Hist. Geo Space Sci., 7, 73–77, 2016
www.hist-geo-space-sci.net/7/73/2016/
doi:10.5194/hgss-7-73-2016
© Author(s) 2016. CC Attribution 3.0 License.

After some 350 years – zero declination again in Paris

Mioara Mandea1 and Jean-Louis Le Mouël2
1CNES – Centre National d’Etudes Spatiales, 2 Place Maurice Quentin, 75039 Paris CEDEX 01, France

2Institut de Physique du Globe de Paris, Sorbonne Paris Cité, Univ. Paris Diderot, UMR7154 – CNRS,
1 rue Jussieu, 75238 Paris CEDEX 05, France

Correspondence to: Mioara Mandea (mioara.mandea@cnes.fr)

Received: 4 May 2016 – Revised: 1 August 2016 – Accepted: 15 August 2016 – Published: 14 September 2016

Abstract. The main part of the geomagnetic field – produced by a dynamo process in the Earth’s outer core –
changes its direction and strength in time, over timescales from months to centuries, even millennia. Its temporal
variations, known as secular variation and secular acceleration, are crucial ingredients for understanding the
physics of the deep Earth. Very long series of measurements therefore play an important role. Here, we provide
an updated series of geomagnetic declination in Paris, shortly after a very special occasion: its value has reached
zero after some 350 years of westerly values. Indeed, during October and November 2013, the declination at
the Chambon la Forêt geomagnetic observatory changed from westerly to easterly values, the agonic line then
passing through this place. We take this occasion to emphasize the importance of long series of continuous
measurements.

1 Introduction

The observed Earth’s magnetic field is the sum of several
internal and external contributions. The core field is more
than 1 order of magnitude stronger than the other contribu-
tions. This main part of the geomagnetic field is believed to
be generated by convective motions in the Earth’s iron-rich,
electrically conducting fluid outer core, by a process known
as the geodynamo. This geodynamo-generated field is named
the core field or main field, and its temporal variation, over
timescales from months to centuries, is named secular varia-
tion. The core field morphology at the Earth’s surface is rela-
tively simple, being dominated by a centered dipole-like field
which accounts for some 90 % of the total field. The litho-
spheric magnetic field, with its origin in the remanent and
induced magnetization of the crust and upper mantle, is not
only weaker and much less variable in time, but also of a
much smaller spatial scale when compared to the large-scale
core field. Its complexity comes from its geological and tec-
tonic origins. The Earth’s magnetic external fields stem from
the interaction of the solar wind with the magnetosphere, and
have as direct sources electric currents in the ionosphere and
magnetosphere. In addition, an external current system inde-
pendent of the solar wind–magnetosphere interaction exists,

the so-called quiet-time daily variation (Sq ) current. It has its
sources in the E-layer of the ionosphere and is driven by the
interaction between neutral winds and the local plasma. To
characterize these sources, measurements of the full vector
magnetic field are needed.

Observing the Earth’s magnetic field, since the time of the
first compasses, can be regarded as the oldest branch of mod-
ern geoscience and core physics. Nowadays, measuring the
magnetic field is more focussed on answering fundamental
questions about the planetary deep interior and its near-space
environment than on practical navigation matters. Since 1832
the Earth’s magnetic field direction and strength have been
continuously measured at various locations around the world,
and these data represent the most important body of measure-
ments to analyse the time evolution of the field morphology.
The geomagnetic observatory network is still a crucial source
of data in producing secular variation models in the past, and
now, together with satellite data, enables us to better describe
the internal and external field contributions.

In this paper, we first describe some key steps in measuring
the geomagnetic field, in France, and then we underline the
role of French magnetic observations in our knowledge of the
magnetic field.

Published by Copernicus Publications.



74 M. Mandea and J.-L. Le Mouël: Agone in Paris

2 Earth’s magnetic field: elements and beginnings
of observation

Measurements of the Earth’s magnetic field have been taken
over more than a century and a half on the ground (geo-
magnetic observatories and magnetic surveys) and over some
decades from space (low Earth orbit magnetic satellites).

The geomagnetic field, at any particular location and time,
is defined in terms of the three components (X, Y , and Z)
that together yield B, the full geomagnetic field vector. The
X, Y and Z elements are respectively the northward, east-
ward and downward components of the magnetic field. The
projection of B in the horizontal plane is noted as H and
its direction is the magnetic north. The horizontal angle be-
tween geographic north (X) and magnetic north (H ) is de-
noted D, the magnetic declination. A compass needle aligns
itself with H ; navigators therefore have to apply a correction
to their compass direction to regain the geographic direction.
Magnetic declination onboard ships has often been referred
to as magnetic variation; the needle is said to be west or east,
by a certain number of degrees, from the geographic north.
Last, the angle between H and B is called the magnetic incli-
nation or dip, and is denoted I (counted positive downwards).

The declination was the very first measured geomagnetic
field element, due to the early use of compasses. This instru-
ment has been known in Europe since the 12th century (e.g.
Merrill et al., 1996; Poirier and Le Mouël, 2013), but it is
not clear when the deviation of the needle from geographic
north, i.e. the declination, became known there. Probably it
was discovered independently in China.

At times when navigation became more important, the ge-
ographic north direction was linked to measurements of lat-
itude. Generally, the astrolabe was used for determining lat-
itude by measuring the angle between the horizon and Po-
laris (pole star). The position of Polaris might be located
within less than 1◦ from the north celestial pole. Apparently,
Roger Bacon was the first European to question the univer-
sality of the north–south directivity of the compass in 1266
(Merrill et al., 1996). In the same epoch, Petrus Peregri-
nus (Pierre Pelerin de Maricourt) conducted experiments on
magnetism and wrote the first treatise containing a detailed
discussion of a freely pivoting compass needle, a fundamen-
tal component of a dry compass. In his letter of 1269, Peregri-
nus explains how to identify the poles of a magnetized sphere
(terrella) and developed physical considerations about mag-
netism which would not be surpassed for some 300 years.

The discovery of declination in the European area has of-
ten been ascribed to Christopher Columbus in 1492, but there
is evidence from ancient sundials and compasses that dec-
lination had been known in Europe since at least the early
15th century. The oldest declination value given by a mag-
netic compass known to us is dated 1451. This instrument
was made by Peuerbach in Vienna. However, it is not clear
whether Peuerbach understood the deviation from the geo-
graphic north as purely a property of the magnetic field or as

one of the instrument. Three more compasses made by him
at the same location between 1451 and 1456 indicate differ-
ent declination values, although the discovery of change in
declination with time (i.e. secular variation) is generally as-
sumed to have taken place only in the early 17th century. It
was probably first noticed by Edmund Gunter in 1622 and
was fully described by Henry Gellibrand in 1634 (Chapman
and Bartels, 1962). Inclination was discovered in 1544 by
Georg Hartmann at Nuremberg, but was probably first mea-
sured correctly by Robert Norman in 1576 (Chapman and
Bartels, 1962).

There was considerable interest in explaining the direc-
tion of the magnetic field from the very beginning of the
17th century and onwards. William Gilbert published his
book De Magnete in 1600; he was the first to state that
the Earth behaves like a giant spherical magnet. He tried
to explain why a permanently magnetized compass needle
points towards the north. At the same time, Guillaume Le
Nautonier, a French cartographer, published in 1602–1604
Mecometrie de l’eymant c’est a dire la maniere de mesurer
les longitudes par moyen de l’eyment (Mandea and Mayaud,
2004). In his book, Le Nautonier shows a global map on
which the magnetic Equator and the magnetic poles (differ-
ent from the geographic ones) are indicated.

From the 17th century, declination and inclination mea-
surements started to be made on a more regular basis, giv-
ing the direction of the local geomagnetic vector, more or
less continuously, in different places around the globe. Rela-
tive measurements of the intensity (or the magnitude) of this
vector were made from the 1790s, by comparing the “swing
time” of a needle at the current location with that measured
at a reference site. It is only in 1825 and 1830 that De-
nis Poisson and Carl Friedrich Gauss developed along some-
what different lines the theory of an absolute measurement
of the magnetic field intensity, or strength. Simultaneously,
Gauss built a magnetometer capable of providing reliable
measurements of intensity. Gauss also established the first
magnetic observatory in Göttingen in 1832. Moreover, Gauss
and Wilhelm Weber founded the Magnetischer Verein (Mag-
netic Union) which, from 1834 to 1841, supported the growth
of a geomagnetic network through Europe; in this context,
magnetometers were installed at sites such as Berlin (1836),
Dublin (1838), Greenwich (1838), Prague (1839), and Mu-
nich (1841).

In France, following a long activity in the field of Earth’s
magnetism, the national magnetic observatory started its ac-
tivity in 1883. Before that date, declination and inclination
measurements had been taken since 1541 and 1676 respec-
tively. In the following, we focus on the Paris declination se-
ries only.

2.1 The Paris declination series

Early declination data can be found in published catalogues
or time series.

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M. Mandea and J.-L. Le Mouël: Agone in Paris 75

1500 1550 1600 1650 1700 1750 1800 1850 1900 1950 2000 2050
Time (years)

-20

-10

0

10

20

D
ec

in
at

io
n 

(d
eg

re
es

)

.

Figure 1. Paris declination series: annual means of declination cor-
rected and adjusted to Chambon la Forêt observatory (see Alexan-
drescu et al., 1996, for details)

For French catalogues, we can quote the Guil-
laume de Nautonier one (Mandea and Mayaud, 2004)
and the one published by Guillaume Delisle around 1705
(with more than 10 000 measurements, which can be found
in the Archives Nationales de Paris). Large efforts have been
made to improve the existing database of historical observa-
tions, including the navigation measurements (Jackson et al.,
2000; Jonkers et al., 2003).

Another category of sources is made of time series at a
given location; for a mere handful of sites, series with more
or less regular observations, spanning a few centuries, do ex-
ist. We can quote the time series of declination and some-
times inclination which have been compiled by (Malin and
Bullard, 1981), Cafarella et al. (1992), Barraclough (1995),
Alexandrescu et al. (1996) and Korte et al. (2009) for Lon-
don, Rome, Edinburgh, Paris and Munich respectively.

The Paris declination series starts as early as in the
16th century, with the first measurement performed by Kün-
stler Bellarmatus in 1541, giving a value of 7◦ E. From
that epoch until the official date of the establishment of the
Académie des Sciences in 1635 by Cardinal Richelieu, some
20 declination measurements were taken in the Paris area.
In 1667, the Académie des Sciences decided to build an as-
tronomical observatory in Paris and to start a programme of
declination measurements. Before the beginning of the con-
struction of the building, a first measurement was made on
21 June 1667, using a 5-inch needle. Subsequent measure-
ments were performed from 1667 onwards, sometimes con-
tinued as a family tradition (La Hire, Cassini, Maraldi – fa-
thers and sons). There are fewer measurements of inclination
than of declination at the Paris Observatory, owing to its late
discovery, but also because it was of less interest to naviga-
tors and was more difficult to measure accurately. More de-
tails about the observations of declination and inclination in
the Paris region are given in Alexandrescu et al. (1996).

Two epochs are important from a historical point of view,
separated by some 350 years, when declination reaches a null
value. The first one is around 1663 (considering the mean
of measurements in Paris and that in Issy-les-Moulineaux,
i.e. measurements which are not reduced to the present-day
location of the Chambon la Forêt observatory). From 1658
to 1667 we note eight values of declination around zero,
in 1658, 1660 (two measurements), 1663, 1664, 1666, and
1667 (two measurements) – see also Table 4 in Alexandrescu
et al. (1996). Among them three values of full 0◦ declina-
tion were observed at Paris, in 1658, 1660 and 1666, the
last two by Abbé Picard with a Picard needle of 5 inches.
In 1663 one more 0◦ measurement was made by Thévenot
at Issy-les-Moulineaux, some 3 km from the Paris observa-
tory. The ones for which the month and day are known are
on 21 June 1663 (0◦0′) and 21 June 1667 (−0◦15′), both
at summer solstice in the Northern Hemisphere. Let us un-
derline that all declination measurements made in the Paris
area (Issy-les-Moulineaux, Montsouris et Montmorency) and
in previous French magnetic observatories (Saint-Maur and
Val-Joyeux) are reduced to the current location of Chambon
la Forêt. In Alexandrescu et al. (1996) a detailed discussion
of the applied corrections is given. The annual means of dec-
lination (1541–2015), adjusted to the Chambon la Forêt ob-
servatory, are presented in Fig. 1.

The second period with a nearly null value of declination is
October–November 2013. Figure 2 shows the daily variation
of declination over the last 4 months of 2013, indicating a
change in the declination sign over October–November 2013.

To give a flavour of the early interest in variation of decli-
nation in Paris, and a possible approach to its estimation and
null values, we mention the note left by a French astronomer
who tried to represent the declination in Paris by a polyno-
mial. In Good et al. (1819) we can read that

M. Burckardt, an ingenious French astronomer, in-
vented a formula to represent the magnetic declina-
tion observed at Paris; thus if t denotes the number
of years from 1663, the tangent of the declination
is

0.449 sin(25′7′′)t +0.0425[sin(50′13′′)t]2

+0.0267[sin(1◦40′26′′)t]4

It follows from this formula that the eastern decli-
nation diminished from 1448, when it was max-
imum of 24◦10′, to 1660 or 1663, when it was
nothing at Paris. Reckoning an equal period back-
ward from 1448 gave 1233 for the earlier epoch
when there was no declination. A little before this
the invention of the mariner’s compass is generally
dated. According to Burckardt’s theorem, the max-
imum of the western declination at Paris will be in
the year 1831; thought it will not vary more than
20 min from that time to 1878. We mention these

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76 M. Mandea and J.-L. Le Mouël: Agone in Paris

Figure 2. Chambon la Forêt declination: daily means from
1 September 2013 to 31 December 2013.

as curious results of this astronomer’s formula; but
would by no means understood as affirming their
accuracy.

Burckardt’s estimates are quite interesting, considering the
time when he developed this approach. The values indicated
are indeed in good agreement with measurements in Paris at
the given epochs: indeed 0◦ declination in 1660 and 1663.
The maximum western declination was measured in 1796
(23◦45′ by Bouvard); over the period (1794–1831) the decli-
nation was around 22◦.

2.2 Declination series and the deep Earth’s interior

To analyse the temporal variations of the core magnetic field,
it is of course essential to have available long series of data.
To the slowly varying secular variation, we note additional
characteristics. One specific feature of the declination vari-
ation we are interested in are the so-called “geomagnetic
jerks”, defined as abrupt changes in the secular variation and
completed in a short time (see more details in Mandea et al.,
2010; Brown et al., 2013). The temporal resolution of annual
means is not adequate to get very accurate information on
the characteristics of these events; however, long declination
series such as the Paris one are the only sets of data which
can be used to detect these events prior to the 20th century.

To enhance rapid events, the first time derivative is com-
puted after applying an 11-year smoothing. The Paris dec-
lination curve clearly exhibits a number of changes in the
secular variation, as shown in Fig. 3. These changes are
more rounded as a result of the use of the filter; neverthe-
less, the geomagnetic jerks can still be clearly identified. The
figure clearly shows that, prior to the 20th century, one of
the most prominent geomagnetic jerks appears around 1870.
This event is also observed in four other European locations
(Alexandrescu et al., 1997) and has been recently detected
in the Munich curve (Korte et al., 2009), although a few

Figure 3. Paris declination series: secular variation of the declina-
tion computed with an 11-year smoothing filter.

years earlier. Going farther back in time, there is evidence
of changes in the secular variation trend, supported by mea-
surements around the epochs: 1600, 1665, 1700, 1730, 1750,
1760, 1770, 1810, 1870, 1890, and 1900. These dates are
close to those detected by Qamili et al. (2012): 1603, 1663,
1703, 1733, 1751, 1763, 1770, 1810, 1868–1870, 1888, and
1900, when analysing the temporal behaviour of the differ-
ence between predicted and actual geomagnetic field model
values for successive intervals from 1600 to 1980, based on
the Gufm1 geomagnetic model (Jackson et al., 2000). Let
us note that here we use the term “geomagnetic jerk” for all
these events; however, as noted by Mandea and Olsen (2009),
we must make a distinction between geomagnetic jerks and
rapid secular variation fluctuations.

Considering the origin of geomagnetic jerks in the fluid
outer core, their signature on the measured magnetic field at
the Earth’s surface may differ from place to place, which ex-
plains why there is no perfect temporal coincidence between
the different declination series.

3 Conclusions

In this paper we updated the Paris series with the last 20 years
of data, considering the event of zero declination through the
Chambon la Firêt observatory. This is not a unique incident in
Europe and an image of the declination observations at other
observatories and repeat stations to demonstrate the westerly
drift of the agonic line is provided by the declination map
of Europe for the epoch 2006, a product of the MagNetE
group (Duma et al., 2012). This map also includes the secular
variation estimates for Europe.

The evolution of the Earth’s magnetic field is intimately
linked to the history of the Earth, allowing insights into the
inner workings of our planet. Furthermore, the magnetic field
is an important component in shielding the Earth’s surface
from solar emissions. Hence, understanding its behaviour

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M. Mandea and J.-L. Le Mouël: Agone in Paris 77

is crucial, even if long-term accurate predictions are not
presently possible. It is inevitable that the geomagnetic field
will continue to exhibit secular variation at all timescales,
and its strength continues to change, producing changes in
the structure and dynamics of the magnetosphere. One can
expect a corresponding change in the geometry of the mag-
netosphere, which is controlled to first order by a balance be-
tween static pressure generated by the geomagnetic field and
the dynamic pressure of the solar wind. The possible conse-
quences for our planet are not yet completely acknowledged.

Understanding how the future geomagnetic field varies is
strongly dependent on how well we know the past magnetic
field. And for this, geomagnetic data, represented by the dec-
lination curve, remain a unique dataset.

4 Data availability

Data are available as following:

a. The annual means

– 1541–1994: from Alexandrescu et al. (1996);

– 1995–2014: from http://www.geomag.bgs.ac.uk/data_
service/data/annual_means.shtml.

The Paris declination series, reduced to the current location
of Chambon la Forêt observatory, is available on request.

b. The daily means

– from http://www.bcmt.fr/clf.html.

Author contributions. Mioara Mandea and Jean-Louis Le Mouël
contributed equally to this work, which is a legacy of the time they
spent in Chambon la Forêt observatory.

Acknowledgements. This “null-declination” event is dedicated
to so many observers, who, with constant patience, measured the
geomagnetic field over centuries. Special thanks are given to the
operators of Chambon la Forêt observatory. We gratefully acknowl-
edge constructive suggestions from two anonymous reviewers.

Edited by: M. G. Johnsen
Reviewed by: two anonymous referees

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	Abstract
	Introduction
	Earth's magnetic field: elements and beginnings of observation
	The Paris declination series
	Declination series and the deep Earth's interior

	Conclusions
	Data availability
	Author contributions
	Acknowledgements
	References