# "*": "https://raw.githubusercontent.com/wefindx/schema/master/method/oo-item.yaml" # "base:title": "0oo - Positronic Material Emulation Screen" "og:title": "Positronic Material Emulation Screen" "og:description": "Traditionally, what determines the chemical and physical properties of materials, is largely, how electron field gets arranged, when electrons encounter the force fields around nuclei. We traditionally rearrange that through introducing or taking away electrons to get new materials. However, nuclei are just sources of almost-point-like positive electric charges. If we could simulate those almost-point-like charges in other ways (like through directed positronic fields), it is not inconceivable, that one day we could create an equivalent of "computer screen" that simulates the surface properties of arbitrary materials including their chemical properties, without having any baryonic matter at all. This would …" "og:image": "https://avatars0.githubusercontent.com/u/28134655" "og:url": "/method/1025/" "base:css": "/static/css/bootstrap.min.9c25540d6272.css" "base:extra-css": "/static/css/base.57997aeac1df.css" "base:favicon": "/static/favicon.acaa334f0136.ico" "base:body_class": "" "layout:logo": "/static/0oo.8d2a8bbef612.svg" "layout:index": "/" "layout:menu": "/menu/" "layout:categories": "/intents/" "layout:ideas": "/methods/" "layout:projects": "/projects/" "layout:users": "/users/" "layout:about": "/about/" "layout:help": "/help/" "layout:bug_report": "https://github.com/wefindx/0oo" "layout:login": "/accounts/login/" "layout:light-off": "/darken/?darken=true" "layout:set-multilingual": "/mulang/?mulang=true" "layout:lang": "Language" "layout:set-language-post-action": "/i18n/setlang/" "layout:csrf-token": "R7HpHe67WnKdGhw2xjRT8Gi1kQyMgbqkz7kPJkT6EEW7Jfi8FqlFl6bZPSHxNdO2" "layout:input-next": "/method/1025/" "layout:languages": [{"code": "ja", "is-active": "false", "name": "日本語"}, {"code": "lt", "is-active": "false", "name": "Lietuviškai"}, {"code": "zh-hans", "is-active": "false", "name": "简体中文"}, {"code": "en", "is-active": "true", "name": "English"}, {"code": "ru", "is-active": "false", "name": "Русский"}, {"code": "oo", "is-active": "false", "name": "O;o,"}] # "item:parent:intents": [{"url": "/intent/1353/", "title": "Femtotechnology"}, {"url": "/intent/1290/", "title": "Science: Physics"}, {"url": "/intent/970/", "title": "High Energy Physics"}, {"url": "/intent/972/", "title": "Nuclear Physics"}] "item:title": ".:en:Positronic Material Emulation Screen.:lt:Pozitroninis medžiagos emuliatorius" "item:summary": ".:en:Shoot positrons to simulate the chemical properties of a surface through electric field patterning, and get electrons simulate materials without use of atoms..:lt:Šaudant pozitronus ir elektronus, (galbūt) galima būtų imituoti paviršių su cheminėmis savybėmis naudojant tik elektrinio lauko moduliavimą, nenaudojant atomų branduolių." "item:voting": 0 "item:voting:add": "/admin/hlog/voting/add/?method=1025" "item:voting:csrf_token": "R7HpHe67WnKdGhw2xjRT8Gi1kQyMgbqkz7kPJkT6EEW7Jfi8FqlFl6bZPSHxNdO2" "item:voting:submit-value-option": {"selected": "[-]", "value": "-"} "item:voting:submit-value-option": {"selected": "[+]", "value": "+"} "item:base-administration": false "item:body": | .:en Traditionally, what determines the chemical and physical properties of materials, is largely, how electron field gets arranged, when electrons encounter the force fields around nuclei. We traditionally rearrange that through introducing or taking away electrons to get new materials. However, nuclei are just sources of almost-point-like positive electric charges. If we could simulate those almost-point-like charges in other ways (like through directed positronic fields), it is not inconceivable, that one day we could create an equivalent of "computer screen" that simulates the surface properties of arbitrary materials including their chemical properties, without having any baryonic matter at all. This would likely be useful for generating arbitrary reactive surfaces to catalyze various chemical reactions. Given that we already have [positronic sources](https://en.wikipedia.org/wiki/Positron_emission#Positron-emitting_isotopes), and advanced electric field manipulation techniques, we could start playing with releasing them in streaks, in geometrically peculiar ways, such as to make them form not only electron-positron rings, or helical structures, but more -- seeking for more stable standing patterns, that remain sensitive to input conditions (incident electromagnetic wave). Such search for patterns eventually could result in discovery of positronic-electronic standing fields that do the trick. _Disclaimer: I'm not a physicist, but this, while highly speculative, seems like a logical possibility. It would be great to have an input from physicists with deeper knowledge into this domain._ .:lt Paprastai medžiagų chemines ir fizikines savybes apsprendžia tai, kaip pasiskirsto elektromagnetinis laukas, kuomet elektronai sąveikauja su elektromagnetiniais laukais aplink atomo branduolius. Paprastai kuriame medžiagas keisdami branduolius moduliuoti elektronų lauko pasiskirstymą. Tačiau branduoliai yra tik vieni iš galimų beveik-taškinių elektrinių krūvių šaltinių, ir jeigu galėtume juos simuliuoti kitais būdais (pvz., tiesioginiais pozitroniniais laukais), tai galbūt galėtume sukurti kažką panašaus į "kompiuterio ekraną", kuris simuliuoja bet kokių medžiagų paviršiaus savybes, įskantant jų chemines savybes išvis nesinaudojant jokia barionine materija. Tai tikriausiai būtų naudinga norint sugeneruoti bet kokių reaktyvių ar katalinių paviršių savybes katalizuoti įvairioms cheminėms reakcijoms. Kadangi jau egzistuoja pozitronų šaltiniai, ir pažangios elektrinio lauko valdymo metodologijos, galima būtų pradėti eksperimentuoti su jų paleidimu geometriškai įdomiomis trajektorijomis ir šuorais, kad susidarytų ne tik elektronų-pozitronų poros ar žiedai, ar spiralinės struktūros, bet daugiau -- ieškant stabilesnių elektronų-pozitronų stovinčių bangų pasiskirstymų, kurie išlieka jautrūs santykiavimui su krentančiomis elektromagnetinėmis bangomis. Tokia lauko pasiskirstymų paieška galbūt galėtų privesti prie tokių praktiškai naudingų positronų-elektronų stovinčių bangų, įgyvendinančių šią idėją. _Atsakomybės apribojimas: nesu fizikas, bet tai, nors ir labai spekuliatyvu, atrodo artima įmanomybei. Būtų puiku gauti įžvalgų iš gilesnių žinių apie šią sritį turinčių žinovų._ "item:source-date": "" "item:permalink": "/method/1025/?l=en" "item:owner": "Mindey" "item:created": "2021-01-02T00:54:18.232000" "item:ownerlink": "/user/147/Mindey" # "item:link:items": "item:link:add": "/admin/hlog/link/add/?parent=1025" "item:project:items": "item:project:add": "/admin/hlog/project/add/?parent=1025" "item:comment:add": "/methods/addnote?parent=1025" "item:comment:add:csrf_token": "R7HpHe67WnKdGhw2xjRT8Gi1kQyMgbqkz7kPJkT6EEW7Jfi8FqlFl6bZPSHxNdO2" "item:comment:form": |
  • Mark if the comment raises new questions.
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  • Mark if the comment contributes facts for reasoning.
  • Please, log in. # "item:comment:items": - "id": "a-1048" "mtrans": | It seems that you can control electronics to achieve more realistic virtual reality? "text": | 看起来,可以控制电子来实现更逼真的虚拟实境? "owner": "尹与及" "ownerlink": "/user/196/尹与及" "permalink": "/method/1025/?l=en#a-1048" "created": "" - "id": "a-1051" "text": | // more realistic virtual reality? Not really. This is not about virtual reality -- it's about creating mass-less interactive objects of the actual reality. One is not limited to 2D screens of course, this could be a 3D, hologram-like objects with surfaces that, at quantum level interact like real. That is, if you shine a laser onto such surface that emulates a mirror, it would (unlike a hologram) actually reflect the laser like a mirror would. "owner": "Mindey" "ownerlink": "/user/147/Mindey" "permalink": "/method/1025/?l=en#a-1051" "created": "" "base:js": "/static/js/base.c7357c06cc89.js"