Ingen kunder, ingen inntjening, ingen kontrakter, ingen kommunikasjon og ingen produkt. Man kan jo lure på hvorfor man satte sparepengene her. Siste mann får slukke lyset, tipper det er FaderGem

https://www.youtube.com/watch?v=gG2_5GMWf1E

what are coin cell battery labs for
ChatGPT
Coin cell battery labs are specialized facilities or setups used for the research, development, and testing of coin cell batteries, which are small, round, single-cell batteries commonly used in compact electronic devices like watches, calculators, hearing aids, and small medical devices. These labs focus on various aspects of coin cell battery technology, including:

Materials Research:

Investigating new materials for electrodes, electrolytes, and separators to improve battery performance, such as energy density, lifespan, and safety.
Developing and testing advanced materials like new cathode and anode materials, solid-state electrolytes, and novel separator materials.
Battery Design and Fabrication:

Designing and fabricating prototype coin cells to test new materials and battery chemistries.
Optimizing the design and manufacturing processes to enhance battery performance and reliability.
Performance Testing:

Conducting various tests to evaluate the performance of coin cells, including capacity, cycle life, charge/discharge rates, and thermal stability.
Testing batteries under different conditions to ensure they meet required standards and specifications for their intended applications.
Failure Analysis and Safety Testing:

Analyzing the failure modes of coin cell batteries to identify potential issues and improve their safety and reliability.
Conducting safety tests such as overcharge, short-circuit, and thermal runaway tests to ensure the batteries are safe for consumer use.
Electrochemical Analysis:

Performing electrochemical impedance spectroscopy (EIS), cyclic voltammetry (CV), and other electrochemical techniques to understand the behavior of battery materials and interfaces.
Investigating the electrochemical processes occurring within the battery to improve its efficiency and performance.
Prototyping and Scale-Up:

Developing scalable manufacturing processes for coin cell batteries to transition from laboratory prototypes to commercial production.
Collaborating with manufacturers to implement new technologies and materials in mass-produced coin cell batteries.
Environmental and Lifecycle Testing:

Assessing the environmental impact of coin cell batteries, including their recyclability and disposal.
Conducting lifecycle analysis to determine the overall sustainability of the battery technology.
Coin cell battery labs are crucial for advancing battery technology, enabling the development of more efficient, durable, and safer batteries for a wide range of applications.

CHATGPT svar

Så mens dere er desperate etter å få en lavere kurs så driver selskapet nå med R&D på høygir. Vi får se hvem som er inne og ute når/om/hvis de lykkes

Så kan vi ta med den siste milestone de kom med:

We are proud to announce that our newly developed battery lab has successfully fabricated its first reference test cells! This significant achievement is a testament to our team's dedication and hard work in our ongoing efforts to innovate, conduct R&D, and optimize our green carbon products.

This milestone marks a new chapter in our journey toward advancing our green carbon products into next generation battery chemistries.

A big thank you to everyone involved in making this happen.

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Eller du får se FaderGem vandrende i midten, hånd i hånd med Mor Blydt Svendsen og Awilco, i slow motion glise fra øre til øre da gjennombruddet kommer.
Lysbryteren får du leke med så mye du vil for min del.

https://www.nordnet.no/market/stocks/17395516-quantum-scape-a

https://www.nordnet.no/market/stocks/17646555-solid-power-a

Fremtidens batteri ?

Disse firmaene har forsket på dette i MANGE år. Nå kommer resultatet

Måtte Odd fyre av en heidundrandes NEWSWEB melding nå som mange har solgt. Da skal man få løpe fort etter.

Har chatgpt data etter 2021 da ?

SOLGT ? Noen har også kjøpt ? ……….. eller….
Ingen har kjøpt pga den nye teknologien UTEN men pga uvitenhet.

If your goals is to manufacture next generation battery materials why would you need a battery lab?
ChatGPT
If your goal is to manufacture next-generation battery materials, having a battery lab is essential for several reasons:

Material Characterization:

To thoroughly understand the properties of new materials, such as their electrochemical behavior, conductivity, stability, and interaction with other components of the battery.
Prototype Development:

To fabricate prototype batteries using the new materials and assess their real-world performance. This helps in transitioning from theoretical concepts and lab-scale materials to practical, usable battery components.
Performance Evaluation:

To conduct comprehensive performance testing of batteries made with the new materials. This includes evaluating metrics like energy density, power density, cycle life, charge/discharge rates, and overall efficiency.
Optimization and Refinement:

To optimize the composition and fabrication processes of the new materials to maximize their performance and compatibility within the battery system. Iterative testing and modification are often necessary to refine materials and processes.
Failure Analysis and Safety Testing:

To identify potential failure modes and safety issues associated with the new materials. Understanding how new materials behave under various conditions (e.g., overcharging, high temperatures) is crucial for ensuring the safety and reliability of the final battery product.
Integration with Existing Technologies:

To test how new materials integrate with existing battery technologies and components. Compatibility with current manufacturing processes and standards is key to practical implementation.
Benchmarking Against Standards:

To compare the performance of batteries with new materials against industry standards and existing technologies. This helps in demonstrating the advantages of the new materials and in making a compelling case for their adoption.
Environmental and Lifecycle Analysis:

To assess the environmental impact, recyclability, and overall sustainability of the new materials throughout the battery's lifecycle. This is increasingly important for meeting regulatory requirements and consumer expectations.
Collaboration and Scale-Up:

To collaborate with industry partners and scale up the production of new materials. Demonstrating the effectiveness of materials in a controlled lab environment is a critical step before moving to pilot and commercial-scale production.
Regulatory Compliance and Certification:

To ensure that batteries using new materials comply with relevant regulations and certification requirements. Rigorous testing in a lab setting is necessary to meet these standards and gain market approval.
In summary, a battery lab provides the necessary infrastructure and expertise to rigorously test, refine, and validate new battery materials, ensuring they are viable for practical applications and can be successfully integrated into commercial battery technologies.

How far are you in this process if you issue a news about reaching a milestone where you have created reference test cells
ChatGPT
Issuing a news update about reaching a milestone where you have created reference test cells suggests that you have made significant progress in the development process of next-generation battery materials. Here's what this typically indicates about your current status:

Material Development and Validation:

You have successfully developed and synthesized new battery materials that show promise based on initial laboratory tests.
Prototype Fabrication:

You have fabricated prototype reference test cells using these new materials. This involves assembling these materials into a functioning battery cell format, which is a critical step towards practical application.
Initial Performance Testing:

You have conducted preliminary performance tests on these reference test cells to validate their basic electrochemical properties and functionality. This includes measuring parameters like capacity, energy density, charge/discharge rates, and initial cycle life.
Proof of Concept:

You have demonstrated proof of concept that the new materials can be used to create functional battery cells, which is a major milestone in the development process.
Benchmarking:

You have likely conducted some benchmarking against existing battery technologies to showcase the potential advantages of your new materials.
Internal Validation:

Internal validation of the reference test cells has been completed, providing confidence that the new materials work as intended in a complete cell configuration.
Next Steps After Creating Reference Test Cells
Extended Testing and Optimization:

Conduct more extensive performance testing over a larger number of cycles and under various conditions to better understand the long-term stability and performance characteristics of the new materials.
Optimize the composition and fabrication process based on these tests to further enhance performance.
Scale-Up Experiments:

Begin scaling up the production of the new materials to produce larger quantities for further testing and potential pilot-scale production.
Safety and Reliability Testing:

Perform detailed safety and reliability tests, including thermal stability, abuse tests, and failure mode analysis to ensure the new materials are safe for commercial use.
Collaboration and Pilot Production:

Collaborate with industry partners to integrate the new materials into larger format cells and modules.
Initiate pilot production runs to test the manufacturing scalability and process integration.
Regulatory and Certification Processes:

Prepare for regulatory compliance and certification processes, ensuring that the new materials and battery cells meet all necessary standards and regulations for commercialization.
Commercialization Strategy:

Develop a commercialization strategy, including identifying potential markets, applications, and partnerships to bring the new battery technology to market.
Creating reference test cells is a significant milestone that indicates a solid foundation for further development, testing, and eventual commercialization of your next-generation battery materials.

Var selvfølgelig ikke for uten grunn de satte i gang denne batterilabben👌🏼 Smart trekk for fremtidens reise. Så har vi Rameez Razaq som fast inventar i denne labben, og dette vil jeg si er ingen hvem som helst. Mon tro hva denne hjernen får til med de andre hodene til stedet med tiden til hjelp.
Det skader neppe å prøve, de som mener bedre foruten bør ta seg en tur i skogen å gjemme seg under en stein i et par århundre til. Dette kan bli særdeles, unnskyld uttrykket, jævlig bra! :-)

Og som Odd sier, litt latency i batterisegmentet akkurat nå, så flott da! Et aldri så lite spillerom for forbedringer til lægginga har frekvensert seg.
Noen tror de piller reker og ser på YouPorn, jeg tror de gjør noe helt annet.. men det er jo hodet til hver enkelt som bestemmer hva som skjer i fantasien. Her finnes ingen grenser, tydeligvis! 😏

Hvorfor har et amerikansk fotballag som oftest et cheerleader-team, som slenger rundt på hverandre i håp om at laget skal vinne? Hva gjør menigheten her? Satan til folk, folk er 🧑‍🦽 Surmula rullestolmisbrukere, det er det dere er, til krykkene har grunn for å svikte under armene på dere. Hva gjør dere da? Løper etter? Run Forest, Run!

Trøstepreik fra chatgpt og utskjelling over en lav sko. Her er det jammen høyt nivå. Gpt er forøvrig tvangsforet på alskens positive børsmeldinger fra hypende grønne batteriselskap fra de siste år, så den infoen som kommer fra den kverna burde en ta med en viss skepsis. Noen som kjenner til reelt antall aksjer i selskapet hvis man tar med opsjoner osv?

Dette kan jo også sammenlignes med propagandaen over hvor bra vaksinedosene var for allmuen, fra 6 mnd til 89 år.. ta alt med en klype salt, kun tiden vil vise hva som er rett. Så langt i BCS spor, så er det kun forbedringer som kan gjøres, ikke nedsetting av eget folks immunforsvar. Så langt, alt vel! Toget går i riktig retning, ikke med haltende bekymringer for noe annet.

Eller bekymringer kan jo gjøre noe med allmenntilstanden til folk... Psykologien vil seire, alt etter som hvor man er i bildet.

Det som jeg mener er viktig her er at selskapet klarer å lande en kontrakt med stort inntektspotensiale. Det vil snu helt om på caset da alle nå mener de ikke har et produkt og at teknologien er humbug. Det er derfor veldig viktig for selskapet å snu disse ondsinnede tungene og få inntekter på plass. Det vil fort bli en døråpner på andre områder. Så lenge BCS ikke tjener penger vil en DD kunne medføre manglende kontrakt. Det beste hadde vært om de inngikk noen mindre kontrakter først slik at de fikk noen ben å stå på og ikke kunne skvises i eventuelle forhandlinger/DD...

Solid-state batteries (SSBs) aim to replace traditional lithium-ion batteries by eliminating the volatile liquid electrolyte. Carbon nanofibers (CNF), carbon nanotubes (CNT), and graphene are promising materials for enhancing SSB performance. Here’s a summary of their roles:

Graphene: A one-atom-thick, highly conductive material that can be used to improve the cathode or anode in SSBs. Graphene’s high thermal and electrical conductivity make it an excellent candidate for enhancing ion transfer and reducing internal resistance. It can also be mixed with ceramic or plastic to create a conductive solid-state electrolyte.
Carbon Nanofibers (CNF): Long, thin fibers with high surface areas, which can be used to create a conductive network in the solid-state electrolyte. CNF can improve the mechanical strength and flexibility of the electrolyte, making it more suitable for large-scale applications.
Carbon Nanotubes (CNT): Tiny, tubular structures with exceptional mechanical and electrical properties. CNTs can be used to create a conductive network or as a reinforcement material in the solid-state electrolyte, enhancing its mechanical strength and thermal stability.
Key Benefits:

Improved safety: Solid-state batteries with CNF, CNT, and graphene can reduce the risk of thermal runaway and explosions, as they eliminate the volatile liquid electrolyte.
Enhanced performance: The high conductivity and mechanical strength of these materials can lead to faster charging, higher energy density, and longer cycle life.
Scalability: The use of CNF, CNT, and graphene can enable mass production of SSBs, making them more viable for widespread adoption.
Challenges and Future Directions:

Scalable production: Developing cost-effective and scalable methods for producing high-quality CNF, CNT, and graphene is crucial for widespread adoption.
Interfacial resistance: Minimizing interfacial resistance between the solid-state electrolyte and electrodes remains a significant challenge.
Stability and durability: Ensuring the long-term stability and durability of these materials under various operating conditions is essential for reliable SSB performance.
Existing Research and Applications:

Graphene-based solid-state batteries have been demonstrated with promising results, including high energy density and fast charging capabilities.
CNF and CNT have been used in composite anodes for lithium-ion batteries, showing improved performance and cycle life.
Researchers are actively exploring the use of CNF, CNT, and graphene in solid-state electrolytes, aiming to create more efficient and scalable SSBs.
By leveraging the unique properties of CNF, CNT, and graphene, solid-state batteries can overcome the limitations of traditional lithium-ion batteries and become a more viable option for various applications, including electric vehicles and renewable energy systems.