Figure 5 - uploaded by Edgar Dörsam

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## Contexts in source publication

**Context 1**

... using a curve fitting method, the relational expression between x 1 and x can be obtained. The specimen used here is the normal copy paper (A4, 80 g/m 2 , average thickness d=84.7 μ m ). The curve fitting method used by Schaffrath is linear. A more complicate curve can be obtained by using more compression data and which can also be described as quadratic or cubic equation (Fig. 5). In Equ. 2, x 1 can be replaced with the relation expresses showed in Fig. 5, which leads to ...

**Context 2**

... using a curve fitting method, the relational expression between x 1 and x can be obtained. The specimen used here is the normal copy paper (A4, 80 g/m 2 , average thickness d=84.7 μ m ). The curve fitting method used by Schaffrath is linear. A more complicate curve can be obtained by using more compression data and which can also be described as quadratic or cubic equation (Fig. 5). In Equ. 2, x 1 can be replaced with the relation expresses showed in Fig. 5, which leads to ...

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We construct equisingular semiuniversal deformations of Legendrian curves.

## Citations

... The influence of surface roughness was also discussed in some papers, for example, the paper surface topography under compression was studied by Teleman, et al. (2004). According to the surface topography, the paper body was considered as being composed of two rough surfaces and an internal structure (Schaffrath and Göttsching, 1991;Chen, Neumann and Dörsam, 2014), the force-deformation relationship of paper was derived by using the Newton formula. ...

The mechanical behavior of paper materials under compression in the out-of-plane direction is highly nonlinear. If the influence of the surface topography is not taken into account, the stress-strain curve of paper materials in the loading process is a typical example of materials with J-shaped compressive curves. When compression is released, the stress-strain curve in the unloading process is also nonlinear. The main purpose of this paper is to establish a suitable mathematical model and actualize the description of the compression curve for paper and paper stacks. The loading and unloading nonlinearities of paper stress-strain relations can be approximated by using different equations. In this paper, the loading curve of paper is calculated by using the sextic polynomial equation and the unloading curve is described by using the modified exponential function. All the used coefficients for determining the functions are expressed as the functions of the stress at the start point of unloading. The compressive behavior of paper under some given forces are also calculated by using the identified equation and verified by means of the experimental data. For multiple sheets, it is assumed that when the force is the same, the deformation of the paper stack is directly proportional to the number of sheets. Based on this assumption, the force-deformation relation of the paper stack is derived. The comparative analysis of the experimental results demonstrates the effectiveness of the description model.

... The method can be summarized as the following three steps [6]: Enlarging and transferring the pictures: the surface of the specimen is magnified 25 times under a binocular microscope and captured by a camera with pixels of 1200×1600. With the aid of MATLAB 8.1 [7], all pictures can be transferred into binary images. ...

The surface topography of paper can range from very rough to extremely smooth, which has significant influences on mechanical properties of paper materials, especially the compressive behavior of paper in the out-of-plane direction. Normally, the stress-strain relations of most of the materials are calculated by using the nominal contact area, which is the whole area of the pressure head. The difference between actual and nominal contact area is ignored, but they are very different, and cannot be neglected in all situations. In this paper, a new experimental method for evaluating the relationship between the actual contact area and the normal load is proposed. A carbon paper is introduced in this method, and it is assumed that the measured contact areas between carbon paper and the actually tested paper are the same as the actual contact areas between the pressure head and the tested paper. Based on this assumption, the mechanical behavior of paper in the out-of-plane direction could be discussed by calculating the actual stress-strain relation and deducing the actual modulus. In addition, the force sensitivities of different carbon papers used for showing the actual contact areas were also compared. The calculation results show the crucial differences between the actual and nominal stress-stain behaviors.

... In order to achieve high-yield and high-performing systems on paper, various efforts on characterizing paper at macro-, micro-and nanoscales abide ( [7], [8], [9]). Besides, new paper types are being fabricated to conform to specialized engineering applications. ...

Driven by low-cost, resource abundance and distinct material properties, the
use of paper in electronics, optics and fluidics is under investigation.
Considering sensor systems based on magneto-resistance principles (anisotropic,
giant, tunnel) that are conventionally manufactured onto inorganic
semiconductor materials, we propose the use of paper substrates for cost
reduction purposes primarily. In particular, we studied the magneto-resistance
sensitivity of permalloy (Py:Ni81Fe19) onto paper substrates. In this work, we
report on our findings with clean room paper (80 g/m2, Rrms = 2.877 {\mu}m, 23%
surface porosity, latex impregnation, no embossed macro-structure). Here, the
Py:Ni81Fe19 coating was manufactured by means of a dry process, sputter
deposition, and spans an area of 10x10 mm2 and a thickness of 70 nm. Employing
a four-point-probe DC resistivity measurement setup, we investigated the change
of electrical resistance of Py:Ni81Fe19 under the presence of an oriented
external magnetic field. In particular, we investigate the magneto-resistive
change at two configurations: (1) the direction of the magnetic field is
parallel to the nominal induced electric current and (2) the direction of the
magnetic field is perpendicular to the electric current. Due to the stochastic
orientation of the fibers interplaying with the Py:Ni81Fe19 coating, the change
in magneto-resistance of the overall system at both measurement configurations
closely corresponds to the classical response of Py:Ni81Fe19 at a +/-45{\deg}
angle between the direction of electrical current and magnetic field. Using the
magneto-optic kerr effect, we observed the formation of domain walls at the
fiber bending locations. Future work will focus on the impact of layer
thickness, fiber dimensions and structure of magnetic coating on the
performance of the paper-based Py:Ni81Fe19 magneto-resistors.