KIRISH: XXI asrda taโlim tizimining raqamlashtirilishi global jarayonga aylandi. Raqamli texnologiyalarni taโlim jarayoniga integratsiya qilish oโquvchilarning bilim olish samaradorligini oshirish, mustaqil fikrlashini rivojlantirish hamda zamonaviy kompetensiyalarni shakllantirishda muhim omil hisoblanadi. Ayniqsa, kimyo fanini oโqitishda murakkab molekulyar jarayonlar, laboratoriya tajribalari va abstrakt tushunchalarni vizuallashtirish zarurati raqamli vositalardan foydalanishni taqozo etadi. Kimyo oโqitish metodikasida raqamli taโlim texnologiyalaridan foydalanish oโquvchilarning nazariy bilimlarini amaliy koโnikmalar bilan integratsiyalash, virtual laboratoriyalar orqali tajribalarni xavfsiz va samarali bajarish hamda individual taโlim trayektoriyasini shakllantirish imkonini beradi. MAQSAD: mazkur tadqiqotning asosiy maqsadi โ kimyo oโqitish metodikasida raqamli taโlim texnologiyalaridan foydalanishning pedagogik imkoniyatlarini aniqlash, ularning oโquv jarayoniga taโsirini tahlil qilish hamda samaradorligini ilmiy asoslashdan iborat. Raqamli taโlim texnologiyalarining nazariy asoslarini oโrganish, kimyo fanini oโqitishda qoโllaniladigan raqamli platformalar va vositalarni tahlil qilish, virtual laboratoriya va simulyatsiyalarning didaktik imkoniyatlarini aniqlash, oโquvchilarning bilim, koโnikma va kompetensiyalariga taโsirini baholash. Kimyo fanining oโziga xosligi โ undagi abstrakt tushunchalar (atom tuzilishi, molekulyar orbital nazariyasi, kimyoviy bogโlanish turlari, kinetik va termodinamik jarayonlar) koโpincha oโquvchilar tomonidan tasavvur qilishda qiyinchilik tugโdiradi. Raqamli simulyatsiyalar, 3D modellashtirish, animatsiyalar va virtual laboratoriyalar ushbu murakkab jarayonlarni vizuallashtirish orqali kognitiv yuklamani kamaytiradi va tushunishni chuqurlashtiradi. Bu esa oโz navbatida bilimlarning barqaror va uzoq muddatli oโzlashtirilishiga xizmat qiladi. MATERIALLAR VA METODLAR: tadqiqot jarayonida quyidagi metodlardan foydalanildi: Nazariy tahlil metodi โ pedagogik va metodik adabiyotlarni oโrganish. Taqqoslash metodi โ anโanaviy va raqamli oโqitish usullarini qiyosiy tahlil qilish. Eksperimental metod โ raqamli vositalardan foydalangan holda dars jarayonini tashkil etish. Statistik tahlil โ oโquvchilarning oโzlashtirish koโrsatkichlarini aniqlash. Tajriba jarayonida quyidagi raqamli vositalardan foydalanildi: PhET Interactive Simulations โ kimyoviy reaksiyalar va molekulyar tuzilmani vizuallashtirish. Google Classroom โ topshiriqlarni boshqarish va baholash. ChemDraw โ kimyoviy formulalar va strukturalarni modellashtirish. Virtual laboratoriya dasturlari va interaktiv test platformalari. Eksperimental tadqiqot umumtaโlim maktabining 9โ10-sinf oโquvchilari oโrtasida olib borildi. Nazorat va tajriba guruhlari shakllantirilib, tajriba guruhida raqamli texnologiyalar asosida darslar tashkil etildi. MUHOKAMA VA NATIJALAR: tadqiqot natijalari shuni koโrsatdiki, raqamli taโlim texnologiyalaridan foydalanish oโquvchilarning mavzuni tushunish darajasini oshirdi, murakkab kimyoviy jarayonlarni vizual idrok etishni osonlashtirdi, mustaqil taโlim olish koโnikmalarini rivojlantirdi, motivatsiyani sezilarli darajada kuchaytirdi. Virtual laboratoriyalar orqali xavfli kimyoviy tajribalarni xavfsiz muhitda bajarish imkoniyati yaratildi. Shuningdek, differensial yondashuv asosida individual topshiriqlar berish orqali oโquvchilarning shaxsiy ehtiyojlari inobatga olindi. Bu esa raqamli texnologiyalarning didaktik samaradorligini tasdiqlaydi. Raqamli texnologiyalarni qoโllash natijasida quyidagi pedagogik samaralarga erishildi: Oโquvchilarning fan boโyicha motivatsiyasi va qiziqishi oshdi, mustaqil va tadqiqotga yoโnaltirilgan oโquv faoliyati shakllandi, tanqidiy va mantiqiy fikrlash koโnikmalari rivojlandi, axborot-kommunikatsion kompetensiyalar mustahkamlandi, differensial va individual yondashuv samaradorligi taโminlandi. Shuningdek, raqamli taโlim texnologiyalari inklyuziv taโlimni qoโllab-quvvatlash imkoniyatiga ega. Turli darajadagi oโquvchilar uchun moslashtirilgan topshiriqlar, multimediya materiallari va adaptiv test tizimlari har bir oโquvchining individual ehtiyojlarini inobatga olishga xizmat qiladi. Bu esa taโlimning insonparvarlik va shaxsga yoโnaltirilgan tamoyillarini amalda taโminlaydi. XULOSA: tadqiqot natijalari shuni koโrsatadiki, kimyo oโqitish metodikasida raqamli taโlim texnologiyalaridan samarali foydalanish taโlim jarayonining mazmuni, shakli va metodlarini tubdan takomillashtirish imkonini beradi. Raqamli vositalar nafaqat axborotni yetkazish vositasi, balki oโquvchilarning mustaqil bilim olish faoliyatini tashkil etuvchi, refleksiv va interaktiv oโquv muhitini yaratuvchi pedagogik instrument sifatida namoyon boโladi. Tadqiqot davomida qoโllanilgan interaktiv platformalar, xususan PhET Interactive Simulations va Google Classroom, oโquvchilarning dars jarayonidagi faolligini oshirish, tezkor qayta aloqa (feedback)ni taโminlash hamda baholash jarayonini shaffof va tizimli tashkil etishda samarali vosita ekanligi aniqlandi. Virtual laboratoriyalar esa moddiytexnik baza cheklangan sharoitlarda ham sifatli amaliy mashgโulotlarni tashkil etish imkonini beradi. Umuman olganda, kimyo oโqitish metodikasida raqamli taโlim texnologiyalaridan foydalanish taโlim sifatini oshirishning muhim strategik yoโnalishi hisoblanadi. U oโquvchilarning nazariy bilimlarini chuqurlashtirish, amaliy koโnikmalarini rivojlantirish hamda zamonaviy jamiyat talablariga mos kompetensiyalarni shakllantirishga xizmat qiladi. Kelgusida sunโiy intellekt, adaptiv oโquv platformalari va kengaytirilgan reallik (AR/VR) texnologiyalarini kimyo taโlimiga integratsiya qilish orqali fan oโqitishning samaradorligini yanada oshirish, oโquvchilarda ilmiy-tadqiqot kompetensiyalarini shakllantirish va innovatsion fikrlashni rivojlantirish mumkin. Shunday qilib, raqamli taโlim texnologiyalaridan oqilona va metodik jihatdan asoslangan foydalanish kimyo taโlimini modernizatsiya qilishning muhim omili sifatida namoyon boโladi
INTRODUCTION: in the 21st century, the digitalization of the education system has become a global process. The integration of digital technologies into the educational process is an important factor in increasing learning effectiveness, developing studentsโ independent thinking, and forming modern competencies. In particular, in teaching chemistry, the need to visualize complex molecular processes, laboratory experiments, and abstract concepts necessitates the active use of digital tools.The use of digital educational technologies in the methodology of teaching chemistry ensures the integration of theoretical knowledge with practical skills, enables safe and effective experimentation through virtual laboratories, and supports the formation of individual learning trajectories. AIM: the main purpose of this study is to identify the pedagogical opportunities for using digital educational technologies in the methodology of teaching chemistry, to analyze their impact on the educational process, and to scientifically substantiate their effectiveness. The objectives of the research include: studying the theoretical foundations of digital educational technologies, analyzing digital platforms and tools used in chemistry teaching, identifying the didactic potential of virtual laboratories and simulations, evaluating their impact on studentsโ knowledge, skills, and competencies. The specificity of chemistry lies in its abstract concepts (atomic structure, molecular orbital theory, types of chemical bonding, kinetic and thermodynamic processes), which often create difficulties for studentsโ understanding. Digital simulations, 3D modeling, animations, and virtual laboratories help visualize complex processes, reduce cognitive load, and deepen comprehension, thereby ensuring durable and long-term knowledge acquisition. MATERIALS AND METHODS: the following research methods were employed: theoretical analysis of pedagogical and methodological literature, comparative analysis of traditional and digital teaching methods, pedagogical experiment using digital tools in the learning process, statistical analysis of studentsโ academic performance.During the experimental work, the following digital tools were used: PhET Interactive Simulations โ for visualizing chemical reactions and molecular structures. Google Classroom โ for assignment management and assessment. ChemDraw โ for modeling chemical formulas and structures, virtual laboratory programs and interactive testing platforms. The experimental study was conducted among 9thโ10th grade students of a general secondary school. Control and experimental groups were formed, and in the experimental group, lessons were organized using digital technologies. DISCUSSION AND RESULTS: the results of the study demonstrated that the use of digital educational technologies: increased studentsโ level of understanding of the subject matter, facilitated the visual perception of complex chemical processes, developed independent learning skills, significantly enhanced learning motivation. Virtual laboratories provided opportunities to conduct potentially hazardous chemical experiments in a safe environment. Furthermore, the implementation of differentiated instruction through individualized tasks allowed consideration of studentsโ personal learning needs. The following pedagogical outcomes were achieved: increased motivation and interest in chemistry, formation of research-oriented learning activities, development of critical and logical thinking skills, strengthening of information and communication competencies, improved effectiveness of individualized and differentiated instruction. Digital educational technologies also support inclusive education. Adapted assignments, multimedia materials, and adaptive testing systems help address diverse learning needs and ensure the implementation of learner-centered and humanistic educational principles. CONCLUSION: the findings of the study indicate that the effective use of digital educational technologies in the methodology of teaching chemistry significantly improves the content, forms, and methods of instruction. Digital tools function not only as means of information delivery but also as pedagogical instruments that create an interactive, reflective, and research-oriented learning environment. The application of platforms such as PhET Interactive Simulations and Google Classroom proved effective in increasing classroom engagement, ensuring immediate feedback, and organizing transparent assessment processes. Virtual laboratories enable high-quality practical activities even in institutions with limited material and technical resources. Overall, the integration of digital educational technologies is a strategic direction for improving the quality of chemistry education. It promotes deeper theoretical understanding, enhances practical skills, and fosters competencies aligned with the demands of modern society. Future research perspectives include the integration of artificial intelligence, adaptive learning platforms, and augmented/virtual reality (AR/VR) technologies into chemistry education to further enhance instructional effectiveness, develop research competencies, and stimulate innovative thinking.