QUYOSH ENERGIYASIDAN FOYDALANISH UCHUN YANGI AVLOD UF GA CHIDAMLI POLIMER NANOKOMPOZITLARI

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23 август 2025

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QUYOSH ENERGIYASIDAN FOYDALANISH UCHUN YANGI AVLOD UF GA CHIDAMLI POLIMER NANOKOMPOZITLARI

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MUQOBIL ENERGETIKA

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MAQOLA ANNOTATSIYASI

Annotatsiya. Kirish. Maqolada quyosh energiyasi tizimlarida foydalaniladigan polimer materiallarning UF nurlanishga bardoshliligini oshirish maqsadida polimer nanokompozitlar (PNK) ishlab chiqilishi va ularning xossalari tadqiq qilingan. TiO₂, ZnO, grafen va MWCNTs kabi nanonapolnitellarning qo‘llanilishi polimer qismlarning, mexanik va issiqlikka chidamliligini sezilarli oshirishi ko‘rsatilgan. Nanonapolnitellarning yuzasini modifikatsiyalash orqali uyg‘unlashuvi yaxshilanishi, shuningdek ularning UF nurlarni zararsizlantirishdagi samaradorligi bu boradagi izlanishlarning dolzarbligini belgilaydi. Materiallar va usullar. Ushbu tadqiqotda ultrabinafsha (UF) nurlanishga bardoshli polimer nanokompozitlar (PNK) ishlab chiqish va ularning quyosh energetikasi tizimlaridagi qo‘llanilish imkoniyatlari o‘rganildi. Nanokompozitlar tarkibiga TiO₂, ZnO, grafen, oksidlangan grafen (GO/rGO), ko‘p qatlamli uglerod nanonaychalar (MWCNTs), CeO₂, P-CNC hamda NaYF₄:Eu³⁺ kabi nanonapolnitellar kiritildi. Ushbu nanomateriallar turli polimer matritsalarda — epoksidli, poliuretan, PVAc va PVA asosida sintez qilindi. Natijalar. Tadqiqot natijalari shuni ko‘rsatdiki, TiO₂, ZnO, grafen va MWCNTs kabi nanonapolnitellar qo‘shilgan polimer nanokompozitlar UF-nurlanishga nisbatan barqarorlikni oshiradi, fotodestuktsiyani kamaytiradi hamda mexanik va termal xossalarni yaxshilaydi. Yuzani modifikatsiyalash orqali nanonapolnitellarning dispersiyasi va polimer bilan uyg‘unlashuvi yaxshilandi. Gibrid nanokompozitlar esa keng spektrli UF-himoya va yuqori chidamlilik ko‘rsatdi, bu ularni quyosh energetikasida qo‘llash uchun istiqbolli materiallarga aylantirdi. Xulosa. UF-barqaror nanonapolnitellar asosidagi polimer nanokompozitlar quyosh panellarining chidamliligi va samaradorligini oshiradi. Yuzani modifikatsiyalash ularning polimer bilan uyg‘unlashuvini yaxshilaydi. Aglomeratsiya, fotokatalitik faollik va ekologik xavflar esa asosiy muammolar bo‘lib qolmoqda. Kelgusida gibrid nanomateriallar va ilg‘or modellashtirish usullari orqali bu muammolarni samarali hal qilish mumkin.

MUALIFLAR

Teglar

# нанонаполнитель# nanofiller# ультрафиолетовое (УФ) излучение# полимерные нанокомпозиты (ПНК)# диоксид титана (TiO₂)# Ultrabinafsha (УФ-излучение)# Polimer nanokompozitlar (ПНК)# Nanoto‘ldiruvchi# Titandioksid (TiO₂)# ultraviolet (UV) radiation# polymer nanocomposites (PNCs)# titanium dioxide (TiO₂)

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