Template Assembly of Spin Crossover One‐Dimensional Nanowires

Abstract: Spin crossover [1] (SCO) is an important example of molecular switching, [2] which can be realized by a wide variety of external stimuli. [3][4][5][6] Many applications have been explored, including sensor [7] and display [8] technologies, and data storage. [9] Much effort has been expended to develop the assembly of SCO complexes in materials and impressive results have been achieved with monodisperse nanoparticles, [10] nanocrystals, [11] thin films, [12] micro-and nanopatterned media, [13] Langmuir-Blo… Show more

“…This included the discovery of several new examples of SCO compounds [3,[9][10][11], the explanation of different types of SCO profiles [4,12] and the modification of SCO compounds to increase cooperativity and to direct their application into materials science [13]. Scientists have developed SCO networks [14][15][16], frameworks [17][18][19], gels [20][21][22], liquid crystals [23][24][25], nanoparticles and nanocrystals [26][27][28][29], nanowires [30], thin films [31][32][33] and have also applied patterning techniques to fabricate SCO devices [34]. Among complexes displaying SCO, [Fe(salEen) 2 ] + derivatives (salEen = N-ethyl-N-(2-aminoethyl)salicylaldiminate) are known to undergo thermal SCO sensitive to unit cell contents and supramolecular packing in the crystal [35].…”

Solution and solid state properties of Fe(III) complexes bearing N-ethyl-N-(2-aminoethyl)salicylaldiminate ligands

“…This included the discovery of several new examples of SCO compounds [3,[9][10][11], the explanation of different types of SCO profiles [4,12] and the modification of SCO compounds to increase cooperativity and to direct their application into materials science [13]. Scientists have developed SCO networks [14][15][16], frameworks [17][18][19], gels [20][21][22], liquid crystals [23][24][25], nanoparticles and nanocrystals [26][27][28][29], nanowires [30], thin films [31][32][33] and have also applied patterning techniques to fabricate SCO devices [34]. Among complexes displaying SCO, [Fe(salEen) 2 ] + derivatives (salEen = N-ethyl-N-(2-aminoethyl)salicylaldiminate) are known to undergo thermal SCO sensitive to unit cell contents and supramolecular packing in the crystal [35].…”

Solution and solid state properties of Fe(III) complexes bearing N-ethyl-N-(2-aminoethyl)salicylaldiminate ligands

“…The results of our studies into spin state choices with various metal-ligand combinations, including those reported here, are summarized in Table 1. LS, HS, SCO [15][16][17][18][19][20][21][22][23][24] LS, HS, SCO [4,24] LS [24][25][26] HS, SCO [24,25] a G.G. Morgan unpublished results. In both Fe(III) and Mn(III) complexes, three possible spin arrangements are possible in mononuclear complexes.…”

“…It has long been known that the R-Sal 2 -222 ligand family promotes SCO in iron(III) in addition to stabilizing both HS and LS complexes across a temperature range [15][16][17][18][19][20][21][22][23][24]. The Fe(III) R-Sal 2 -222 complexes have, in recent years, been extensively developed as new switchable materials due to the ease of derivatization which has led to the synthesis of ionic liquids [27], liquid crystals [28], Langmuir-Blodgett film formation with amphiphilic complexes [6,29], and preparation of templated nanowires [21]. We have also observed SCO in Fe(III) complexes from the R-Sal 2 -232 ligand type [4], but the majority of this class of compound remains HS from room temperature down to 5 K. In contrast, the R-Sal 2 -323 ligand type has been shown by Reedjik [26] to promote the LS state in iron (III).…”

Anion Influence on Spin State in Two Novel Fe(III) Compounds: [Fe(5F-sal2333)]X

“…[9] The C12 alkylated complex also allows for the formation of nanowires by template methods. [10] Here we report the physical and magnetic properties of the C18 alkylated complex (1) above 300 K where it exhibits a liquid crystalline phase and opening of a scan-rate dependent hysteresis window centered at 310 K.…”

Robust Room Temperature Hysteresis in an Fe^III Spin Crossover Metallomesogen