Laser vibrational excitation of radicals to prevent crystallinity degradation caused by boron doping in diamond - Sorbonne Université
Journal Articles Science Advances Year : 2021

Laser vibrational excitation of radicals to prevent crystallinity degradation caused by boron doping in diamond

Abstract

Pursuing high-level doping without deteriorating crystallinity is prohibitively difficult but scientifically crucial to unleashing the hidden power of materials. This study demonstrates an effective route for maintaining lattice integrity during the combustion chemical vapor deposition of highly conductive boron-doped diamonds (BDDs) through laser vibrational excitation of a growth-critical radical, boron dihydride (BH2). The improved diamond crystallinity is attributed to a laser-enabled, thermal nonequilibrium suppression of the relative abundance of boron hydrides (BH), whose excessive presence induces boron segregation and disturbs the crystallization. The BDDs show a boron concentration of 4.3 × 1021 cm−3, a film resistivity of 28.1 milliohm·cm, and hole mobility of 55.6 cm2 V−1 s−1, outperforming a commercial BDD. The highly conductive and crystalline BDDs exhibit enhanced efficiency in sensing glucose, confirming the advantages of laser excitation in producing high-performance BDD sensors. Regaining crystallinity with laser excitation in doping process could remove the long-standing bottlenecks in semiconductor industry.
Fichier principal
Vignette du fichier
2021_adv_Diamond Electrochem_Loic.pdf (1.64 Mo) Télécharger le fichier
Origin Publication funded by an institution

Dates and versions

hal-03120211 , version 1 (25-01-2021)

Licence

Identifiers

Cite

Lisha Fan, Loic Constantin, Zhipeng Wu, Kayleigh A. Mcelveen, Xiu G. Chen, et al.. Laser vibrational excitation of radicals to prevent crystallinity degradation caused by boron doping in diamond. Science Advances , 2021, 7 (4), pp.eabc7547. ⟨10.1126/sciadv.abc7547⟩. ⟨hal-03120211⟩
74 View
35 Download

Altmetric

Share

More