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Neural Computation Jan 2008We studied the dynamics of large networks of spiking neurons with conductance-based (nonlinear) synapses and compared them to networks with current-based (linear)... (Comparative Study)
Comparative Study
We studied the dynamics of large networks of spiking neurons with conductance-based (nonlinear) synapses and compared them to networks with current-based (linear) synapses. For systems with sparse and inhibition-dominated recurrent connectivity, weak external inputs induced asynchronous irregular firing at low rates. Membrane potentials fluctuated a few millivolts below threshold, and membrane conductances were increased by a factor 2 to 5 with respect to the resting state. This combination of parameters characterizes the ongoing spiking activity typically recorded in the cortex in vivo. Many aspects of the asynchronous irregular state in conductance-based networks could be sufficiently well characterized with a simple numerical mean field approach. In particular, it correctly predicted an intriguing property of conductance-based networks that does not appear to be shared by current-based models: they exhibit states of low-rate asynchronous irregular activity that persist for some period of time even in the absence of external inputs and without cortical pacemakers. Simulations of larger networks (up to 350,000 neurons) demonstrated that the survival time of self-sustained activity increases exponentially with network size.
Topics: Action Potentials; Animals; Cell Membrane; Cerebral Cortex; Computer Simulation; Cortical Synchronization; Excitatory Postsynaptic Potentials; Humans; Inhibitory Postsynaptic Potentials; Nerve Net; Neural Networks, Computer; Neural Pathways; Neurons; Nonlinear Dynamics; Synaptic Transmission; Time Factors
PubMed: 18044999
DOI: 10.1162/neco.2008.20.1.1 -
Angewandte Chemie (International Ed. in... Feb 2020The design of solid-state reference electrodes without a liquid junction is important to allow miniature and cost-effective electrochemical sensors. To address this, a...
The design of solid-state reference electrodes without a liquid junction is important to allow miniature and cost-effective electrochemical sensors. To address this, a pulse control is proposed using an Ag/AgI element as reliable solid-state reference electrode. It involves the local release of iodide by a cathodic current that is immediately followed by an electromotive force (EMF) measurement that serves as the reference potential. The recapture of iodide ions is achieved by potentiostatic control. This results in intermittent potential values that are reproducible to less than one millivolt (SD=0.27 mV, n=50). The ionic strength is shown to influence the activity coefficient of released iodide in accordance with the extended Debye-Hückel equation, resulting in a predictable change of the potential reading. The principle is applied to potentiometric potassium detection with a valinomycin-based ion-selective electrode (ISE), demonstrating a completely solid-state sensor configuration.
PubMed: 31714666
DOI: 10.1002/anie.201912651 -
Science Advances Oct 2023Ionic liquid-based ionogels emerge as promising candidates for efficient ionic thermoelectric conversion due to their quasi-solid state, giant thermopower, high...
Ionic liquid-based ionogels emerge as promising candidates for efficient ionic thermoelectric conversion due to their quasi-solid state, giant thermopower, high flexibility, and good stability. P-type ionogels have shown impressive performance; however, the development of n-type ionogels lags behind. Here, an n-type ionogel consisting of polyethylene oxide (PEO), lithium salt, and ionic liquid is developed. Strong coordination of lithium ion with ether oxygen and the anion-rich clusters generated by ion-preferential association promote rapid transport of the anions and boost Eastman entropy change, resulting in a huge negative ionic Seebeck coefficient (-15 millivolts per kelvin) and a high electrical conductivity (1.86 millisiemens per centimeter) at 50% relative humidity. Moreover, dynamic and reversible interactions among the ternary mixtures endow the ionogel with fast autonomous self-healing capability and green recyclability. All PEO-based ionic thermoelectric modules are fabricated, which exhibits outstanding thermal responses (-80 millivolts per kelvin for three p-n pairs), demonstrating great potential for low-grade energy harvesting and ultrasensitive thermal sensing.
PubMed: 37878706
DOI: 10.1126/sciadv.adk2098 -
ACS Applied Materials & Interfaces Dec 2022Moisture-activated electric generators (MEGs) that harvest clean energy from atmospheric humidity offer exciting opportunities for upgraded energy conversions. However,...
Moisture-activated electric generators (MEGs) that harvest clean energy from atmospheric humidity offer exciting opportunities for upgraded energy conversions. However, it is challenging to obtain MEGs that are both easy to fabricate and of high output power, due to the requirement for particular functional materials and the cumbersome manufacturing process. Herein, a simple and general method is adopted to prepare MEGs with chemically gradient structures. As a specific example, a gradient distribution of citric acid was successfully constructed inside an A4 printer paper by asymmetric drying, which can generate a continuous voltage of tens of millivolts by ambient humidity, and even to volts (275 mV and 7.6 μA cm) under asymmetric humidity stimulation, and the maximum power density output was 2.1 μW cm. The driving force behind this energy conversion is a self-maintained ionic gradient created within the paper by the asymmetric ionization of gradient organic acids when exposed to gradient or nongradient humid air. This work broadens the class of materials and possibilities for the rapid development of MEGs, shedding new light on the revolution of generators that harvest green and sustainable energy for power generation.
PubMed: 36437545
DOI: 10.1021/acsami.2c12777 -
Comparative Biochemistry and... Sep 2000This article deals with the silk weave produced by pupating larvae of the Oriental hornet and its electric properties. Larvae of this hornet commence pupation at... (Review)
Review
This article deals with the silk weave produced by pupating larvae of the Oriental hornet and its electric properties. Larvae of this hornet commence pupation at approximately 2 weeks of age. Creation of the cocoonal silk weave requires a number of hours and the encased pupa remains in the cocoon for approximately 2 more weeks before ecloding as an adult. The silk weave is initially of a creamish white color, but gradually becomes brown-gray owing to the activity of certain bacteria secreted in the silk. The silk weave is composed of fibers arranged in multiple layers with interposed surfaces occupying a considerable part of the area and containing pockets of bacteria. The spun silk contains both metallic and non-metallic elements, mostly K and Cl but also Mg, P, S, Ca, Ti and V. Shaped as a dome, the silk projects considerably beyond the cell proper, contributing importantly to its total volume and providing a shield for the contained pupa against predators, parasites, or extreme changes in temperature, as well as affording a 'sterile and clean room' in which the pupa can form its new cuticle without the interference of contaminating dust particles or the turbulence of air currents. The silk is endowed with electric properties. Inter alia, a thermoelectric phenomenon was observed in the dark, namely, upon increase in temperature the current rose to several hundred nano Amperes (nA); in light, a photovoltaic effect was observed involving voltages of several dozen millivolts (mV), with a sharp transition between the current and voltage during transition from darkness to light. Also recorded was a very high electric capacitance, amounting to scores of milli farads (mF). In all, the pupal silk behaves like an organic semiconductor, in that its electric properties are temperature-dependent, and it also displays ferroelectric properties. Additionally, a luminescence phenomenon was recorded on the silk, wherein excitation at wavelengths within the UV(i.e. 249, 290 and 312 nm) range yielded an emission spectrum at a wavelength of 450 and of 530 nm. The silk caps are anisotropic in that the emission from the outside is lower than that from the inside. By way of recap, the various mentioned properties of the pupal silk are discussed from their biological and physical aspects.
Topics: Animals; Electrophysiology; Insect Proteins; Larva; Photochemistry; Semiconductors; Silk; Temperature; Thermogenesis; Wasps
PubMed: 10996813
DOI: 10.1016/s1095-6433(00)00237-3 -
Sensors (Basel, Switzerland) Mar 2024The seafloor E-field signal is extremely weak and difficult to measured, even with a high signal-to-noise ratio. The preamplifier for electrodes is a key technology for...
The seafloor E-field signal is extremely weak and difficult to measured, even with a high signal-to-noise ratio. The preamplifier for electrodes is a key technology for ocean-bottom electromagnetic receivers. In this study, a chopper amplifier was proposed and developed to measure the seafloor E-field signal in the nanovolt to millivolt range at significantly low frequencies. It included a modulator, transformer, AC amplifier, high-impedance (hi-Z) module, demodulator, low-pass filter, and chopper clock generator. The injected charge in complementary metal-oxide semiconductor (CMOS) switches that form the modulator is the main source of 1/ noise. Combined with the principles of peak filtering and dead bands, a hi-Z module was designed to effectively reduce low-frequency noise. The chopper amplifier achieved an ultralow voltage noise of 0.6 nV/rt (Hz) at 1 Hz and 1.2 nV/rt (Hz) at 0.001 Hz. The corner frequency was less than 100 mHz, and there were few 1/ noises in the effective observation frequency band used for detecting electric fields. Each component is described with relevant tradeoffs that realize low noise in the low-frequency range. The amplifier was compact, measuring Ø 68 mm × H 12 mm, and had a low power consumption of approximately 23 mW (two channels). The fixed gain was 1500 with an input voltage range of 2.7 mV. The chopper amplifiers demonstrated stable performance in offshore geophysical prospecting applications.
PubMed: 38544183
DOI: 10.3390/s24061920 -
Nano Letters Sep 2018The complex neuronal circuitry connected by submicron synapses in our brain calls for technologies that can map neural networks with ultrahigh spatiotemporal resolution...
The complex neuronal circuitry connected by submicron synapses in our brain calls for technologies that can map neural networks with ultrahigh spatiotemporal resolution to decipher the underlying mechanisms for multiple aspects of neuroscience. Here we show that, through combining graphene transistor arrays with scanning photocurrent microscopy, we can detect the electrical activities of individual synapses of primary hippocampal neurons. Through measuring the local conductance change of graphene optoelectronic probes directly underneath neuronal processes, we are able to estimate millivolt extracellular potential variations of individual synapses during depolarization. The ultrafast nature of graphene photocurrent response allows for decoding of activity patterns of individual synapses with a sub-millisecond temporal resolution. This new neurotechnology provides promising potentials for recording of electrophysiological outcomes of individual synapses in neural networks.
Topics: Animals; Cells, Cultured; Coculture Techniques; Electrophysiological Phenomena; Equipment Design; Graphite; Hippocampus; Lab-On-A-Chip Devices; Microscopy, Fluorescence; Nerve Net; Neurons; Rats; Synapses; Transistors, Electronic
PubMed: 30063361
DOI: 10.1021/acs.nanolett.8b02298 -
Nano Letters Apr 2023Highly uniform quantum systems are essential for the practical implementation of scalable quantum processors. While quantum dot spin qubits based on semiconductor...
Highly uniform quantum systems are essential for the practical implementation of scalable quantum processors. While quantum dot spin qubits based on semiconductor technology are a promising platform for large-scale quantum computing, their small size makes them particularly sensitive to their local environment. Here, we present a method to electrically obtain a high degree of uniformity in the intrinsic potential landscape using hysteretic shifts of the gate voltage characteristics. We demonstrate the tuning of pinch-off voltages in quantum dot devices over hundreds of millivolts that then remain stable at least for hours. Applying our method, we homogenize the pinch-off voltages of the plunger gates in a linear array for four quantum dots, reducing the spread in pinch-off voltages by one order of magnitude. This work provides a new tool for the tuning of quantum dot devices and offers new perspectives for the implementation of scalable spin qubit arrays.
PubMed: 36975126
DOI: 10.1021/acs.nanolett.2c04446 -
Giant negative thermopower of ionic hydrogel by synergistic coordination and hydration interactions.Science Advances Nov 2021The design of ultrasensitive ionic thermopiles is important for low-grade heat collection and temperature sensing. However, high-quality ionic thermoelectric materials...
The design of ultrasensitive ionic thermopiles is important for low-grade heat collection and temperature sensing. However, high-quality ionic thermoelectric materials with negative thermopower have been rarely reported to date. Effective adjustment of the interaction between the polymer network and the electrolyte anion/cation is an important method to achieve notable thermopower. Here, we demonstrate an ionic hydrogel thermoelectric material with giant negative thermopower obtained by synergistic coordination and hydration interactions. The ionic hydrogel, made of polyvinyl alcohol and sodium hydroxide, is prepared by simple dry-annealed process and exhibits a thermopower of up to −37.61 millivolts per kelvin, an extremely high absolute thermopower for electronic and ionic conductors. This ionic hydrogel is promising for the design of high-thermopower ionic thermoelectric materials and the low-grade heat energy harvesting.
PubMed: 34818039
DOI: 10.1126/sciadv.abi7233 -
Science Advances Sep 2021The biophysical characteristics of the extracellular matrix (ECM), such as a three-dimensional (3D) network and bioelectricity, have a profound influence on cell...
The biophysical characteristics of the extracellular matrix (ECM), such as a three-dimensional (3D) network and bioelectricity, have a profound influence on cell development, migration, function expression, etc. Here, inspired by these biophysical cues of ECM, we develop an electromechanical coupling bio-nanogenerator (bio-NG) composed of highly discrete piezoelectric fibers. It can generate surface piezopotential up to millivolts by cell inherent force and thus provide in situ electrical stimulation for the living cells. Besides, the unique 3D space in the bio-NGs provides an ECM-like growth microenvironment for cells. As a result, our bio-NGs effectively promote cell viability and development and, more importantly, maintain its specific functional expression. These advanced in vitro bio-NGs are expected to fill the gap between the inaccurate 2D systems and the expensive and time-consuming animal models, mimicking the complexity of the ECM and the physiological relevance of an in vivo biological system.
PubMed: 34559554
DOI: 10.1126/sciadv.abh2350