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electronalytics · 1 year ago
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Step-down Transformer Market Report Includes Dynamics, Products, and Application, Value, Size, Share 2017 – 2032
Step-down transformers are electrical devices used to lower the voltage levels of electrical power for various applications, and the step-down transformer market refers to the sector of the economy that produces and supplies step-down transformers.
From 2017 to 2030, the size of the global step-down transformer market is anticipated to increase at a CAGR of 5.1%.
Market Overview:
A sizable portion of the worldwide power transformer market is the step-down transformer market.It serves a broad range of industries, including the production, transmission, and distribution of electricity as well as the commercial, residential, and industrial sectors.Step-down transformer production and maintenance are performed by manufacturers, suppliers, distributors, and service providers in the market.
Increasing Power Demand:
The market for step-down transformers is primarily driven by the rising global demand for power.
Increased power consumption is a result of rapid urbanisation, industry, and infrastructural expansion, which calls for the use of step-down transformers.
Renewable Energy Integration:
Step-down transformers are necessary for the grid integration of renewable energy sources, such as solar and wind power, in order to reduce the generated electricity's voltage to grid-acceptable levels.
Grid Modernization Initiatives:
To increase effectiveness and dependability, many nations are putting their attention on modernising their electricity infrastructures.
Step-down transformer replacement or installation is a common component of grid modernization projects, which is fueling market expansion.
Industrial Growth:
Step-down transformers are necessary for the activities of the industrial sector, which includes manufacturing, oil and gas, mining, and other industries.
The need for step-down transformers is fueled by industrial expansion, particularly in emerging economies.
Smart Grid Development:
The creation of sophisticated step-down transformers with monitoring and control features is necessary for the development of smart grids, which allow for two-way communication and effective energy management.
Aging Grid Infrastructure:
The infrastructure of many nations' electricity grids needs to be modernised or rebuilt.
As obsolete, less efficient transformers are replaced, this opens up chances for the step-down transformer market.
Energy Efficiency Regulations:
Governments and environmental organisations' strict energy efficiency laws force the use of energy-efficient step-down transformers, which fosters market expansion.
Technological Advancements:
Step-down transformers are becoming smaller, more effective, and more dependable because to developments in transformer design, materials, and manufacturing techniques.
Market demand is increasing for innovations like digital monitoring systems and solid-state transformers.
These factors collectively contribute to the growth and demand for step-down transformers in various sectors. The market is expected to expand further as the need for electricity continues to rise, renewable energy integration expands, and infrastructure development projects increase worldwide.
Trends:
1. Growing Demand for Energy-Efficient Solutions: The demand for energy-efficient solutions is growing in the step-down transformer market. There is an increasing need for transformers that can effectively step down high voltage electricity to lower voltages for diverse applications due to a focus on lowering energy consumption and carbon emissions. To satisfy these demands, manufacturers are creating transformers with higher efficiency ratings.
2. Integration of Smart Technologies: The market for step-down transformers is experiencing a major trend towards the integration of smart technologies. A growing number of people are interested in smart transformers that have sophisticated monitoring and control capabilities. These transformers improve the overall effectiveness and dependability of power distribution networks by enabling real-time monitoring, remote control, and diagnostics. Integration of the smart grid is made easier by the use of modern communication systems and the Internet of Things (IoT).
3. Expanding Renewable Energy Sector: The need for step-down transformers is being driven by the rapidly growing renewable energy sector. Higher voltage electricity produced by renewable energy sources like solar and wind must be scaled down before delivery. Step-down transformers are increasingly being used in solar and wind farms in order to enable effective power transmission to the grid as nations throughout the world prioritise the development of renewable energy.
4. Infrastructure Development and Industrialization: Step-down transformer demand is being fueled by infrastructure development and industrialization initiatives in emerging economies. For power transmission and distribution networks in a variety of industries, including manufacturing, construction, and mining, these transformers are crucial. Step-down transformers are anticipated to be required for infrastructure projects because to the ongoing rise of urbanisation and industrial activity.
5. Focus on Grid Modernization and Power Quality: To improve power quality and dependability, many nations are investing in grid modernization projects. Step-down transformers are essential to this procedure because they ensure efficient power distribution and maintain ideal voltage levels. There is a rising focus on updating and replacing outdated transformers with modern, more efficient versions as utilities work to increase grid efficiency, decrease losses, and minimise downtime.
Here are some of the key benefits for stakeholders:
Voltage Regulation and Power Distribution
Electrical Safety and Equipment Protection
Energy Efficiency and Cost Savings
Facilitation of Renewable Energy Integration
Industrial Applications
Transmission Line Optimization
Backup Power and Emergency Preparedness
Flexibility and Customization
Smart Grid Integration
Environment-Friendly Solutions
We recommend referring our Stringent datalytics firm, industry publications, and websites that specialize in providing market reports. These sources often offer comprehensive analysis, market trends, growth forecasts, competitive landscape, and other valuable insights into this market.
By visiting our website or contacting us directly, you can explore the availability of specific reports related to this market. These reports often require a purchase or subscription, but we provide comprehensive and in-depth information that can be valuable for businesses, investors, and individuals interested in this market.
“Remember to look for recent reports to ensure you have the most current and relevant information.”
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Market Segmentations:
Global Step-down Transformer Market: By Company
• Technova Control System
• ADM Instrument Engineering
• Wilson Power Solutions
• Tesla Industries
• Procon Controls
• Schneider Electric
• ABB
• SHANGHAI MIN WEN ELECTRIC
• Shanghai YingShiDan Electrical Manufacturing
• Shanghai Huilou Electrical Equipment
Global Step-down Transformer Market: By Type
• 24V
• 36V
• 110V
• 220V
• Others
Global Step-down Transformer Market: By Application
• Industrial Equipment
• Home Appliance
• Consumer Electronic
• Others
Global Step-down Transformer Market: Regional Analysis
The regional analysis of the global Step-down Transformer market provides insights into the market's performance across different regions of the world. The analysis is based on recent and future trends and includes market forecast for the prediction period. The countries covered in the regional analysis of the Step-down Transformer market report are as follows:
North America: The North America region includes the U.S., Canada, and Mexico. The U.S. is the largest market for Step-down Transformer in this region, followed by Canada and Mexico. The market growth in this region is primarily driven by the presence of key market players and the increasing demand for the product.
Europe: The Europe region includes Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe. Germany is the largest market for Step-down Transformer in this region, followed by the U.K. and France. The market growth in this region is driven by the increasing demand for the product in the automotive and aerospace sectors.
Asia-Pacific: The Asia-Pacific region includes Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, and Rest of Asia-Pacific. China is the largest market for Step-down Transformer in this region, followed by Japan and India. The market growth in this region is driven by the increasing adoption of the product in various end-use industries, such as automotive, aerospace, and construction.
Middle East and Africa: The Middle East and Africa region includes Saudi Arabia, U.A.E, South Africa, Egypt, Israel, and Rest of Middle East and Africa. The market growth in this region is driven by the increasing demand for the product in the aerospace and defense sectors.
South America: The South America region includes Argentina, Brazil, and Rest of South America. Brazil is the largest market for Step-down Transformer in this region, followed by Argentina. The market growth in this region is primarily driven by the increasing demand for the product in the automotive sector.
Visit Report Page for More Details: https://stringentdatalytics.com/reports/step-down-transformer-market/10433/
Reasons to Purchase Step-down Transformer Market Report:
• To obtain insights into industry trends and dynamics, including market size, growth rates, and important factors and difficulties. This study offers insightful information on these topics.
• To identify important participants and rivals: This research studies can assist companies in identifying key participants and rivals in their sector, along with their market share, business plans, and strengths and weaknesses.
• To comprehend consumer behaviour: these research studies can offer insightful information about customer behaviour, including preferences, spending patterns, and demographics.
• To assess market opportunities: These research studies can aid companies in assessing market chances, such as prospective new goods or services, fresh markets, and new trends.
• To make well-informed business decisions: These research reports give companies data-driven insights that they may use to plan their strategy, develop new products, and devise marketing and advertising plans.
In general, market research studies offer companies and organisations useful data that can aid in making decisions and maintaining competitiveness in their industry. They can offer a strong basis for decision-making, strategy formulation, and company planning.
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sonicsquid3000 · 3 months ago
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You know, now that I think about it…
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Is anyone else able to access the “past events” tab? Or were the developers like “sike, we’re never going to use this feature at all. Good luck missing out on all your favorite consorts.” I genuinely don’t know this cause, for the longest, I didn’t have a community to confirm this or not.
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chirp-a-chirp · 3 hours ago
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Turn that frown upside down Guy and MAYBE your face will match your emotions…*
*Also, this will be my face trying to smile while navigating awkward Thanksgiving conversations
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acefaun · 2 years ago
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Me, playing an otome game: I must be the center of attention, all eyes must be on me, all arguments must be about me. If I'm not present, everyone must pray for my swift return as if I stole your left lung or something equally vital to your survival. The entire nation must know of my presence—Nay, the WORLD must know of me and my accomplishments!
Me, in real life: Don't stare at me, don't touch me, don't breath on me, don't think about me, don't utter my name, don't come near my space bubble. I'm a figment of your imagination, you can't know something that doesn't exist.
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periphrasis · 2 years ago
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ultrimio · 6 months ago
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Conceptual Design for a Neutrino Power Transmission System
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Overview
Neutrinos could potentially be used to send electricity over long distances without the need for high-voltage direct current (HVDC) lines. Neutrinos have the unique property of being able to pass through matter without interacting with it, which makes them ideal for transmitting energy over long distances without significant energy loss. This property allows neutrinos to be used as a medium for energy transmission, potentially replacing HVDC lines in certain applications.
So the goal is to create a neutrino-based power transmission system capable of sending and receiving a beam of neutrinos that carry a few MW of power across a short distance. This setup will include a neutrino beam generator (transmitter), a travel medium, and a neutrino detector (receiver) that can convert the neutrinos' kinetic energy into electrical power.
1. Neutrino Beam Generator (Transmitter)
Particle Accelerator: At the heart of the neutrino beam generator will be a particle accelerator. This accelerator will increase the energy of protons before colliding them with a target to produce pions and kaons, which then decay into neutrinos. A compact linear accelerator or a small synchrotron could be used for this purpose.
Target Material: The protons accelerated by the particle accelerator will strike a dense material target (like tungsten or graphite) to create a shower of pions and kaons.
Decay Tunnel: After production, these particles will travel through a decay tunnel where they decay into neutrinos. This tunnel needs to be under vacuum or filled with inert gas to minimize interactions before decay.
Focusing Horns: Magnetic horns will be used to focus the charged pions and kaons before they decay, enhancing the neutrino beam's intensity and directionality.
Energy and Beam Intensity: To achieve a few MW of power, the system will need to operate at several gigaelectronvolts (GeV) with a proton beam current of a few tens of milliamperes.
2. Travel Medium
Direct Line of Sight: Neutrinos can travel through the Earth with negligible absorption or scattering, but for initial tests, a direct line of sight through air or vacuum could be used to simplify detection.
Distance: The initial setup could span a distance from a few hundred meters to a few kilometers, allowing for measurable neutrino interactions without requiring excessively large infrastructure.
3. Neutrino Detector (Receiver)
Detector Medium: A large volume of water or liquid scintillator will be used as the detecting medium. Neutrinos interacting with the medium produce a charged particle that can then be detected via Cherenkov radiation or scintillation light.
Photodetectors: Photomultiplier tubes (PMTs) or Silicon Photomultipliers (SiPMs) will be arranged around the detector medium to capture the light signals generated by neutrino interactions.
Energy Conversion: The kinetic energy of particles produced in neutrino interactions will be converted into heat. This heat can then be used in a traditional heat-to-electricity conversion system (like a steam turbine or thermoelectric generators).
Shielding and Background Reduction: To improve the signal-to-noise ratio, the detector will be shielded with lead or water to reduce background radiation. A veto system may also be employed to distinguish neutrino events from other particle interactions.
4. Control and Data Acquisition
Synchronization: Precise timing and synchronization between the accelerator and the detector will be crucial to identify and correlate neutrino events.
Data Acquisition System: A high-speed data acquisition system will collect data from the photodetectors, processing and recording the timing and energy of detected events.
Hypothetical Power Calculation
To estimate the power that could be transmitted:
Neutrino Flux: Let the number of neutrinos per second be ( N_\nu ), and each neutrino carries an average energy ( E_\nu ).
Neutrino Interaction Rate: Only a tiny fraction (( \sigma )) of neutrinos will interact with the detector material. For a detector with ( N_d ) target nuclei, the interaction rate ( R ) is ( R = N_\nu \sigma N_d ).
Power Conversion: If each interaction deposits energy ( E_d ) into the detector, the power ( P ) is ( P = R \times E_d ).
For a beam of ( 10^{15} ) neutrinos per second (a feasible rate for a small accelerator) each with ( E_\nu = 1 ) GeV, and assuming an interaction cross-section ( \sigma \approx 10^{-38} ) cm(^2), a detector with ( N_d = 10^{30} ) (corresponding to about 10 kilotons of water), and ( E_d = E_\nu ) (for simplicity in this hypothetical scenario), the power is:
[ P = 10
^{15} \times 10^{-38} \times 10^{30} \times 1 \text{ GeV} ]
[ P = 10^{7} \times 1 \text{ GeV} ]
Converting GeV to joules (1 GeV ≈ (1.6 \times 10^{-10}) J):
[ P = 10^{7} \times 1.6 \times 10^{-10} \text{ J/s} ]
[ P = 1.6 \text{ MW} ]
Thus, under these very optimistic and idealized conditions, the setup could theoretically transmit about 1.6 MW of power. However, this is an idealized maximum, and actual performance would likely be significantly lower due to various inefficiencies and losses.
Detailed Steps to Implement the Conceptual Design
Step 1: Building the Neutrino Beam Generator
Accelerator Design:
Choose a compact linear accelerator or a small synchrotron capable of accelerating protons to the required energy (several GeV).
Design the beamline with the necessary magnetic optics to focus and direct the proton beam.
Target Station:
Construct a target station with a high-density tungsten or graphite target to maximize pion and kaon production.
Implement a cooling system to manage the heat generated by the high-intensity proton beam.
Decay Tunnel:
Design and construct a decay tunnel, optimizing its length to maximize the decay of pions and kaons into neutrinos.
Include magnetic focusing horns to shape and direct the emerging neutrino beam.
Safety and Controls:
Develop a control system to synchronize the operation of the accelerator and monitor the beam's properties.
Implement safety systems to manage radiation and operational risks.
Step 2: Setting Up the Neutrino Detector
Detector Medium:
Select a large volume of water or liquid scintillator. For a few MW of transmitted power, consider a detector size of around 10 kilotons, similar to large neutrino detectors in current experiments.
Place the detector underground or in a well-shielded facility to reduce cosmic ray backgrounds.
Photodetectors:
Install thousands of photomultiplier tubes (PMTs) or Silicon Photomultipliers (SiPMs) around the detector to capture light from neutrino interactions.
Optimize the arrangement of these sensors to maximize coverage and detection efficiency.
Energy Conversion System:
Design a system to convert the kinetic energy from particle reactions into heat.
Couple this heat to a heat exchanger and use it to drive a turbine or other electricity-generating device.
Data Acquisition and Processing:
Implement a high-speed data acquisition system to record signals from the photodetectors.
Develop software to analyze the timing and energy of events, distinguishing neutrino interactions from background noise.
Step 3: Integration and Testing
Integration:
Carefully align the neutrino beam generator with the detector over the chosen distance.
Test the proton beam operation, target interaction, and neutrino production phases individually before full operation.
Calibration:
Use calibration sources and possibly a low-intensity neutrino source to calibrate the detector.
Adjust the photodetector and data acquisition settings to optimize signal detection and reduce noise.
Full System Test:
Begin with low-intensity beams to ensure the system's stability and operational safety.
Gradually increase the beam intensity, monitoring the detector's response and the power output.
Operational Refinement:
Refine the beam focusing and detector sensitivity based on initial tests.
Implement iterative improvements to increase the system's efficiency and power output.
Challenges and Feasibility
While the theoretical framework suggests that a few MW of power could be transmitted via neutrinos, several significant challenges would need to be addressed to make such a system feasible:
Interaction Rates: The extremely low interaction rate of neutrinos means that even with a high-intensity beam and a large detector, only a tiny fraction of the neutrinos will be detected and contribute to power generation.
Technological Limits: The current state of particle accelerator and neutrino detection technology would make it difficult to achieve the necessary beam intensity and detection efficiency required for MW-level power transmission.
Cost and Infrastructure: The cost of building and operating such a system would be enormous, likely many orders of magnitude greater than existing power transmission systems.
Efficiency: Converting the kinetic energy of particles produced in neutrino interactions to electrical energy with high efficiency is a significant technical challenge.
Scalability: Scaling this setup to practical applications would require even more significant advancements in technology and reductions
in cost.
Detailed Analysis of Efficiency and Cost
Even in an ideal scenario where technological barriers are overcome, the efficiency of converting neutrino interactions into usable power is a critical factor. Here’s a deeper look into the efficiency and cost aspects:
Efficiency Analysis
Neutrino Detection Efficiency: Current neutrino detectors have very low efficiency due to the small cross-section of neutrino interactions. To improve this, advanced materials or innovative detection techniques would be required. For instance, using superfluid helium or advanced photodetectors could potentially increase interaction rates and energy conversion efficiency.
Energy Conversion Efficiency: The process of converting the kinetic energy from particle reactions into usable electrical energy currently has many stages of loss. Thermal systems, like steam turbines, typically have efficiencies of 30-40%. To enhance this, direct energy conversion methods, such as thermoelectric generators or direct kinetic-to-electric conversion, need development but are still far from achieving high efficiency at the scale required.
Overall System Efficiency: Combining the neutrino interaction efficiency and the energy conversion efficiency, the overall system efficiency could be extremely low. For neutrino power transmission to be comparable to current technologies, these efficiencies need to be boosted by several orders of magnitude.
Cost Considerations
Capital Costs: The initial costs include building the particle accelerator, target station, decay tunnel, focusing system, and the neutrino detector. Each of these components is expensive, with costs potentially running into billions of dollars for a setup that could aim to transmit a few MW of power.
Operational Costs: The operational costs include the energy to run the accelerator and the maintenance of the entire system. Given the high-energy particles involved and the precision technology required, these costs would be significantly higher than those for traditional power transmission methods.
Cost-Effectiveness: To determine the cost-effectiveness, compare the total cost per unit of power transmitted with that of HVDC systems. Currently, HVDC transmission costs are about $1-2 million per mile for the infrastructure, plus additional costs for power losses over distance. In contrast, a neutrino-based system would have negligible losses over distance, but the infrastructure costs would dwarf any current system.
Potential Improvements and Research Directions
To move from a theoretical concept to a more practical proposition, several areas of research and development could be pursued:
Advanced Materials: Research into new materials with higher sensitivity to neutrino interactions could improve detection rates. Nanomaterials or quantum dots might offer new pathways to detect and harness the energy from neutrino interactions more efficiently.
Accelerator Technology: Developing more compact and efficient accelerators would reduce the initial and operational costs of generating high-intensity neutrino beams. Using new acceleration techniques, such as plasma wakefield acceleration, could significantly decrease the size and cost of accelerators.
Detector Technology: Improvements in photodetector efficiency and the development of new scintillating materials could enhance the signal-to-noise ratio in neutrino detectors. High-temperature superconductors could also be used to improve the efficiency of magnetic horns and focusing devices.
Energy Conversion Methods: Exploring direct conversion methods, where the kinetic energy of particles from neutrino interactions is directly converted into electricity, could bypass the inefficiencies of thermal conversion systems. Research into piezoelectric materials or other direct conversion technologies could be key.
Conceptual Experiment to Demonstrate Viability
To demonstrate the viability of neutrino power transmission, even at a very small scale, a conceptual experiment could be set up as follows:
Experimental Setup
Small-Scale Accelerator: Use a small-scale proton accelerator to generate a neutrino beam. For experimental purposes, this could be a linear accelerator used in many research labs, capable of accelerating protons to a few hundred MeV.
Miniature Target and Decay Tunnel: Design a compact target and a short decay tunnel to produce and focus neutrinos. This setup will test the beam production and initial focusing systems.
Small Detector: Construct a small-scale neutrino detector, possibly using a few tons of liquid scintillator or water, equipped with sensitive photodetectors. This detector will test the feasibility of detecting focused neutrino beams at short distances.
Measurement and Analysis: Measure the rate of neutrino interactions and the energy deposited in the detector. Compare this to the expected values based on the beam properties and detector design.
Steps to Conduct the Experiment
Calibrate the Accelerator and Beamline: Ensure the proton beam is correctly tuned and the target is accurately positioned to maximize pion and kaon production.
Operate the Decay Tunnel and Focusing System: Run tests to optimize the magnetic focusing horns and maximize the neutrino beam coherence.
Run the Detector: Collect data from the neutrino interactions, focusing on capturing the rare events and distinguishing them from background noise.
Data Analysis: Analyze the collected data to determine the neutrino flux and interaction rate, and compare these to
theoretical predictions to validate the setup.
Optimization: Based on initial results, adjust the beam energy, focusing systems, and detector configurations to improve interaction rates and signal clarity.
Example Calculation for a Proof-of-Concept Experiment
To put the above experimental setup into a more quantitative framework, here's a simplified example calculation:
Assumptions and Parameters
Proton Beam Energy: 500 MeV (which is within the capability of many smaller particle accelerators).
Number of Protons per Second ((N_p)): (1 \times 10^{13}) protons/second (a relatively low intensity to ensure safe operations for a proof-of-concept).
Target Efficiency: Assume 20% of the protons produce pions or kaons that decay into neutrinos.
Neutrino Energy ((E_\nu)): Approximately 30% of the pion or kaon energy, so around 150 MeV per neutrino.
Distance to Detector ((D)): 100 meters (to stay within a compact experimental facility).
Detector Mass: 10 tons of water (equivalent to (10^4) kg, or about (6 \times 10^{31}) protons assuming 2 protons per water molecule).
Neutrino Interaction Cross-Section ((\sigma)): Approximately (10^{-38} , \text{m}^2) (typical for neutrinos at this energy).
Neutrino Detection Efficiency: Assume 50% due to detector design and quantum efficiency of photodetectors.
Neutrino Production
Pions/Kaons Produced: [ N_{\text{pions/kaons}} = N_p \times 0.2 = 2 \times 10^{12} \text{ per second} ]
Neutrinos Produced: [ N_\nu = N_{\text{pions/kaons}} = 2 \times 10^{12} \text{ neutrinos per second} ]
Neutrino Flux at the Detector
Given the neutrinos spread out over a sphere: [ \text{Flux} = \frac{N_\nu}{4 \pi D^2} = \frac{2 \times 10^{12}}{4 \pi (100)^2} , \text{neutrinos/m}^2/\text{s} ] [ \text{Flux} \approx 1.6 \times 10^7 , \text{neutrinos/m}^2/\text{s} ]
Expected Interaction Rate in the Detector
Number of Target Nuclei ((N_t)) in the detector: [ N_t = 6 \times 10^{31} ]
Interactions per Second: [ R = \text{Flux} \times N_t \times \sigma \times \text{Efficiency} ] [ R = 1.6 \times 10^7 \times 6 \times 10^{31} \times 10^{-38} \times 0.5 ] [ R \approx 48 , \text{interactions/second} ]
Energy Deposited
Energy per Interaction: Assuming each neutrino interaction deposits roughly its full energy (150 MeV, or (150 \times 1.6 \times 10^{-13}) J): [ E_d = 150 \times 1.6 \times 10^{-13} , \text{J} = 2.4 \times 10^{-11} , \text{J} ]
Total Power: [ P = R \times E_d ] [ P = 48 \times 2.4 \times 10^{-11} , \text{J/s} ] [ P \approx 1.15 \times 10^{-9} , \text{W} ]
So, the power deposited in the detector from neutrino interactions would be about (1.15 \times 10^{-9}) watts.
Challenges and Improvements for Scaling Up
While the proof-of-concept might demonstrate the fundamental principles, scaling this up to transmit even a single watt of power, let alone megawatts, highlights the significant challenges:
Increased Beam Intensity: To increase the power output, the intensity of the proton beam and the efficiency of pion/kaon production must be dramatically increased. For high power levels, this would require a much higher energy and intensity accelerator, larger and more efficient targets, and more sophisticated focusing systems.
Larger Detector: The detector would need to be massively scaled
up in size. To detect enough neutrinos to convert to a practical amount of power, we're talking about scaling from a 10-ton detector to potentially tens of thousands of tons or more, similar to the scale of detectors used in major neutrino experiments like Super-Kamiokande in Japan.
Improved Detection and Conversion Efficiency: To realistically convert the interactions into usable power, the efficiency of both the detection and the subsequent energy conversion process needs to be near-perfect, which is far beyond current capabilities.
Steps to Scale Up the Experiment
To transition from the initial proof-of-concept to a more substantial demonstration and eventually to a practical application, several steps and advancements are necessary:
Enhanced Accelerator Performance:
Upgrade to Higher Energies: Move from a 500 MeV system to several GeV or even higher, as higher energy neutrinos can penetrate further and have a higher probability of interaction.
Increase Beam Current: Amplify the proton beam current to increase the number of neutrinos generated, aiming for a beam power in the range of hundreds of megawatts to gigawatts.
Optimized Target and Decay Tunnel:
Target Material and Design: Use advanced materials that can withstand the intense bombardment of protons and optimize the geometry for maximum pion and kaon production.
Magnetic Focusing: Refine the magnetic horns and other focusing devices to maximize the collimation and directionality of the produced neutrinos, minimizing spread and loss.
Massive Scale Detector:
Detector Volume: Scale the detector up to the kiloton or even megaton range, using water, liquid scintillator, or other materials that provide a large number of target nuclei.
Advanced Photodetectors: Deploy tens of thousands of high-efficiency photodetectors to capture as much of the light from interactions as possible.
High-Efficiency Energy Conversion:
Direct Conversion Technologies: Research and develop technologies that can convert the kinetic energy from particle reactions directly into electrical energy with minimal loss.
Thermodynamic Cycles: If using heat conversion, optimize the thermodynamic cycle (such as using supercritical CO2 turbines) to maximize the efficiency of converting heat into electricity.
Integration and Synchronization:
Data Acquisition and Processing: Handle the vast amounts of data from the detector with real-time processing to identify and quantify neutrino events.
Synchronization: Ensure precise timing between the neutrino production at the accelerator and the detection events to accurately attribute interactions to the beam.
Realistic Projections and Innovations Required
Considering the stark difference between the power levels in the initial experiment and the target power levels, let's outline the innovations and breakthroughs needed:
Neutrino Production and Beam Focus: To transmit appreciable power via neutrinos, the beam must be incredibly intense and well-focused. Innovations might include using plasma wakefield acceleration for more compact accelerators or novel superconducting materials for more efficient and powerful magnetic focusing.
Cross-Section Enhancement: While we can't change the fundamental cross-section of neutrino interactions, we can increase the effective cross-section by using quantum resonance effects or other advanced physics concepts currently in theoretical stages.
Breakthrough in Detection: Moving beyond conventional photodetection, using quantum coherent technologies or metamaterials could enhance the interaction rate detectable by the system.
Scalable and Safe Operation: As the system scales, ensuring safety and managing the high-energy particles and radiation produced will require advanced shielding and remote handling technologies.
Example of a Scaled Concept
To visualize what a scaled-up neutrino power transmission system might look like, consider the following:
Accelerator: A 10 GeV proton accelerator, with a beam power of 1 GW, producing a focused neutrino beam through a 1 km decay tunnel.
Neutrino Beam: A beam with a diameter of around 10 meters at production, focused down to a few meters at the detector site several kilometers away.
Detector: A 100 kiloton water Cherenkov or liquid scintillator detector, buried deep underground to minimize cosmic ray backgrounds, equipped with around 100,000 high-efficiency photodetectors.
Power Output: Assuming we could improve the overall system efficiency to even 0.1% (a huge leap from current capabilities), the output power could be: [ P_{\text{output}} = 1\text{ GW} \times 0.001 = 1\text{ MW} ]
This setup, while still futuristic, illustrates the scale and type of development needed to make neutrino power transmission a feasible alternative to current technologies.
Conclusion
While the concept of using neutrinos to transmit power is fascinating and could overcome many limitations of current power transmission infrastructure, the path from theory to practical application is long and filled with significant hurdels.
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spookythesillyfella · 2 months ago
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WOWOWOW ?????? WOWOWOWOWOWOWOWOW !!!!!!!!
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User spooks has been far too nice now I get to draw our guys
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Nyeheheheheehhe
[HV Colin and Tracey belong to @spookythesillyfella ]
#colin n hv colin must be having the most fascinating of conversations#“sooo .... does your tony also have a plethora of mental health issues that he refuses to communicate with to anyone ?? is he feral too ??”#“i mean . i wouldn't call it THAT . per se – but i think he fits that feral part pretty well !”#“ah cool . cool ... does he like bite and stuff ?”#“you're asking me if he bites. like a dog would ?”#“no !! no !! not like a dog !! y'know like in a uh romantic fashion ??”#“In a What.”#“what ? did you hear something ?”#or maybe about sketch#“hey so does your sketchbook also have that soulless . empty stare that he deploys when he's mad or is he like normal ???”#“sketch is far from normal . but what you describe has never happened before !!”#“great ... least you never have to wake up in the middle of the night and almost die cause you saw an eerie figure staring at you ...”#“ahahh ..... weeeelll ....”#tracey nd hv tracey also . theyre gonna be best friends forever like immediately#“we should kill them” yes tracies .we all cheer in unison#i honestly think they'd either create an entirely new universe . or they'll end one :)#odd reblogs#dhmis#dhmis art#dhmis au#high voltage au#dhmis colin#colin the computer#dhmis hv colin#dhmis electracey#electracey the meter#dhmis hv electracey#im keeping this in my box labeled SAFE KEEPING#jummy i love you so much you deserve the world whatever you ask from me . even if it would be my heart on a platter . you shall receive ☺️#★ my trinket box ★
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kossups · 1 year ago
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Safeguard Your Electronics with a Robust Battery Backup System
In a digital age where we're dependent on electronic devices for work and leisure, unexpected power disruptions can be a real buzzkill. But fear not! The answer to your power-related worries lies in one powerful solution: the battery backup system. In this article, we'll delve into the world of battery backup systems and highlight why they are a must-have for anyone seeking uninterrupted power.
The Power of Battery Backup Systems: Imagine you're in the middle of an important video call or finalizing an important document when suddenly, darkness envelops your room. Enter the superhero of electronics – the battery backup system. This ingenious device steps in immediately during power outages, ensuring your devices stay online and operational.
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Exploring Different Types of Battery Backup Systems: When it comes to safeguarding your electronics, not all battery backup systems are created equal. There are three primary types:
Offline/Standby Systems: Basic yet effective, they're perfect for safeguarding home devices like computers and entertainment systems.
Line-Interactive Systems: A notch up in protection, these systems offer voltage regulation and battery power during outages, ideal for small businesses.
Online/Double-Conversion Systems: The cream of the crop, they provide continuous AC-to-DC conversion, making them indispensable for critical operations like data centers.
Crucial Components of a Battery Backup System: Let's crack open the anatomy of a battery backup system:
Batteries: The powerhouse that stores energy, ready to leap into action when the main power falters.
Inverters: These wizards convert battery-stored DC power into usable AC power for your devices.
Automatic Transfer Switches: The gatekeepers that detect power disruptions and swiftly switch to battery power, ensuring seamless operations.
Advantages Galore with Battery Backup Systems:
Device Defender: Shield your devices from power surges and voltage spikes.
Data Protector: Keep your data safe during sudden outages, whether you're working from home or running a business.
Operational Savior: Crucial processes in businesses like servers and communication systems remain unaffected and uninterrupted.
Life Extender: Ensure the longevity of your electronic gadgets with consistent power supply.
Stress Reliever: Bid adieu to power-related stress as you continue your tasks seamlessly.
Choosing the Right Battery Backup System: The key to a harmonious power backup experience lies in selecting the right system for your needs:
Load Capacity: Calculate the combined power requirements of all connected devices.
Runtime Consideration: Determine how long the battery can sustain your devices during an outage.
Device Compatibility: Match the power needs of your devices with the capabilities of the battery backup system.
Simple Setup and Easy Maintenance: Installing a battery backup system isn't rocket science. Stick to the manufacturer's instructions or consult a pro for complex setups. Regular maintenance includes battery checks and system functionality tests.
Real-Life Stories:
Home Heroics: A homeowner's crucial work project was saved by a battery backup system during an unexpected outage.
Business Triumph: An online store didn't lose a penny in revenue during a blackout because their online operations were backed by a battery backup system.
Medical Marvel: Hospitals rely on these systems to ensure life-saving medical equipment remains operational, even during power failures.
Battery Backup vs. Generators: Making the Choice: While generators offer prolonged power supply, battery backup systems are compact, noise-free, and provide instant power. They're a cost-effective solution for short-duration outages.
Conclusion : When darkness threatens to disrupt your digital world, a dependable battery backup system steps in as your guardian angel. Whether you're safeguarding your home office, ensuring business continuity, or protecting critical systems, investing in a robust battery backup system is a smart move. Empower yourself with uninterrupted power and embrace the future of electronics resilience.
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gay-dorito-dust · 4 months ago
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Reader being a nonfilter dumbass to sentient Logan w/ wade joining in
Reader: *sees the scene of Logan's costume becomes shreds due to the high electric voltage*
Reader: *looks at wade*
Wade: *looks at Reader*
Wade: no lube no protection, all day all night
Reader: from the kitchen floor to the bathroom sink
Logan: leave me the fuck alone
*Logan and Laura (x-23) having a heart to heart conversation*
Reader: I just know damn well he’s good with kids.
Wade: so good with kids.
Reader: Like really good with kids despite saying he doesn’t want any of his own but secretly does.
Reader: I’m ovulating so hard rn just thinking about it.
Wade: same here compadre. Same here.
Logan: WILL YOU TWO PACK IT IN!
Laura: ???
Logan: *does literally anything*
Reader: I’m hard. This fine specimen of a man shouldn’t legally be this fine.
Wade: hope I don’t get blue balls from how hard I am right now.
Reader: you literally had a boner this entire time, that suit of yours does little to hide it.
Wade: you’ve been looking at my boner? Does it make my ass look fat?
Reader: you’ve got a fat enough ass as it is, your dick just emphasise it.
Wade: *wipes a tear* you truly know how to make a man feel special.
Logan: ??? What the fuck-
Logan: *bends down*
Wade and reader: *tilts their heads in order to get a better view of Logan’s ass before looking at one another* nice.
Logan: *growls in Wolverine*
Logan: *walks past*
Reader: nice ass
Wade: *gasp* do not lust in your heart *catches a glimpse of Logan’s ass* Jesus you’re right.
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alchemist-of-life · 6 months ago
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I’m curious how binary cant work for admech since day 1. At first, I thought it’s just high speed alternation in frequencies of sounds to denote 0 and 1, just like how computer cable does with voltage. So I wrote a python script to convert natural language to binary code then to sound based on the idea (so that I can curse in binary in ttrpg). However, since the human auditory cortex can only distinguish sound about 20ms apart, the current commonly used binary coding method (Unicode) that requires 8 bits to encode for one letter (16 bits for one character in Mandarin) would make binary cant less efficient than natural language through the bare ear. As a result, binary cant users not only need vocal implants but also auditory implants to receive info (or perhaps cortex implants to decode). Based on these assumptions, binary cant would be able to happen in sound frequencies not perceivable by the original human cochlea so techpriests conversation can be extremely quiet. And more efficiently, just through data cables.
Or it could be the other way around, scientists might develop more efficient binary language without basing it on the symbol system of natural languages (I’m not that familiar with linguistics so I don’t know if this is possible or not).
However, the sound techpriests made in the game mechanicus doesn’t sound like my assumption. There are definitely more than 2 pitches used in the conversations (which makes it less binary...) and they seem to be faster than natural language. I still couldn’t figure out what’s happening here. Do the twisting pitches actually encode more than one bit? Is binary cant actually an analog signal encoding a digital signal? Or is the sound effect just mean to sound better for the game?
The binary curse program (turn the sound on!):
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barbw2xey · 2 years ago
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Voltage conversion system, Power Management IC, ‎DC-DC Switching Converter
MP4570 Series 55 V 3 A Fully Integrated Step-Down Converter - TSSOP-20EP
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spiraleyedbimbo · 9 months ago
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Please don't do this. I'm an industrial electrician by day. I work with dangerous voltages in dangerous machines. A lapse in judgment could cost me dearly, and that's not sexy at all. What is sexy? Consent is sexy. Conversation is sexy. Consideration is sexy. And to whomever is reading this: your butt is sexy. Pass it on.
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andmaybegayer · 3 months ago
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huh, Doxy makes a wand variant that outsources the voltage conversion to a USB-C phone charger now. Clever cost cutting measure!
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zxvmp · 7 months ago
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DTF? (Denki x Fem!Reader)
summary: it’s the weekend, so you and your classmates decide to celebrate your off days partying. where would be a better place to party than the club? What you didn’t think would happen was hooking up with Kaminari.
tags: alcohol, underage drinking, smut, improper quirk usage, unprotected sex (wrap it before you tap it guys), vaginal sex, roughness, skin marking
a/n: not proof read, so sorry for any errors 😩
You scrambled through your dresser drawers looking for an outfit. If you were going out with your classmates, you wanted to look extra good. There weren’t many opportunities for you to dress up and look good, so you wanted to take advantage of this opportunity.
It was Mina’s idea to sneak out when Aizawa fell asleep. The club was your idea. It took a bunch of convincing Yaoyarozu to create fake ID’s for everyone. Not to mention getting Ida to not snitch. He agreed to be on watch out for you all in case Aizawa got up.
The plan was perfect.
You pulled out a short, skimpy bright red dress that looked like a stripper would wear. It shocked you that you even owned such a thing. You thought it was a bit too much, but you really didn’t have anything else. Plus, you were sure the other girls would wear similar things.
Once the hallways started to silence, you took the time to get ready and patiently wait for a text message. You wore your hair down with a slight curls at the ends. Your makeup was subtle, just mascara, blush, and lipgloss.
As your phone buzzed on your nightstand, you applied your finishing touches and checked your phone.
Mina 🩷
alr guyss
we’re in the clear! 😍
meet up in the front quickly!! (1:02 a.m.)
Kirishima 🪨
awesome 😎
i’m so pumped
Mineta 😐
me too 🤤
*Jirou, You, Yaoyarozu, Uraraka, & others disliked Minetas message*
You slid on white high-top converse and quietly opened your door. Since you didn’t own any heels, your converse were just going to have to do. Plus, you didn’t want to deal with sore ankles the next day.
The walk down to the front doors was difficult. Mostly because everyone was containing their laughter from trying to be quiet. It didn’t help that Denki accidentally tripped down the stairs, causing a loud bang to roar throughout the staircase.
Once you all made it to the front, Denki used small voltages to disable to cameras set up. After all of the cameras were disabled, you booked it towards the front gates where multiple taxis were parked. You made a mental note to thank Yaoyarozu for paying for them.
You ended up jn a taxi with Denki, Mina, and Kirishima. The four of you were known as the planners for party situations. It was a tight squeeze in the backseat, but you all managed. You were in between Mina and Denki.
To help pass time, you played mini games on your phone. As you played your games, you noticed you forgot to charge your phone. You let out a sad sigh and disregarded the low battery notification.
Denki heard your sigh and turned his head to notice your low battery. “I got you.” He pointed a finger at your phone and used his quirk to charge your phone.
You gave him a smile, “Thanks.”
He nodded and turned his head to continue talking to Kirishima. However, your eyes were left lingering on him. He wore a black dressed shirt that was slightly unbuttoned with a gold chain. For pants, he wore black baggy jeans. An all-black combo. His cologne entered your nostrils which made you start to realize how attractive Denki actually was. You knew he was hot, but tonight he looked better than usual.
Seeing him now really set something off in you.
“Whatcha lookin at?” Mina whispered, nudging you playfully.
You bit back a smile and nudged her back, “Stop.”
Mina giggled, “C’mon just say it’s already! You think he’s hot.”
Just before you could raise your hand to silence her, Kirishima caught your attention.
“Yo, we’re here!” Kirishima excitedly hopped out the car. Denki gave you a quick glance before hopping out shortly after.
You looked back at Mina and she raised and dropped her eyebrows playfully, making you roll your eyes.
As you scooted towards the door of the car, Denki stood outside with his hand out. You paused before taking his hand.
“What’s up with all these kind gestures? You’re usually always finding a way to annoy me.”
Denki laughed, “Who says i’m still not finding ways?”
You let out a small yelp and jolted at the sudden feeling of a shock. “Ow!”
While Denki was in a laughing state, you took your chance to activate your quirk. You raised your hand and summoned a water hand to follow your action. A loud slapping sound echoed throughout the crowd, causing some people to turn back and look at the two of you.
“OW! Mine did NOT hurt that much.” Denki rubbed his cheek and wiped a tear that formed in his eye.
You snickered, “C’mon, half of them already made it in.”
~
Loud music played throughout the club. You were already five shots in of the 10 minutes of being there.
“Damn (Y/N), you do this often?” Kirishima watched as you downed a shot, amazed at how you were in the lead.
You, Denki, Mina, Kirishima, Bakugo, and Yaoyarozu were all in a drinking competition. At first, it started off with the whole class. But after three shots, multiple people tapped out.
“Nope, maybe you guys are just lightweight.” You wink, finishing another shot. In truth, you really didn’t know how you were managing multiple shots.
Bakugo snatched the shot you were reaching for before you could grab it, “Shut you damn weirdo, I won’t allow you to beat me.”
You giggled, “Alright tough guy, I was about to tap out anyways.”
And thank god you did. While you watched the others compete to drink, it all hit you. You were cheering on Denki as it happened. In one blink, your vision became slower and you could feel your body become fuzzy.
“Damn, you guys look fucked up.” Mina laughed, nudging Kirishima to look.
“How many did you guys take?!” Kirishima burst out laughing.
You looked over at Denki and noticed his eyes were half-lidded and a drunk smirk was plastered on his lips. The two of you help eye contact before he broke it.
“Wayyy more than you.”
You giggled, “Yeah!”
“Whatever, i’m gonna go find someone to dance with.” Mina got up and disappeared into the large crowd of people.
You decided dancing was a good idea and began dragging Denki into the crowd without a thought. Flashing lights were displayed everywhere and you could feel strangers brush up against you every other second.
“Awe you wanna dance with me?”
You shrugged your shoulders, “I’m bored.”
At first, it started with the two of you singing your heart out to a justin beiber song. Mina probably managed to sneak in a song request because you knew it was her favorite song. Then, as the music began to drift off to other songs, you found yourself dancing against Denki.
His hands were rested on your hips while your back was against his stomach. You felt so free and loose drunk. It was amazing. Not to mention the rush of excitement you felt whenever you’d occasionally grind your ass against Denkis crotch. You could tell he enjoyed it from the way his grip on your hips would change.
You felt goosebumps form on your neck when you felt Denki kneel down to your level to rest his head on your shoulder. You turned your head slightly and caught his eyes.
In that moment, it was like everything around you was a blur. It was only you and Denki. His eyes traveled from your eyes to your lips. You felt the urge to kiss him. He must’ve felt the same thing, because he beat you to it.
His lips were on yours in an instant. You gasped into the kiss when you felt his hands slowly move around your body. The kiss escalated quickly. You turned around to wrap your arms around his neck for a better angle.
After a while, you both pulled away to catch your breath. You stared up into his yellow eyes admiring his handsome face. Behind his half-lidded eyes, you could tell his gaze was filled with lust. You couldn’t lie and say you weren’t aroused either.
A smirk formed on your lips, “Down to fuck?”
~
It was a risky gamble. As everyone began to head back to their dorm rooms, you managed to sneak into Denki’s unnoticed.
The second the two of you reached his room, your hands were all over each other. A trail of clothes and shoes were led up to his bed. Soft moans escaped your mouth as his mouth attacked your skin. One of his hands were placed beside your head while the other was slowly making its way down your thighs.
You gripped his forearm when you felt his middle finger run down your slit. His smirk deepens and you could he was enjoying every moment of this. He loved the way your facial expressions changed with each touch. It’s like he knew your weaknesses.
“Had a feeling you liked me.” He inserted his ring and middle finger, making you whine, “Tell me i’m wrong.”
“What…?” You breathe out. Your mind was focused on the way his fingers were plunging in and out of you. The alcohol in your system made you sensitive to any and every touch.
“C’mon, you don’t think I tease you all the time just for fun? I do it because I know you like it.” His pace increased, “I mean, when I didn’t hear you deny Mina, it all started to piece together.”
You were at a loss for words. You’d have to kill Mina later for her loud mouth.
“If you knew, why are you trying to get it out of me n-now?” You words were mushing together from the sensations you were feeling. Denkis fingers were curling up into you at a perfect angle.
He giggled, “I dunno, just wanted to hear it from you.”
Before you could say anything else, you were cut off by the waves of electricity coursing throughout your body. Denki placed his thumb on your clit and used his quirk to stimulate you more. You never thought such a feeling could make you feel so good.
A loud moan echoed in his room and you felt a knot form in your stomach. Through your blurred vision, you could see that Denki was in awe.
“Fuck..”
His lips crashed onto yours and you could feel another shock jolt your body. With a final thrust of his fingers, you came undone. Your release coated his fingers and you were almost embarrassed at the sight.
“Think you can take some more, pretty girl?” Denki brought his fingers up to his mouth to lick them clean.
Watching him do so sparked something in your body you never thought would. You nodded your head to his question as you calmed down from your high.
Denki had a pretty good size for a dick, much bigger than you imagined. Watching him slide in was definitely the highlight of your night. Both of you groaned in unison once he was fully in. You felt so full.
You threw your head back and closed your eyes once he began to thrust. He started of slow so the two of you could adjust to the euphoric feeling.
“Fuck—Denki, keep going.” You muttered in between quick breaths. He felt so good inside of you. It was a perfect fit.
He let in a sharp inhale when you clenched around him, “Whatever you say, angel.”
His nicknames made your heart swoon. Once his pace picked up, you clutched the bedsheets beneath you. The grip his hands had on your hips was brutal and sure to leave markings in the morning, but you didn’t care. Not when you felt like that.
Your breaths started to become erratic, and you could tell from the way his thrust started to become sloppy, he was close.
“Denki-”
He groaned, “Yes?”
“After this, what are we?”
He smiled and planted a kiss on your forehead, “Whatever you want us to be.”
You smiled and hooked your arms around his neck to bring him into a kiss. Denki brought a hand up to your cheek and traced circles with his thumb. You turned into mush under his touch. He was truly your weakness, and you were totally okay with that.
“Tell me if it’s too much, mkay?”
You nodded and unhooked your arms from his neck. His hands returned to your hips and you felt his pace pick up again. However, his thumb began to circle your clit with his quirk playing a role, sending you over the edge. You were a moaning mess.
The voltage of electricity had you seeing stars and feeling things you didn’t think you could ever achieve. No man has ever made you feel that way.
Nothing but moans and broken cries came out your mouth. Denki was enjoying every second of it. Hell, if he could hear you and watch you crumble like this everyday he’d do it in a heartbeat.
Without warning, your body began to spasm and an intense orgasm took over your body. Denki continued to thrust into you, chasing his own high.
“Ah—Denki!”
“I know babe, just give me a couple more seconds.”
Your mind went blank and your ears began to ring. After a couple minutes, you began to snap back to reality. Your eyes traveled down to see Denki cleaning your stomach with a T-shirt. You mentally thanked him for not finishing inside of you.
You snickered.
“What? It’s all I had.”
“Thank you, now let’s sleep. I’m exhausted.”
He tossed the dirty T-shirt to the side and crawled up next to you. You pulled a blanket over your bodies and slowly drifted off to sleep. You had a lot to discuss in the morning.
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mydear-corinthian · 7 months ago
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Rivals || Jonathan Crane x reader
Synopsis: You and Crane are both fighting for the asylum's new head of the psychologist department. Pairing: Jonathan Crane x reader / Jonathan Crane x psych! reader / Scarecrow x reader Warnings: SMUT +18, unprotected sex, p in v, rivalry Notes: RUSHED, there will be lots of grammatical errors. Click here to see the MAIN MASTERLIST Click here to see the CILLIAN MURPHY MASTERLIST
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Today is the important day of your career. The head medical chief will now announce who will be the head of the psychology department.
You were working for nearly 5 years in Gotham's asylum, Arkham Asylum. You've seen many patients; juveniles, sadists, serial killers, and other more. It wasn't easy at first but slowly, you got the hang of it, being able to adjust the unusual environment of the hospital.
You had barely any interaction with anyone else when you were an intern except for Jonathan Crane. He was your age, a fellow psychologist committed to helping Arkham Asylum's needy patients. Your relationship with Crane developed with shared experiences and shared loyalty, creating a firm connection during the psychological obstacles of the asylum.
The pressure between you and Crane was intense and serious considering there were just the two of you. You will both keep track of the number of patients you see each day, the number of consultations and interviews you do, and of course, the journey toward becoming the department head of psychology.
Now, the both of you standing in front of the head chief resident, waiting for him to announce the result.
Even though you appeared calm and collected on the outside, there was a stream of anxiousness running through you. Jonathan Crane was just as calm as you were, but in opposite to you, he was so confident and at relaxed that there was no trace of nervousness.
"Doctor Crane, Doctor (Y/n), I want to say that the both of you did a wonderful job here as Arkham's psychology resident. I saw both of your performance since your first day and I can see the massive progress that you guys done for the past 5 years," the head chief resident said, lowering down the papers that contained both of your performances and records.
"Thank you, chief." a smile was plastered on your face as you thanked the chief resident.
"You both did an excellent job. I hereby congratulate our new chief..," the chief resident slowly announced, making your heart flutter, a wave of anxiety rushed over your spine.
"Doctor Jonathan Crane,"
Your eyes widened. You looked at your workmate, his eyes glowing as he shook the hands of the chief resident, thanking him.
You were left cashing by the shock that went through you like a voltage, and your hopes were buried in a deep sense of disappointment. A dream set back in the face of unexpected defeat, the pain of longing for this desired position, grown throughout your time at Arkham, suddenly seemed to resonate down the corridors of your mind.
Jealousy was starting to spin all over you as you shook Crane's delicate hand, muttering a 'congratulations'. You left the office after, giving the both of them privacy as they started a new conversation about Crane's new responsibilities and duties to the hospital.
Your gloomy walk echoed through the asylum's corridors. You immediately walked to your office and harshly opened and closed the door.
"What the fuck!" you yelled loudly in frustration Your palms curled up together like a ball. "What the fuck do you mean that Jonathan got the position and not me?" slapping your wooden table harshly as you threw a big tantrum.
"Fuck you, Jonathan!"
Good thing that your office was soundproof so all the staffs and patients passing by won't hear a single sound of you bursting into frustration.
Your tantrum stopped when you heard a knock on your office's door. Assuming it was the head chief resident, you fixed your hair and your outside, composing yourself.
You opened the door with a smile but it was gone after you see who it was-- Jonathan Crane.
"What are you doing here, Crane?" you spitted, your arms folding each other on your chest.
"May I come in?" he asked.
"Fine," you groaned in annoyance, opening the door widely so he can enter your lightly-dimmed office.
He scanned your office, looking at the picture frames on the hanged shelf, books that were neatly stored beside your frames, and your Ph.D and awards that hanged over the white walls of the office.
"Now, what do you want, Crane?" you asked again, sitting in front of the wooden table, both arms still locked in your chest together, your eyes piercing through his.
"I just want to congratulate you for having the chance to compete for the position," he teased, a small grin plastered on his soft cheeks.
"Oh fuck off, Jonathan. Yeah, I got it, you got the position," you rolled your eyes, getting angry and annoyed every time Crane breathes.
"Won't you congratulate me, (Y/n)?" he asked, moving closer and closer to you, until your faces were only centimetres apart.
"Fuck no! Just go and flex your position to somebody else because I don't care about you,"
Your response made him chuckle. He took a deep breath as he adjusted his clear eyeglasses. "Mhm, I don't think so. You care about me. You have feelings for me, don't you?"
Your eyes grew wide at what he said. Was he aware that you like him? He's your rival, and you were beginning to feel something for him. He's a perfect man - well for you. He's good looking, smart, and works with you but you kept it as a secret, ashamed that you're in love with someone you compete with. His words caused you blushing leaving you speechless.
"I - What? Funny, Jonathan. I don't even like yo-"
"Not according to your journal here," he cut you off, he took a small brown notebook out of the pocket of his blazer, showing it you.
Then you realized what it was: it's your missing journal book. You remembered leaving it at your desk a week ago but after that, it just suddenly disappeared like that. You kept on finding it, you searched everywhere, your apartment, your bag, your office, your cabinets: none.
"Where'd you get that! Give it back!" you gasped, attempting to grab it from his hand but he sways his arm back further away.
"God look at this. You were imagining stuffs like this huh? Lusty images and scenarios of me," he teased, opening the journal and scanned the pages.
"Fuck you, Jonathan," you cursed.
"If that's what you want," he said before he crashed his lips to yours. Tasting every spot in your lips. You gasped at the sudden action but it was true, you fantasized about this.
You returned the passionate kiss, wrapping your arms over his neck and then his now messy hair, pushing your lips deeper to him.
His tongue traveled deeper into your tempting mouth, the passionate kiss becoming more messier and messier. His hand held tightly to your delicate body, pulling you closer him. Your lips softly moaned, each one begging for the kiss to get even hotter and more intense. You could feel the heat building as you both gave in to the burning desire that was dominating over. 
Crane's lips started to trail down on your neck, kissing the sweet and sensitive spots all over, earning a loud moan from you.
"You know, I fantasized about this too," he confessed, sucking your sweet spot that will likely leave a mark. Your back arched, your cunt getting more and more wet. "It's just that I don't write about it."
"Oh god, Jonathan," you moaned. His hands found your tight long sleeve shirt, unbuttoning it one by one. Crane tossed your shirt on the floor, continuing kissing you.
"Look at you. So fucking sexy," he said, your breasts now exposed after he unhook your bra only using two of his fingers.
Crane's trousers stretched out revealing his bulge and how he was hard already. In not much time at all, you unfastened his belt and took off his underwear, causing his hard cock to spring out, pre-cum leaking all over it.
"See what you did to me?"
"I need you, Jonathan," you begged, showing how wet you were when you removed your trousers. Your black panties were now stained with wetness.
He removed your panties with his soft hands before aligning his cock into your hole. "So wet for me, huh?" his tip teasing your wet and impatient hole as you moaned softly.
"Please.." you begged, getting more and more impatient.
He slowly entered you, earning a low grunt from him. Stretching your small hole as you took him.
"You're so tight, fuck," he cursed, starting his pace slow. His cock pushing in and out of your needy cunt, letting you a loud moan.
"Is this what you imagine me doing to you? Fucking you? Taking my cock?" he asked, his hands gripped your hips harshly as his pace fastened. A small dash of sweat was starting to form on his forehead as he grunt out loud from the sensation.
"Yes - oh god, Jonathan!" moaning, your eyes shut as you rolled your head back, taking him deeper and deeper. Allowing him to penetrate all the sensitive spots down there.
All you experienced was nothing but pleasure. You felt a rush feeling of thrill wash over you, seeing only sparkles. A huge mess was made as your skin flapped loudly, the table moved around, and some of your materials items fell off the table.
"Look at me while I'm fucking you, sweetheart." Crane hissed, harshly gripping your jaw to make you look at him.
His pace was immeasurable. The sound of his and your skin slapping together echoed inside the room as you let out a series of pornographic moans.
"Good thing your office is soundproofed," he laughed. "You don't want them to hear you moan while I fuck you, huh?"
Crane's right hand gripped your thighs, giving him support as he fucked you harshly.
In a short while, you felt your orgasm starting to form. Your legs trembling as you locked his back with it, allowing him to penetrate deeper at your sensitive spots.
His icy-like eyes met yours, mesmerizing him. His eyes. His mouth. His jaw line. Everything, admiring him.
"Jo - Jonathan, I'm close.." you breath shaking, feeling your orgasm coming near and nearer.
"Yeah? Come then, cum on my cock, love," his pace remained fast. His grunts were getting louder and louder.
After a few more thrusts, your orgasm came and so did his, staining the inside of walls with his seed as he came inside. The both of you continuously let out a few grunts and moans while reaching your high.
He didn't pulled out until every drop of his cum pours inside of you. The both of you pant hard, your cunt clenching on his hard cock.
"I like you, Jonathan," you confessed.
"Oh sweetheart, you belong to me," he said, pulling out slowly before he kissed you again but this time he did it passionately.
"I'm still mad at you for getting my desired position," you admitted, glaring at his sweet features as he chuckled with your response.
"Well, I can request the chief to make 2 psychologist the heads of our department," he remarked. "But before that, let me.. enjoy what belongs to me."
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girlactionfigure · 3 months ago
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1 Nobel Prize in Chemistry - The Development of Multiscale Models for Complex Chemical Systems
2 Nobel Prize in Chemistry - Quasiperiodic Crystals
3 Nobel Prize in Chemistry - Decoding the Structure and The Function of The Ribosome
4 Nobel Prize in Economic Sciences - Repeated Games
5 Nobel Prize in Chemistry – Ubiquitin, Deciding the Fate of Defective Proteins in Living Cells
6 Nobel Prize in Economics - Human Judgment and Decision-Making Under Uncertainty
7 Fields Medal Award in Mathematics
8 Turing Award - Machine Reasoning Under Uncertainty
9 Turing Award - Nondeterministic Decision-Making
10 Turing Award - The Development of Interactive Zero-Knowledge Proofs
11 Turing Award - Developing New Tools for Systems Verification
12 Vine Seeds Discovered from The Byzantine Period
13 The World’s Most Ancient Hebrew Inscription
14 Ancient Golden Treasure Found at Foot of Temple Mount
15 Sniffphone - Mobile Disease Diagnostics
16 Discovering the Gene Responsible for Fingerprints Formation
17 Pillcam - For Diagnosing and Monitoring Diseases in The Digestive System
18 Technological Application of The Molecular Recognition and Assembly Mechanisms Behind Degenerative Disorders
19 Exelon – A Drug for The Treatment of Dementia
20 Azilect - Drug for Parkinson’s Disease
21 Nano Ghosts - A “Magic Bullet” For Fighting Cancer
22 Doxil (Caelyx) For Cancer Treatment
23 The Genetics of Hearing
24 Copaxone - Drug for The Treatment of Multiple Sclerosis
25 Preserving the Dead Sea Scrolls
26 Developing the Biotechnologies of Valuable Products from Red Marine Microalgae
27 A New Method for Recruiting Immune Cells to Fight Cancer
28 Study of Bacterial Mechanisms for Coping with Temperature Change
29 Steering with The Bats 30 Transmitting Voice Conversations Via the Internet
31 Rewalk – An Exoskeleton That Enables Paraplegics to Walk Again
32 Intelligent Computer Systems
33 Muon Detectors in The World's Largest Scientific Experiment
34 Renaissance Robot for Spine and Brain Surgery
35 Mobileye Accident Prevention System
36 Firewall for Computer Network Security
37 Waze – Outsmarting Traffic, Together
38 Diskonkey - USB Flash Drive
39 Venμs Environmental Research Satellite
40 Iron Dome – Rocket and Mortar Air Defense System
41 Gridon - Preventing Power Outages in High Voltage Grids
42 The First Israeli Nanosatellite
43 Intel's New Generation Processors
44 Electroink - The World’s First Electronic Ink for Commercial Printing
45 Development of A Commercial Membrane for Desalination
46 Developing Modern Wine from Vines of The Bible
47 New Varieties of Seedless Grapes
48 Long-Keeping Regular and Cherry Tomatoes
49 Adapting Citrus Cultivation to Desert Conditions
50 Rhopalaea Idoneta - A New Ascidian Species from The Gulf of Eilat
51 Life in The Dead Sea - Various Fungi Discovered in The Brine
52 Drip Technology - The Irrigation Method That Revolutionized Agriculture
53 Repair of Heart Tissues from Algae
54 Proof of The Existence of Imaginary Particles, Which Could Be Used in Quantum Computers
55 Flying in Peace with The Birds
56 Self-Organization of Bacteria Colonies Sheds Light on The Behaviour of Cancer Cells
57 The First Israeli Astronaut, Colonel Ilan Ramon
58 Dr. Chaim Weizmann - Scientist and Statesman, The First President of Israel, One of The Founders of The Modern Field of Biotechnology
59 Aaron Aaronsohn Botanist, Agronomist, Entrepreneur, Zionist Leader, and Head of The Nili Underground Organization
60 Albert Einstein - Founding Father of The Theory of Relativity, Co-Founder of the Hebrew University in Jerusalem
61 Maimonides - Doctor and Philosopher
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@TheMossadIL
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