[1] [1] CHEN C T, WU B C, JIANG A D, et al. A new-type ultraviolet SHG crystal—β-BaB2O4［J］. Science in China, Ser B, 1985, 28(3): 235-243.

[2] [2] FURUSAWA S I, CHIKAGAWA O, TANGE S, et al. Second harmonic generation in Li2B4O7［J］. Journal of the Physical Society of Japan, 1991, 60(8): 2691-2693.

[3] [3] CHEN C T, WU Y C, LI R K. The anionic group theory of the non-linear optical effect and its applications in the development of new high-quality NLO crystals in the borate series［J］. International Reviews in Physical Chemistry, 1989, 8(1): 65-91.

[4] [4] CHEN C T, LIU G Z. Recent advances in nonlinear optical and electrooptical materials［J］. Annual Review of Materials Science, 1986, 16, 203-243.

[5] [5] ZOU G H, YE N, HUANG L, et al. Alkaline-alkaline earth fluoride carbonate crystals ABCO3F (A=K, Rb, Cs; B=Ca, Sr, Ba) as nonlinear optical materials［J］. Journal of the American Chemical Society, 2011, 133(49): 20001-20007.

[6] [6] YANG G S, PENG G, YE N, et al. Structural modulation of anionic group architectures by cations to optimize SHG effects: a facile route to new NLO materials in the ATCO3F (A=K, Rb; T=Zn, Cd) series［J］. Chemistry of Materials, 2015, 27(21): 7520-7530.

[7] [7] ZOU G H, HUANG L, YE N, et al. CsPbCO3F: a strong second-harmonic generation material derived from enhancement via p-π interaction［J］. Journal of the American Chemical Society, 2013, 135(49): 18560-18566.

[8] [8] SONG Y X, LUO M, LIN D H, et al. π-conjugated trigonal planar［C(NH2)3］+ cationic group: a superior functional unit for ultraviolet nonlinear optical materials［J］. ACS Omega, 2021, 6(13): 9263-9268.

[9] [9] TRAN T T, HALASYAMANI P S, RONDINELLI J M. Role of acentric displacements on the crystal structure and second-harmonic generating properties of RbPbCO3F and CsPbCO3F［J］. Inorganic Chemistry, 2014, 53(12): 6241-6251.

[10] [10] LUO M, YE N, ZOU G H, et al. Na8Lu2(CO3)6F2 and Na3Lu(CO3)2F2: rare earth fluoride carbonates as deep-UV nonlinear optical materials［J］. Chemistry of Materials, 2013, 25(15): 3147-3153.

[11] [11] CAO L L, SONG Y X, PENG G, et al. Refractive index modulates second-harmonic responses in RE8O(CO3)3(OH)15X (RE=Y, Lu; X=Cl, Br): rare-earth halide carbonates as ultraviolet nonlinear optical materials［J］. Chemistry of Materials, 2019, 31(6): 2130-2137.

[12] [12] LUO M, LIN C S, ZOU G H, et al. Sodium-rare earth carbonates with shorite structure and large second harmonic generation response［J］. CrystEngComm, 2014, 16(21): 4414-4421.

[13] [13] LUO M, WANG G X, LIN C S, et al. Na4La2(CO3)5 and CsNa5Ca5(CO3)8: two new carbonates as UV nonlinear optical materials［J］. Inorganic Chemistry, 2014, 53(15): 8098-8104.

[14] [14] SONG Y X, LUO M, ZHAO D, et al. Explorations of new UV nonlinear optical materials in the Na2CO3-CaCO3 system［J］. Journal of Materials Chemistry C, 2017, 5(34): 8758-8764.

[16] [16] CHEN Q L, LUO M. Synthesis, crystal structure, and nonlinear optical properties of a new alkali and alkaline earth metal carbonate RbNa5Ca5(CO3)8［J］. Crystals, 2017, 7(1): 10.

[17] [17] LUO M, SONG Y X, LIN C S, et al. Molecular engineering as an approach to design a new beryllium-free fluoride carbonate as a deep-ultraviolet nonlinear optical material［J］. Chemistry of Materials, 2016, 28(7): 2301-2307.

[18] [18] PENG G, LIN C S, YE N. NaZnCO3(OH): a high-performance carbonate ultraviolet nonlinear optical crystal derived from KBe2BO3F2［J］. Journal of the American Chemical Society, 2020, 142(49): 20542-20546.

[19] [19] HELLWIG H, R&UUML S, HLE, et al. Polar potassium rare earth nitrates K2［RE(NO3)5 (H2O)2］(RE=La, Ce, Pr and Nd). II. Linear and nonlinear optical properties［J］. Journal of Applied Crystallography, 2000, 33(Pt 2): 380-386.

[20] [20] WANG C, LIU Q, Li Z. A new nonlinear optical crystal: Bi2O2(OH)(NO3)［J］. Crystal Research and Technology, 2011, 46(7): 655-658.

[21] [21] WANG G X, LUO M, LIN C S, et al. Lanthanum lead oxide hydroxide nitrates with a nonlinear optical effect［J］. Inorganic Chemistry, 2014, 53(23): 12584-12589.

[22] [22] WANG G X, LUO M, YE N, et al. Series of lead oxide hydroxide nitrates obtained by adjusting the pH values of the reaction systems［J］. Inorganic Chemistry, 2014, 53(10): 5222-5228.

[23] [23] PENG G, YANG Y, TANG Y H, et al. Collaborative enhancement from Pb2+ and F- in Pb2(NO3)2(H2O)F2 generates the largest second harmonic generation effect among nitrates［J］. Chemical Communications, 2017, 53(68): 9398-9401.

[24] [24] SONG Y X, LUO M, LIN C S, et al. Structural modulation of nitrate group with cations to affect SHG responses in RE(OH)2NO3 (RE=La, Y, and Gd): new polar materials with large NLO effect after adjusting pH values of reaction systems［J］. Chemistry of Materials, 2017, 29: 903.

[25] [25] LUO M, LIN C S, LIN D H, et al. Rational design of the metal-free KBe2BO3F2·(KBBF) family member C(NH2)3SO3F with ultraviolet optical nonlinearity［J］. Angewandte Chemie International Edition, 2020, 59(37): 15978-15981.

[26] [26] WEN X, LIN C S, LUO M, et al. C(NH2)3］3PO4·2H2O: a new metal-free ultraviolet nonlinear optical phosphate with large birefringence and second-harmonic generation response［J］. Science China Materials, 2021, 64(8): 2008-2016.

[27] [27] KALMUTZKI M, STRBELE M, WACKENHUT F, et al. Synthesis, structure, and frequency-doubling effect of calcium cyanurate［J］. Angewandte Chemie, 2014, 53(51): 14260-14263.

[28] [28] LIN D H, LUO M, LIN C S, et al. KLi(HC3N3O3)·2H2O: solvent-drop grinding method toward the hydro-isocyanurate nonlinear optical crystal［J］. Journal of the American Chemical Society, 2019, 141(8): 3390-3394.

[29] [29] XU F, LI B, TAO Y, et al. Crystal growth and physical properties of the nonlinear optical crystal KLi(HC3N3O3)·2H2O［J］. Crystal Growth & Design, 2022, 22(5): 3471-3478.

[30] [30] LIN D H, LUO M, LIN C S, et al. An optimal arrangement of (H2C4N2O3)2-groups in the first non-centrosymmetric alkali barbiturate Li2(H2C4N2O3)·2H2O inducing a giant second harmonic generation response and a striking birefringence［J］. Crystal Growth & Design, 2020, 20(8): 4904-4908.

[31] [31] XU Y Y, LIN C S, LIN D H, et al. Explorations of second-order nonlinear optical materials in the alkaline earth barbiturate system: noncentrosymmetric Ca(H3C4N2O3)2·H2O and centrosymmetric Sr(H5C8N4O5)2·4H2O［J］. Inorganic Chemistry, 2020, 59(21): 15962-15968.