[EN] Today, I had the opportunity to give a talk at the Institute of the Chemistry of Plant Substances on "The Power of Computer Simulations to Understand the Molecular Level Mechanisms that Occur at the Cellular Level" and it was amazing! I'm thrilled to have received such a positive response from the audience, including researchers expressing their interest and asking many questions. After the talk, we discussed possible future collaboration with the lab members of Azimova Shaxnoz Sadikovna, who have extracted various compounds and tested them for cell viability. Some of the compounds showed promising results against cancer cell lines, but we still have a lot of work to do to reveal the exact mechanisms behind this. Hopefully, our collaboration will be fruitful!
#Science #CancerResearch #Collaboration
#Science #CancerResearch #Collaboration
📢 Exciting News! 📚 Our latest research paper in Nanomaterials has just been published! 🧪🔬
We delve into the fascinating world of 2H MoTe2 (molybdenum ditelluride) and its incredible potential. This material has garnered immense interest for its applications in superconductivity, nonvolatile memory, and semiconductors. It boasts a wide range of electrical properties that make it a true game-changer.
But what's even more intriguing is our exploration of MoTe2 in combination with hexagonal boron nitride (h-BN) within lateral heterostructures. This pairing offers a unique platform for crafting groundbreaking electronic devices.
In our study, we've successfully created highly conductive interfaces in crystalline ionic liquid-gated (ILG) field-effect transistors (FETs) featuring MoTe2/h-BN heterojunctions. 🌟
Our findings reveal an efficient carrier modulation with ILG FETs, showcasing double the performance compared to standard back gating. We've achieved remarkable unipolar p-type behavior and significantly boosted mobility in MoTe2/h-BN heterochannels, setting new mobility records. At 80 K, we observed hole and electron mobility values ranging from 345 cm² V⁻¹ s⁻¹ to 285 cm² V⁻¹ s⁻¹.
But what sets our study apart is the drastic reduction of Schottky barriers, which allowed us to unlock the intrinsic, heterointerface conduction in the channels. This presents exciting opportunities for developing phase change devices using atomically thin membranes.
I want to extend my heartfelt thanks to our brilliant team, including Saidov Kamoliddin, Odilkhuja Parpiev, and Olim Ruzimuradov and our collaborators at EMPA Swiss Federal Laboratories for Materials Science and Technology: Gurdial Blugan, Sena Yuzbasi, and Natalia Kovalska. https://www.mdpi.com/2079-4991/13/18/2559
Stay tuned for more groundbreaking discoveries! 🌐🔍 #Nanomaterials #Research #Science #Innovation
We delve into the fascinating world of 2H MoTe2 (molybdenum ditelluride) and its incredible potential. This material has garnered immense interest for its applications in superconductivity, nonvolatile memory, and semiconductors. It boasts a wide range of electrical properties that make it a true game-changer.
But what's even more intriguing is our exploration of MoTe2 in combination with hexagonal boron nitride (h-BN) within lateral heterostructures. This pairing offers a unique platform for crafting groundbreaking electronic devices.
In our study, we've successfully created highly conductive interfaces in crystalline ionic liquid-gated (ILG) field-effect transistors (FETs) featuring MoTe2/h-BN heterojunctions. 🌟
Our findings reveal an efficient carrier modulation with ILG FETs, showcasing double the performance compared to standard back gating. We've achieved remarkable unipolar p-type behavior and significantly boosted mobility in MoTe2/h-BN heterochannels, setting new mobility records. At 80 K, we observed hole and electron mobility values ranging from 345 cm² V⁻¹ s⁻¹ to 285 cm² V⁻¹ s⁻¹.
But what sets our study apart is the drastic reduction of Schottky barriers, which allowed us to unlock the intrinsic, heterointerface conduction in the channels. This presents exciting opportunities for developing phase change devices using atomically thin membranes.
I want to extend my heartfelt thanks to our brilliant team, including Saidov Kamoliddin, Odilkhuja Parpiev, and Olim Ruzimuradov and our collaborators at EMPA Swiss Federal Laboratories for Materials Science and Technology: Gurdial Blugan, Sena Yuzbasi, and Natalia Kovalska. https://www.mdpi.com/2079-4991/13/18/2559
Stay tuned for more groundbreaking discoveries! 🌐🔍 #Nanomaterials #Research #Science #Innovation
MDPI
Formation of Highly Conductive Interfaces in Crystalline Ionic Liquid-Gated Unipolar MoTe2/h-BN Field-Effect Transistor
2H MoTe2 (molybdenum ditelluride) has generated significant interest because of its superconducting, nonvolatile memory, and semiconducting of new materials, and it has a large range of electrical properties. The combination of transition metal dichalcogenides…
🎉 Navbatdagi ilmiy maqola! 🌟
PhD talabam Akbar Qodirovning ilmiy ishi Computational and Theoretical Chemistry ( IF-2.8 ) jurnalida chop etildi! 🧪📄
🔹 Tadqiqotda imidazoliy asosidagi ion suyuqliklar ([BMIM][SCN] va [BMIM][DCA]) tarkibida CO₂, H₂S va CH₄ gazlarining o‘zaro ta’siri molekulyar dinamika simulyatsiyalari yordamida chuqur o‘rganildi.
🔹 Natijalar shuni ko‘rsatadiki, CO₂ va H₂S ion suyuqlik yuzasida to‘planishga moyil bo‘lib, ayniqsa [BMIM][DCA] muhitida anion-gaz o‘zaro ta’siri kuchliroq ekanligi aniqlandi.
🔹 CH₄ esa zaif bog‘lanishlar hosil qilgani uchun suyuqlik tarkibiga kamroq kiradi va past eruvchanlikka ega.
🔹 Shuningdek, harorat omili gazlarning harakatchanligiga sezilarli darajada ta’sir qiladi.
🌍 Ushbu tadqiqot atmosferadagi xavfli gazlarni tutib qolish va global isish oqibatlarini kamaytirish uchun katta ahamiyatga ega. Ion suyuqliklar kelajakda bu gazlarni ushlab qolish va past bosim sharoitida xavfsiz saqlash uchun istiqbolli yechim bo‘lishi mumkin.
🙏 Shuningdek, ushbu tadqiqotga qo‘shgan qimmatli hissasi uchun Malayziyadagi Sunway universiteti professori Mohamed Kheireddine Arouaga ham samimiy minnatdorchilik bildiramiz!
Akbarni ushbu ulkan yutuq bilan tabriklayman! 👏 ✨
#Science #Research #ClimateChange #GasCapture #PhD #ionicliquids https://www.sciencedirect.com/science/article/pii/S2210271X25003822?via%3Dihub
PhD talabam Akbar Qodirovning ilmiy ishi Computational and Theoretical Chemistry ( IF-2.8 ) jurnalida chop etildi! 🧪📄
🔹 Tadqiqotda imidazoliy asosidagi ion suyuqliklar ([BMIM][SCN] va [BMIM][DCA]) tarkibida CO₂, H₂S va CH₄ gazlarining o‘zaro ta’siri molekulyar dinamika simulyatsiyalari yordamida chuqur o‘rganildi.
🔹 Natijalar shuni ko‘rsatadiki, CO₂ va H₂S ion suyuqlik yuzasida to‘planishga moyil bo‘lib, ayniqsa [BMIM][DCA] muhitida anion-gaz o‘zaro ta’siri kuchliroq ekanligi aniqlandi.
🔹 CH₄ esa zaif bog‘lanishlar hosil qilgani uchun suyuqlik tarkibiga kamroq kiradi va past eruvchanlikka ega.
🔹 Shuningdek, harorat omili gazlarning harakatchanligiga sezilarli darajada ta’sir qiladi.
🌍 Ushbu tadqiqot atmosferadagi xavfli gazlarni tutib qolish va global isish oqibatlarini kamaytirish uchun katta ahamiyatga ega. Ion suyuqliklar kelajakda bu gazlarni ushlab qolish va past bosim sharoitida xavfsiz saqlash uchun istiqbolli yechim bo‘lishi mumkin.
🙏 Shuningdek, ushbu tadqiqotga qo‘shgan qimmatli hissasi uchun Malayziyadagi Sunway universiteti professori Mohamed Kheireddine Arouaga ham samimiy minnatdorchilik bildiramiz!
Akbarni ushbu ulkan yutuq bilan tabriklayman! 👏 ✨
#Science #Research #ClimateChange #GasCapture #PhD #ionicliquids https://www.sciencedirect.com/science/article/pii/S2210271X25003822?via%3Dihub
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