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Autori principali: Tripathy, Soumya Pratap, Saha, Sayan, Gupta, Saurabh Kumar, Das, Pallavee, Nayak, Binay Priyadarsan, Routray, Anup, Choudhary, Priya, V, Srihari, Maitra, Bitop, Reyaz, Ashna, Samant, Anushka, Sinha, Debopriya, Parida, Kritideepan, Das, Kuna, Sahoo, Abhijeet, Pal, Kunal, Ray, Sirsendu Sekhar
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.06467
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author Tripathy, Soumya Pratap
Saha, Sayan
Gupta, Saurabh Kumar
Das, Pallavee
Nayak, Binay Priyadarsan
Routray, Anup
Choudhary, Priya
V, Srihari
Maitra, Bitop
Reyaz, Ashna
Samant, Anushka
Sinha, Debopriya
Parida, Kritideepan
Das, Kuna
Sahoo, Abhijeet
Pal, Kunal
Ray, Sirsendu Sekhar
author_facet Tripathy, Soumya Pratap
Saha, Sayan
Gupta, Saurabh Kumar
Das, Pallavee
Nayak, Binay Priyadarsan
Routray, Anup
Choudhary, Priya
V, Srihari
Maitra, Bitop
Reyaz, Ashna
Samant, Anushka
Sinha, Debopriya
Parida, Kritideepan
Das, Kuna
Sahoo, Abhijeet
Pal, Kunal
Ray, Sirsendu Sekhar
contents Hydrothermal synthesis offers an economical and scalable way to produce nanodiamonds under relatively mild, low-pressure and low-temperature conditions. However,its sustainability and the detailed mechanisms behind diamond formation in such environments are still not fully understood. In this work, we designed ten hydrothermal synthesis protocols using different CHO-based molecular precursors containing COOH and OH groups, such as organic acids, polyols, sugars, and polysaccharides.The reactions were carried out at 190 degrees Centigrade in chlorinated, strongly alkaline aqueous solutions with alkali and alkaline-earth metal ions. Using high-resolution transmission electron microscopy and X-ray photoelectron spectroscopy, we confirmed the presence of diamond-specific lattice planes and sp3-hybridized carbon structures. Our results show that the type of precursor, its molecular size, and the ionic composition of the solution play key roles in determining the defect patterns and polymorph distribution in the resulting nanodiamonds. Atomic-scale imaging showed both coherent and incoherent transitions from graphite to diamond, along with gradual lattice compression and complex twinning patterns. These observations provide direct insight into how interfacial crystallography and defect dynamics drive diamond formation in aqueous systems. Overall, the study positions hydrothermal synthesis as a sustainable, chemistry-driven, and tunable approach for creating nanodiamonds tailored for applications in quantum technologies, biomedicine, catalysis, and advanced materials.
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id arxiv_https___arxiv_org_abs_2511_06467
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Facile Salt-Assisted Hydrothermal Synthesis of Nanodiamonds from CHO Precursors: Atomic-Scale Mechanistic Insights
Tripathy, Soumya Pratap
Saha, Sayan
Gupta, Saurabh Kumar
Das, Pallavee
Nayak, Binay Priyadarsan
Routray, Anup
Choudhary, Priya
V, Srihari
Maitra, Bitop
Reyaz, Ashna
Samant, Anushka
Sinha, Debopriya
Parida, Kritideepan
Das, Kuna
Sahoo, Abhijeet
Pal, Kunal
Ray, Sirsendu Sekhar
Mesoscale and Nanoscale Physics
Materials Science
Hydrothermal synthesis offers an economical and scalable way to produce nanodiamonds under relatively mild, low-pressure and low-temperature conditions. However,its sustainability and the detailed mechanisms behind diamond formation in such environments are still not fully understood. In this work, we designed ten hydrothermal synthesis protocols using different CHO-based molecular precursors containing COOH and OH groups, such as organic acids, polyols, sugars, and polysaccharides.The reactions were carried out at 190 degrees Centigrade in chlorinated, strongly alkaline aqueous solutions with alkali and alkaline-earth metal ions. Using high-resolution transmission electron microscopy and X-ray photoelectron spectroscopy, we confirmed the presence of diamond-specific lattice planes and sp3-hybridized carbon structures. Our results show that the type of precursor, its molecular size, and the ionic composition of the solution play key roles in determining the defect patterns and polymorph distribution in the resulting nanodiamonds. Atomic-scale imaging showed both coherent and incoherent transitions from graphite to diamond, along with gradual lattice compression and complex twinning patterns. These observations provide direct insight into how interfacial crystallography and defect dynamics drive diamond formation in aqueous systems. Overall, the study positions hydrothermal synthesis as a sustainable, chemistry-driven, and tunable approach for creating nanodiamonds tailored for applications in quantum technologies, biomedicine, catalysis, and advanced materials.
title Facile Salt-Assisted Hydrothermal Synthesis of Nanodiamonds from CHO Precursors: Atomic-Scale Mechanistic Insights
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2511.06467