Embedded thin film fabrication via glass welding by an ultrafast laser

Figures & data

Figure 1. Experimental setup.

Table 1. The characterizations and corresponding values of JGS2 substrate before welding.

Serial number	Characterization	Value
1	Sio2 content	>99.95%
2	Zn content	0%
3	Visible light transmission (1064 nm)	>93%
4	Surface flatness	6 μm
5	Bonding strength	0MPa

Figure 2. Schematic of the welding process of an embedded thin film. (a) Two-dimensional diagram. (b) three-dimensional model.

Figure 3. SEM Image of the embedded thin film (one of the glass substrates was randomly selected).

Figure 4. Detailed SEM image of the embedded thin film.

Table 2. Welding effect based on different parameters.

Serial number	Average power(W)	Line spacing of welding route(mm)	welding speed(mm/s)	welding successfully or failure/thin-film
1	17.5	0.05	70	X
2	18.5	0.05	70	X
3	20	0.05	70	$\surd \left(goodthin-film\right)$
4	20	0.05	80	X
5	20	0.05	90	X
6	20	0.05	60	X
7	20	0.05	50	X
8	20	0.01	70	$\surd (betterthin-film)$
9	20	0.1	70	$\surd \left(badthin-film\right)$
10	20	1	70	$\surd \left(withoutthin-film\right)$
11	21.5	0.05	70	X
12	22.5	0.05	70	X
13	25	0.05	70	X

Figure 5. Full cross section of the embedded thin film.

Figure 6. Zinc content and distribution in the embedded thin film.

Figure 7. The comparison of glass substrates before and after welding. (a) Two glass substrates with evenly distributed ZnO powders before welding. (b) Two glass substrates with an embedded thin film after welding.

Table 3. The characterizations and corresponding values of JGS2 substrate after welding.

Serial number	Characterization	Value
1	Sio2 content	<98.86%
2	Zn content	>1.09%
3	Visible light transmission (1064 nm)	opaque
4	Surface flatness	7–9 μm
5	Bonding strength	12.22MPa