Wettability
alteration of the shale surface is a potential strategy
to address wellbore instability issues arising from shale hydration.
In this study, we have explored an oil-in-water (o/w) nanoemulsion,
in which soluble silicate (lithium silicate and potassium methyl silicate)
as the aqueous phase and organosilanes (3-methacryloxypropyltrimethoxysilane
(KH570) and n-octyltriethoxysilane (n-OTES)) as the
oil phase, as a shale inhibitor via forming a hydrophobic “artificial
borehole shield” in situ on shale surfaces to maintain wellbore
stability in high-temperature drilling operations. The shale dispersion
test showed the highest shale recovery of nanoemulsion was up to 106.4%
compared to that of water (20%), and recovered shale cuttings remained
at the original integrity after hot rolling at 180 °C, indicating
superior inhibition performance and resistance to elevated temperatures.
Moreover, recovered shale cuttings manifested water repellency upon
reimmersion in water, ascribed to the hydrophobic film, preventing
water from permeating into the shale. The results of the contact angle
measurement elucidated that the film wettability, from hydrophilic
to superhydrophobic (ranging from 9.6–154°), can be achieved
by altering the n-OTES-to-KH570 weight ratio from 0.2 to 2.25, and
the film with the highest hydrophobicity (154°) and the lowest
surface energy (3.17 mJ·m–2) can be obtained
at a ratio of 1.3. Scanning electron microscopy images demonstrated
that the superhydrophobic film was composed of tightly stacked reticulate
nanofilaments with a diameter of 7–17 nm and several micrometers
in length and overlapped well-distributed nanospheres with a diameter
of 30 nm. X-ray diffraction and Fourier transform infrared spectroscopy
confirmed the film was crystalline silica grafted with long-chain
alkylsiloxane. It is assumed that the unique micronanostructure combined
with the siloxane modification contributed to the hydrophobicity.
Consequently, this study provides a potential alternative solution
for wellbore stabilization in deep well drilling engineering by employing
nanoemulsion as a shale hydration inhibitor via forming a protective
film with controllable wettability. Furthermore, it can be conferred
a practical application due to easily available, less hazardous, and
cost-effective materials.
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