisted longer than cortical cells, they too eventually degenerated. Mitotic cells at the periphery of the vascular cylinder replaced the cortical cells which degenerated and produced a population of new cells. After a prolonged lag period these cells started to proliferate at about 25 days after sub-culture in medium with 2, 4-D. The rapid division of these cells resulted in tumor growth. At the ultrastructural level, multivesicular bodies CMVB] and nucleoli were studied in relation to cell expansion growth and to RNA metabolism during the Formation of tumors. MVB appeared only after sub-culturing on 2, 4-D containing medium, MVB frequently became associated with the cell wall and deposited internal vesicles in the wall space. The possible relation of MVB to cell expansion is discussed. In the normal root tips, the area occupied by the granular region within the nucleolus and the degree of dispersion of granular components progressively increased within a vascular initial, dividing peripheral vascular cells, and elongating peripheral vascular cells. The surface intruded L-zone [lightly staining zone] of the nucleolus in the initial cells progressively moved into the nucleolus of the dividing and elongating cells. During the first few days of culture in 2, 4-D medium, the granular region in the nucleolus increased and the L-zone moved into the nucleolus. These changes may be due to increased RNA synthesis necessary for cell expansion. Dedifferentiating cells occasionally contained multiple nucleoli. This was related to the acceleration of nucleolar reorganization of cells in the lag phase with a very low demand for ribosomal RNA. Before the rapid cell proliferation phase, the granular region of the nucleolus increased rapidly. This was considered to be related to the increased production of ribosomal RNA which is a prerequisite for the rapid cell division in tumor formation

RiSi: Spectro-temporal RAN-agnostic Modulation Identification for OFDMA Signals

Blind modulation identification is essential for 6G's RAN-agnostic communications, which identifies the modulation type of an incompatible wireless signal without any prior knowledge. Nowadays, research on blind modulation identification relies on deep convolutional networks that deal with a received signal's raw I/Q samples, but they mostly are limited to single-carrier signal recognition thus not pragmatic for identifying spectro-temporal OFDM/OFDMA signals whose modulation varies with time and frequency. Therefore, this paper proposes RiSi, a semantic segmentation neural network designed to work on OFDMA's spectrograms, by replacing vanilla DeepLabV3+'s 2D convolutions with 'flattened' convolutions to enforce the time-frequency orthogonality constraint and to achieve the grid-like pattern of OFDMA's resource blocks, and by introducing three-channel inputs consisting of I/Q/amplitude. Then, we synthesized a realistic and effective dataset consisting of OFDMA signals with various channel impairments to train the proposed network. Moreover, we treated varying communication parameters as different domains to apply domain generalization methods, to enhance our model's adaptability to diverse communication environments. Extensive evaluation shows that RiSi's modulation identification accuracy reaches 86% averaged over four modulation types (BPSK, QPSK, 16-QAM, 64-QAM), while its domain generalization performance for unseen data has been also shown to be reliable.Comment: 10 pages, 10 figure

Electrostatic-induced assembly of graphene-encapsulated carbon@nickel-aluminum layered double hydroxide core-shell spheres hybrid structure for high-energy and high-power-density asymmetric supercapacitor

Achieving high energy density while retaining high power density is difficult in electrical double-layer capacitors and in pseudocapacitors considering the origin of different charge storage mechanisms. Rational structural design became an appealing strategy in circumventing these trade-offs between energy and power densities. A hybrid structure consists of chemically converted graphene-encapsulated carbon@nickel-aluminum layered double hydroxide core–shell spheres as spacers among graphene layers (G-CLS) used as an advanced electrode to achieve high energy density while retaining high power density for high-performance supercapacitors. The merits of the proposed architecture are as follows: (1) CLS act as spacers to avoid the close restacking of graphene; (2) highly conductive carbon sphere and graphene preserve the mechanical integrity and improve the electrical conductivity of LDHs hybrid. Thus, the proposed hybrid structure can simultaneously achieve high electrical double-layer capacitance and pseudocapacitance resulting in the overall highly active electrode. The G-CLS electrode exhibited high specific capacitance (1710.5 F g−1 at 1 A g−1) under three-electrode tests. An ASC fabricated using the G-CLS as positive electrode and reduced graphite oxide as negative electrode demonstrated remarkable electrochemical performance. The ASC device operated at 1.4 V, and delivered a high energy density of 35.5 Wh kg−1 at a 670.7 W kg−1 power density at 1 A g−1 with an excellent rate capability, as well as a robust long-term cycling stability of up to 10 000 cycles

User Recognition Based on Human Body Impulse Response: A Feasibility Study

Human recognition technologies for security systems require high reliability and easy accessibility in the advent of the internet of things (IoT). While several biometric approaches have been studied for user recognition, there are demands for more convenient techniques suitable for the IoT devices. Recently, electrical frequency responses of the human body have been unveiled as one of promising biometric signals, but the pilot studies are inconclusive about the characteristics of human body as a transmission medium for electric signals. This paper provides a multi-domain analysis of human body impulse responses (HBIR) measured at the receiver when customized impulse signals are passed through the human body. We analyzed the impulse responses in the time, frequency, and wavelet domains and extracted representative feature vectors using a proposed accumulated difference metric in each domain. The classification performance was tested using the k-nearest neighbors (KNN) algorithm and the support vector machine (SVM) algorithm on 10-day data acquired from five subjects. The average classification accuracies of the simple classifier KNN for the time, frequency, and wavelet features reached 92.99%, 77.01%, and 94.55%, respectively. In addition, the kernel-based SVM slightly improved the accuracies of three features by 0.58%, 2.34%, and 0.42%, respectively. The result shows potential of the proposed approach for user recognition based on HBIR

A novel approach to fabricate carbon-sphere-intercalated holey graphene electrode for high-energy-density electrochemical capacitors

Desirable porous structure and huge ion-accessible surface area are crucial for rapid electronic and ionic pathway electrodes in high-performance graphene-based electrochemical capacitors. However, graphene nanosheets tend to aggregate and restack because of van der Waals interaction among graphene sheets, resulting in the loss of ion-accessible surface area and unsatisfactory electrochemical performance. To resolve this daunting challenge, a novel approach is developed for the self-assembly of holey graphene sheets intercalated with carbon spheres (H-GCS) to obtain freestanding electrodes by using a simple vacuum filtration approach and a subsequent KOH activation process. Through the introduction of carbon spheres as spacers, the restacking of reduced graphene oxide (rGO) sheets during the filtration process is mitigated efficiently. Pores on rGO sheets produced by subsequent KOH activation also provide rapid ionic diffusion kinetics and high ion-accessible electrochemical surface area, both of which favor the formation of electric double-layer capacitance. Furthermore, a higher degree of graphitization of CSs in H-GCS thin film improves the electrical conductivity of the H-GCS electrode. The H-GCS electrode exhibits 207.1 F g−1 of specific capacitance at a current density of 1 A g−1 in 6 M KOH aqueous electrolyte. Moreover, the symmetric electrochemical capacitor assembled with H-GCS electrodes and organic electrolyte is capable of delivering a maximum energy density of 29.5 Wh kg−1 and a power density of 22.6 kW kg−1

Nicolau Syndrome after Intramuscular Injection: 3 Cases

Nicolau syndrome is a rare complication of intramuscular injection consisting of ischemic necrosis of skin, soft tissue, and muscular tissue that arises locoregionally. The characteristic pattern is pain around the injection site, developing into erythema, a livedoid dermatitis patch, and necrosis of the skin, subcutaneous fat, and muscle tissue. Three patients were injected with drugs (diclofenac sodium, ketoprofen, meperidine) for pain relief. Three patients complained of pain, and a skin lesion was observed, after which necrosis developed on their buttocks. Each patient underwent debridement and coverage. The wound healed uneventfully. We report three cases of Nicolau syndrome in the buttocks following diclofenac intramuscular injection

New Record of Sillago sinica (Pisces: Sillaginidae) in Korean Waters, and Re-identification of Sillago parvisquamis Previously Reported from Korea as S. sinica

A single specimen of the genus Sillago, collected from Gwangyang, Korea, in May 2009, is characterized by XI first dorsal fin spines, 3 or 4 rows of melanophore pattern along the second dorsal fin membrane, and a darkish posterior margin of the caudal fin. Our specimen was identified as Sillago sinica reported as a new species; this identification is confirmed by mitochondrial DNA cytochrome oxidase subunit I sequences, which show that our specimen corresponds to S. sinica (d=0.000) and differs from the congeneric species Sillago parvisquamis (d=0.170). Comparisons of Korean specimens previously reported as S. parvisquamis with specimens of S. sinica show that the S. parvisquamis specimens are actually S. sinica. We propose the new Korean name “buk-bang-jeom-bo-ri-myeol” for S. sinica