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Federal Reserve Bank of Chicago

Measuring Interest Rate Risk in the Life
Insurance Sector: the U.S. and the U.K.
Daniel Hartley, Anna Paulson, and
Richard J. Rosen

January 2016
WP 2016-02

Measuring Interest Rate Risk in the Life Insurance Sector: the U.S. and the U.K.*
Daniel Hartley
Anna Paulson
Richard J. Rosen
Federal Reserve Bank of Chicago
January 2016

Abstract
We use a two factor model of life insurer stock returns to measure interest rate risk at U.S. and
U.K. insurers. Our estimates show that interest rate risk among U.S. life insurers increased as
interest rates decreased to historically low levels in recent years. For life insurers in the U.K., in
contrast, interest rate risk remained low during this time, roughly unchanged from what it was in
the period prior to the financial crisis when long-term interest rates were in their usual historical
ranges. We attribute these differences to the heavier use of products that combine guarantees
with options for policyholders to adjust their behavior by U.S. life insurers relative to their U.K.
counterparts.
Keywords: Insurance companies, interest rate risk, life insurance, low interest rates

*We are grateful for helpful comments from Thomas King, Ralph Koijen, Zain Mohey-Deen, Moto Yogo
and the participants at The Economics, Regulation and Systemic Risk of Insurance Markets conference at
the London Business School, and for excellent research assistance from Tyna Eloundou and Teddy
Kalambokidis. The views expressed in this paper are our own and do not necessarily reflect those of the
Federal Reserve Bank of Chicago or the Board of Governors of the Federal Reserve System.
Corresponding author: Richard J. Rosen, richard.rosen@chi.frb.org, +1 (312) 322-6368.

1. Introduction
Interest rates have decreased to levels at or near historical lows in many countries around
the world including the U.S., the U.K. and continental Europe in recent years (see Figure 1). The
interest rate environment is important for life insurance firms because they typically use fixedincome markets to hedge the implicit or explicit return that they promise on core products – life
insurance policies and annuities. However, hedging interest rate risk for insurance policies and
annuities is not always straightforward. Many life insurers use hedging strategies such as
duration matching. These techniques generally do a good job of hedging interest rate risk when
rates are relatively stable and near historical averages, as they were in the early part of the
century in the United States and Europe. But, these strategies may not do as well when there is a
large change in interest rates such as the sustained decrease in rates that occurred after the 2008
financial crisis. In this paper, we measure the interest rate risk exposure of insurers in the U.S.,
the U.K., and continental Europe during the rate decrease and the subsequent period when
interest rates have continued to be very low by historical standards. We compare these measures
to measures of their interest rate risk exposure during the more normal interest rate period prior
to the financial crisis.
Life insurance firms sell products that promise payments in the future. Most products
sold by life insurers offer some combination of protection – either from loss of life (a life
insurance policy) or from outliving financial resources (an annuity) – and savings (often in a taxadvantaged way). All of these products involve policyholders paying in funds before, often well
before, insurers make any payments. This pattern exposes insurers to interest rate risk.
Exposure to interest rate risk varies with the features of particular products. We exploit
differences in the features of life insurance products across countries to examine the importance
of product features in determining life insurance exposure to interest rate risk.
One important dimension across which life insurance products differ is the degree to
which policyholders are guaranteed minimum returns on the savings elements of their policies.
In many countries such as the United States, annuities and other savings products offered by life
insurers are generally sold with minimum rate guarantees. So, for example, a policyholder might
be offered an annuity that guarantees a minimum return of 4% per year on all invested funds. In
other countries such as the United Kingdom, it is more common for the return on savings

1

elements in life insurance products to be a function of the return insurers earn on investments. 1
All else equal, products with guarantees are more exposed to interest rate risk than products that
with no guarantees.
Of course, all else is not equal. Life insurers can choose assets and use derivatives to
hedge the interest rate risk introduced by their liabilities. 2 The task of asset-liability
management is an important function at these firms. Insurers seek to invest in a way that ensures
that funds are available when they are due to policyholders. This generally leads life insurers to
invest heavily in fixed-income assets such as bonds. For example, according to data from SNL
Financial, over 87% of Prudential Financial’s investment assets were fixed income securities in
2014. Life insurers may choose assets to back their liabilities with interest rate risk in mind but
may choose not to—or may not be able to—completely balance the interest rate sensitivity of
their assets and liabilities. This conflict arises in part because assets with maturities as long as
those of some insurance liabilities are not always available. This often leads life insurers to
manage interest rate risk through approximate hedges such as duration matching. Duration
matching is effective for hedging small changes in interest rates, but can leave insurers unhedged
if interest rates move substantially (the so-called convexity problem).
Another important factor in evaluating interest rate risk is that life insurers can be
exposed to interest rate risk through the behavior of policyholders, especially through products
with guaranteed returns. Some insurance products offer policyholders the option to contribute
additional funds at their discretion (possibly only in specific circumstances) or to close out a
contract in return for a predetermined payment (in the latter case, the policyholder is said to
surrender the contract). When interest rates change, it is more likely that policyholders will act
on these options. For example, they may contribute more to an annuity with a high guaranteed
return when interest rates are low or surrender an annuity with a low return guarantee when
interest rates rise significantly. The key is that the combined effect of guarantees and
policyholder behavior can make hedging interest rate risk much more complex. This can lead life
insurers to leave themselves more exposed to changes in interest rates that are large enough to
1

Moody’s (2015) estimates that guaranteed products account for between 60% and 80% of U.S. life insurance
industry reserves and for 40% of U.K. life insurance reserves. However, many of the guarantees in the U.K. are
made at interest rates well below market rates at the time they are granted and essentially provide protection against
a loss on the policyholders’ investments (guarantees are made at 0 – 1% even when market interest rates are much
higher).
2
See Berends and King (2015) for a discussion of derivatives usage by U.S. life insurers.
2

substantially affect policyholder behavior. We examine whether differences in guarantees and
policyholder behavior across countries are related to the interest rate sensitivity of life insurers in
those countries.
We propose a measure of the residual interest rate risk that life insurers retain after taking
into account their efforts to reduce interest rate risk through asset liability management and other
hedging activities. We then examine how this measure has changed in recent years as interest
rates decreased and then remained low. The evolution of interest rates has been similar in many
countries, including in the U.S. and the U.K., which are the focus of this study (see Figure 1).
Despite being exposed to similar changes in interest rates, the residual exposure of life insurers
to interest rate risk may differ by country due to differences in the characteristics of products
sold across countries. The primary focus of this paper is a comparison of interest rate risk for
insurance firms in the U.S. and the U.K. We compare the residual exposure to interest rate risk
for firms in the U.S. to that of firms in the U.K. In the U.S., guarantees and policyholder options
are common and in the U.K. they are not, so our study design helps to shed light on the role of
guarantees in generating interest rate risk. 3
There are two potential approaches to measuring the interest rate exposure of life
insurance firms: bottom-up and top-down. A bottom-up measure would make use of detailed
data on insurance assets and liabilities and would involve estimating the interest rate risk of each
on an individual- or product-basis. This approach is impractical for us as it would require
detailed information that is not publicly available. However, stock analysts and ratings agencies
pay close attention to the product mix of insurers and interest rate guarantees of the products that
insurers sell. Thus, the interest rate sensitivity of an insurer’s liabilities is likely to be factored
into the price of their stock. For these reasons, we use a top-down approach that relies on the
sensitivity of life insurer stock returns to interest rates.
The top-down measure of interest rate exposure that we use is based on a two factor
market model of insurer stock returns. We include a broad stock market return factor to control
for changes in the overall economy as well as an interest rate factor. The coefficient on the
interest rate factor, which is allowed to vary through time, is our measure of the exposure to
interest rate risk.
3

Many annuities in the U.K. were compulsory for our sample period. Policyholders in the U.K. had little optionality
in their investments (Oliver Wyman, 2014) and surrenders are not possible for U.K. annuities (Geneva Association,
2012).
3

In order to see how interest rate sensitivity is related to the product-specific features of
life insurance and annuities, we compare the U.S., where many insurance products have
guarantees and some policyholder flexibility, to the U.K., where the combination of both
guarantees and policyholder options is much less common. We examine residual interest rate
risk exposure for insurers in the two countries along multiple dimensions. However, we are
particularly interested in the period beginning in July 2010. This period was after the financial
crisis and was when long-term interest rates decreased significantly before leveling off at a
historically low level. We refer to this as the low-rate period. During this period, we find that
the stock prices of U.K. life insurers were not significantly impacted by small changes in interest
rates, suggesting they were not particularly exposed to interest rate risk. Over the same time
period, U.S life insurers’ stock prices increased significantly when interest rates increased,
implying that U.S. life insurers faced considerable interest rate risk and that, in particular, the
duration of their liabilities exceeded that of their assets. We interpret this finding to mean that
the guarantees and policyholder options that are common to U.S. life insurance products exposed
them to considerable interest rate risk in the period following the financial crisis when interest
rates fell significantly and stayed low.
We test our interpretation and ensure these results are not due to omitted factors, through
a two-stage differences-in-differences test for both U.S. and U.K firms.

First, we compare the

low-rate period to a period when interest rates were ‘normal,’ that is to say within historical
norms. We define the normal rate period as beginning in 2002 and continuing through June
2007 (ending before the financial crisis). During this period, we find that small changes in
interest rates had no effect on life insurer stock prices in either the U.K. or U.S. Next, we
compare changes in interest rate sensitivity between the normal period and the low-rate period
for the two countries. We find that interest rate risk increased for U.S. life insurers between the
normal period and the low-rate period. But, there was no change in interest rate risk for U.K life
insurers between the same two time periods.
The second stage of the difference-in-difference analysis focuses on ensuring that the
differences that we observe between the U.S. and the U.K are due to differences in the life
insurance industry in the two countries. In this stage, we compare the changes in interest rate
risk exposure for life insurers in the two countries to changes in interest rate risk exposure for a
control group of firms. Specifically, we examine the interest rate risk for non-life insurers
4

(primarily property and casualty insurance firms) during the ‘normal’ rate period and the ‘lowrate’ period for in the U.S. and the U.K. Non-life insurers typically have liabilities of a much
shorter duration (auto or business continuity insurance, for example) and their products do not
have a savings element or a guaranteed return. Consistent with intuition, we find that non-life
insurers’ stock prices had little reaction to small interest rate changes in either the low-rate
period or the normal-rate period for either U.K. or U.S. insurers. Thus, the second stage of the
analysis shows that life insurers in the U.S. had an increase in interest rate risk in the low-rate
period relative to the normal rate period when compared to non-life insurers in the U.S. while
there was no such pattern in the U.K.
As a robustness check, we conduct a similar analysis using a sample of large insurers
based in continental Europe. This analysis is complicated by two factors: First, there is no clear
way to assess the prevalence of a combination of guarantees and policyholder options in life
insurance products for most European countries. Second, large continental European insurance
firms often have significant cross border activities. To address the second factor, we evaluate
insurers by the source country for premiums, not where the firm is headquartered. Then, we split
our sample based on the share of life insurance premiums that each insurer earns from Germany.
While there is not a perfect consensus regarding the degree to which the life insurance products
of each European country combine guarantees and options in a manner similar to U.S. products,
there is broad agreement that the products offered in Germany are more similar to those in the
U.S. than to those in the U.K. Consistent with the results in our main analysis, we find that life
insurers with larger share of German premiums experienced an increase in interest rate risk
during the low-rate period relative to life insurers with a smaller share of premiums from
Germany, although the difference is statistically significant for only a portion of the low-rate
period.
As a further check that our top-down procedure captures residual interest rate risk, we
compare the residual interest rate risk from our model to country-level bottom-up measures
derived from the European Insurance and Occupational Pensions Authority (EIOPA) ‘low for
long’ stress scenario for European countries. Despite large differences between our approach and
the EIOPA procedure, we find that our measure of risk is correlated with interest rate risk
estimated from the EIOPA results.

5

Our overall findings are consistent with life insurance firms in the U.S. retaining a
portion of the interest rate risk associated with interest rate guarantees and policyholder options.
One interpretation is that during the normal interest rate period insurers successfully hedged
themselves against small movements in interest rates using duration matching or something
similar. They did not, however, hedge themselves against the effects of rate guarantees and the
exercise of policyholder options under the low-probability scenario that interest rates decreased
significantly. When this event came to pass, policyholders with guarantees elected to keep their
policies longer and, when possible, increased their savings rate. Keeping policies longer
effectively delayed the expected pattern of payments from the insurer to policyholders and forces
the insurer to pay an above-market interest rate during this extra time. The effect of this was to
increase the duration of insurers’ liabilities by more than the amount of a fixed-rate coupon bond
with the same duration prior to the rate drop. If insurers had assets (which, recall, are primarily
fixed-rate coupon bonds) of the same duration as the liabilities before interest rates decreased,
this would leave them unhedged.
In contrast to the U.S., in the U.K., where insurers have more flexibility to pass lower
returns on to policyholders and where policyholders have much less flexibility to change
investments or surrender, insurers were less exposed to the effect of lower interest rates. Our
results suggest that these product features allowed U.K. life insurers to remain largely hedged to
interest changes across both the normal and the low rate period.
We consider two potential alternative explanations for why the sensitivity of life insurers’
stock prices to interest rates might increase when interest rates decrease significantly. The first is
that duration matching is only an approximate hedge against interest rate risk (the convexity
problem). Given life insurance balance sheets, if insurers do not adjust their asset portfolios as
rates fall, the duration of liabilities will increase faster than the duration of assets. 4 This is true
even when there are no guarantees and policyholder behavior does not change. Convexity is an
issue in both the U.S. and the U.K., yet we find that the sensitivity of life insurers’ stock prices to
interest rates only increased in the U.S. and not in the U.K. This suggests that convexity from
duration matching is not the major driver of our results, perhaps because insurers dynamically
adjusted their portfolios as interest rates decreased.

4

This is true because of the structure of assets and liabilities in life insurers’ portfolios. See Section 4 for more
details.
6

A second potential explanation for why a top-down measure of interest rate sensitivity
based on stock prices could be larger in the low-rate period is that some insurance products can
be difficult to sell at a profit when interest rates are very low. Since insurers’ profit is equal to
the return they earn on assets plus payments from policyholders less payments to policyholders,
a decrease in interest rates lowers asset returns and induces insurers to either increase prices or
reduce benefits, making insurance products generally less attractive to customers. Lower
demand will show up in insurer stock prices and hence impact our top-down measure of interest
rate risk. This effect is likely to impact both U.S. and U.K. life insurers, so it may not seem like
an obvious explanation for our findings. However, the combination of guarantees and
policyholder options means that insurers have to price in the ability of policyholders to switch
out of a product if interest rates rise significantly. This may make it relatively more difficult for
life insurers to sell certain product classes in the U.S. relative to those in the U.K. To the extent
that this is true, it reinforces our interpretation that the combination of guarantees and
policyholder options left U.S. insurers relatively more exposed to residual interest rate risk.
The rest of the paper is organized as follows. Section 2 describes our top-down measure
of interest rate risk. Section 3 describes the data we use in the analysis. Our main hypotheses
and findings for the U.S. and the U.K. are described in Section 4. In section 5, we present a
robustness check of our results using a sample of European insurers. Section 6 concludes.

2. Measuring exposure to interest rate changes
To assess how the interest rate environment affects the exposure of insurance firms to
interest rate changes, we use a top-down model that relates stock returns to changes in bond
prices. Specifically, we estimate a two-factor model of insurer stock returns where the factors
are a broad market factor and a government bond factor. Previous studies of the sensitivity of
life insurance firms to interest rate risk have used a similar approach to measure the correlation
between insurers’ stocks returns and interest rate changes (Brewer, Mondschean, and Strahan
1993; Brewer et al. 2007; Carson, Elyasiani, and Mansur 2008; Berends et al. 2013). In contrast
to Fama and French (1992; 1993) we retain the panel structure of the data rather than forming
portfolios of stock returns. The results are robust to using portfolios. The benefit of retaining
the full information contained in the panel of returns is shown in Ang, Liu, and Schwarz (2010)
in the context of testing factor models. The panel data approach allows us to implement
7

difference-in-differences estimates that exploit the full variation in the share of insurance
premiums that are due to life insurance products.
We are interested in the coefficient on the government bond return but we include the
stock market index to control for common factors such as macroeconomic shocks that influence
all equity prices. Thus, our two-factor model gauges the extent to which changes in the ten-year
rate that are uncorrelated with moves in the overall market are associated with changes in
insurance firm stock prices. For a panel of insurer stocks indexed by i, we estimate:
Ri, t = α + βRm, t + γR10, t + εi ,t ,

(1)

where
Ri, t = the return (including dividends) on stock i in week t,
Rm, t = the return on a value-weighted stock market portfolio in week t,
R10, t = the return on a government (either U.S. or U.K.) bond with a ten-year constant
maturity in week t, and
ε i,t is a mean zero error term.
We estimate the model using weekly (Friday through Friday) data and value weight the
regressions using the stock market capitalization of insurers as of the year-end prior to each
observation as the weight. 5
Since we are interested in how the interest rate sensitivity of insurance firms has changed
over time, we estimate the coefficients using a window consisting of two years of weekly return
data. We re-estimate the coefficients on a rolling basis, sliding the window forward by one week
each time. In choosing a window of two years, we are trading off having a long enough window
to deliver enough data for estimation with having a short enough window so that the business
environment and interest rates can be considered reasonably stable during each window.
Assuming that market expectations for future interest rate movements can be described
by a random walk at short horizons (such as a week), we can interpret, γ, the coefficient on the
return on the ten-year interest rate, as a measure of how news about changes in interest rates are
capitalized into the stock prices of insurance firms. If γ is different from zero, the market
perceives there to some interest rate sensitivity in the insurance firms’ profits. For example, if γ
5

We have also estimated the model in terms of excess returns by subtracting the 3-month government bond return
from each of the total returns as in Fama-French (1992, 1993). However, we do not have the German government
bond series for the first few years of our sample period. Still, the results are almost exactly the same in the pre- and
post- crisis periods for both methods.
8

is negative, the market believes that the insurance firms’ future profits will increase when returns
on the ten-year government bond decrease, that is, when interest rates increase.

3. Data
We examine data on insurance firm stock returns from January 2002 through July 2015. 6
Our objective is to determine whether interest sensitivity is different in the recent period of
decreasing and low interest rates than it would be in a period of ‘normal’ interest rates. It would
be natural to compare the low-rate period to the years immediately preceding it, but that period
included the financial crisis when interest rates and stock returns were likely moving for reasons
that are outside the focus of the paper. For that reason, we define the time period immediately
before the financial crisis (which we assumes starts in August 2007), from January 2002 to June
2007 as the normal period.
The sample of insurance firms includes all publicly-traded insurers based in the U.S. or
the U.K. that are included in the SNL Financial dataset and that have stock price data extending
back in time to at least two years before the financial crisis. 7 Many of the larger insurance firms
in both the U.S. and the U.K. have a mix of life insurance and other types of insurance. We use
insurance premiums to divide firms into those that are predominately life insurers and those that
are not. Firms are categorized as life insurers if they derive at least 50% of their premiums from
life insurance. 8 Firms are divided based on 2014 premium data to keep the portfolios consistent
over time. Very few firms would switch groups if we were to reclassify them every year. Note
that most of non-life premiums are for property and casualty (P&C) insurers, so the non-life
group is largely P&C insurers.
In our main analysis, we focus on four samples: U.S. life insurers, U.S. non-life insurers,
U.K. life insurers, and U.K. non-life insurers. In a robustness exercise discussed below, we

6

We do not look back further than 2002 because before that there are not enough insurance firms with traded stock
to conduct our analysis. Mutual insurance firms are excluded because they do not have publicly traded stock.
7
We include Manulife, a firm based in Canada, in the U.S. sample since most of its premiums are from John
Hancock, its U.S. subsidiary. We exclude American International Group (AIG) since the market’s perception of its
interest rate risk may be distorted due to government intervention.
8
We measure premiums using GAAP or IFRS accounting figures, as appropriate (one Swiss company uses Swiss
GAAP). Because GAAP revenue does not include fixed and variable annuity premiums, we may understate the
extent to which U.S. insurers are involved in interest rate sensitive life insurance activities. This should tend to
make the non-life insurance sample more sensitive to interest rate risk. We exclude premiums from reinsurance of
life insurers’ products because life reinsurance predominantly covers mortality risk.
9

examine the interest sensitivity of continental European insurers. Descriptive statistics on the
sample of life and non-life insurers for the U.S., the U.K., and continental Europe are shown in
Table 1. As measured by total assets, the average size of life insurers in all three samples as well
non-life insurers in the U.S. were of a similar magnitude during our sample period. The U.K.
and continental European non-life insurers were much smaller. A rough measure of leverage, the
ratio of assets (excluding separate account assets) to equity, was larger for U.K. and continental
European life insurers than for U.S. life insurers. As is to be expected due to the shorter duration
of non-life liabilities, on average, non-life insurers had lower asset-to-equity ratios than life
insurers. U.K. life and non-life insurers showed the highest profitability among the six samples,
while U.S. life insurers showed the lowest profitability, as of the end of 2014.
Tables 2 and 3 list the companies in the U.S. and U.K. samples, respectively. They also
report the share of premium income that each insurer earned from life and health insurance
products in 2014, the number of weekly stock return observations available for each insurer, and
the market capitalization of each insurer as of the end of 2014. We use market capitalization as
reported by SNL Financial to form weights, which vary at an annual frequency. All reported
regressions are weighted by market capitalization.

4. Hypotheses and U.S. – U.K. Comparison
4.1 Hypotheses
We focus on a comparison of the U.S. and the U.K. because it provides a useful contrast
in the types of products sold by life insurance firms. In the U.S., many life insurers offer
guaranteed minimum rates of return on the savings elements of whole life policies, fixed-rate
annuities, and variable annuities. In addition, policyholders often have the right to withdraw the
savings embedded in these policies (sometimes after a penalty) or to borrow against the savings.
Policyholders may also have the right to adjust the flow of new savings. Obviously, the value of
these options depends on how the current interest rate (and expectations of future rates)
compares to the guaranteed rate. As interest rates decrease, there is more incentive for
policyholders to increase their savings or to delay plans to surrender policies. This has the effect
of increasing the duration of liabilities. By contrast, in the U.K. most products with a savings
element offered by insurance firms have either no or de minimus guarantees. This means that for
10

U.K. policyholders, the return on their savings is proportional to the return that insurers earn on
assets financed by policyholders’ premiums. This gives policyholders less incentive to time
savings to changes in interest rates. As a result, when interest rates decrease, liabilities in the
U.K. should lengthen less than those in the U.S. This motivates our main difference-indifferences hypothesis:
Life insurance firms in the U.S. should become more sensitive to interest rates
relative to life insurance firms in the U.K. as interest rates decrease. This should be
reflected in a larger decrease in γ, the coefficient on the bond return in the two-factor
model, for U.S. life insurers than for U.K. life insurers between the normal and the
low interest rate periods.
Since most life insurance products are fairly long term, we expect that this increased interest rate
sensitivity could persist for a while if rates remain low after a large decrease.
One complication to a simple test of the difference in interest rate sensitivity between
U.S. and U.K. life insurance firms is that conditions for insurance firms in the U.S. and the U.K.
might otherwise differ. Some of these differences should be captured by the stock market index
variable. However, some insurance-specific factors may not be captured by the broad stock
market indices we use. To account for this, we compare life insurance firms to other insurance
firms. If there are factors in the U.S. or the U.K. that impact returns to the insurance industry in
each country generally, this comparison will ensure that we are focused on differences due to
interest rate sensitivity and not to other factors influencing the evolution of returns in each
country. As noted earlier, this comparison group of firms is primarily P&C insurers. P&C
insurance products typically have a much shorter duration than life insurance products and,
partially as a result, P&C insurers typically have fewer fixed-income assets and the fixed-income
assets they do have are shorter maturity than those held by life insurers. In addition, return
guarantees and policyholder options are not relevant for P&C insurers. Thus, we expect that the
non-life insurance firms will be less sensitive to interest rate changes and will be more similar
between the U.S. and the U.K. compared to life insurance firms. Still, the non-life firms will be
responsive to changes in the local environment for insurers, and that may differ across the two
countries. We can refine our difference-in-difference hypothesis as follows:
The difference between the change in γ for U.S. life insurers and the change in γ for
U.S. non-life insurers from the normal rate period to the low-rate period should be
11

more negative than the difference between the change in γ for U.K. life insurers and
the change in γ for U.K. non-life insurers.
We also expect that:
The difference between the change in γ for U.S. life insurers and the change in γ for
U.S. non-life insurers from the normal rate period to the low-rate period should be
negative.

A substantial decrease in interest rates can affect the interest rate sensitivity of life
insurers even if they hedge risk using an approximate method such as duration matching. Life
insurance liabilities often have a very long duration. People purchase life insurance policies well
before they are likely to die. Similarly, they invest in annuities that are often established prior to
retirement and that are expected to make payouts for many years. While insurers would
presumably like to hedge these risks by investing in assets of a similar duration to the liabilities,
there is often a shortage of high-quality, long duration, fixed-income assets. This is one of the
reasons that insurers frequently choose to hedge by matching the overall duration of their asset
portfolio to the overall duration of their liabilities. This is in essence, hedging a mixture of new
(long-term) and old (shorter-term) liabilities with assets whose duration is somewhere in the
middle. If insurers do not adjust these hedges when interest rates decrease, the duration of
liabilities will increase more than the duration of assets does. This is the so-called convexity
problem. Insurers can mitigate this problem by dynamically re-hedging their portfolios as rates
change. We expect the convexity problem to be largely similar in the U.S. and the U.K. except
for the impact of guarantees and policyholder behavior given guarantees. As a result, any
changes in γ in the U.S. relative to the U.K. should not be driven by convexity, apart from the
effects of guarantees and policyholder optionality.
Low interest rates can also affect the ability of life insurance firms to profitably sell
certain products. For products with a savings element, it is difficult for an insurer to profitably
offer a significant return (whether guaranteed or not) when interest rates are very low. There is
little incentive for potential policyholders to lock their money into an annuity or to tie it up
through the savings elements of a life insurance contract when the rate of return is mere basis
points. This means that the profitability of life insurers may decrease when interest rates
decrease because of a reduced ability to sell products. To the extent that this is broadly true for
12

both the U.S. and the U.K., it should affect the interest rate sensitivity of life insurers in both
countries. However, there is an additional factor that affects profitability: for products where
policyholders have options, insurers have to price in the effect of those options. If interest rates
increase, policyholders are more likely to exercise options to leave or reduce payments. This
means a policy with those features will have to be priced higher (or offer a lower guaranteed
rate), all else equal, than one without those features. Guarantees and policyholder options are
present more often in the U.S. than the U.K., so some of what we measure might come from the
inability to sell products. Still, this is consistent with our broader story that the complications
from guarantees and policyholder options meant that U.S. insurers did not hedge the residual
interest rate risk of a large decrease in interest rates, where the risk of not being able to sell
products is one component of interest rate risk. Our top-down approach does not allow us to
determine the exact sources of the interest rate risk.
4.2 U.S. – U.K. Comparison
Figure 2 plots the estimates of γ from the rolling regressions for the sample of U.S.
insurance firms. We use the S&P 500 as our market index. Each point in the black line reflects a
point estimate using the past two-years of weekly returns data. The light gray bands reflect 95%
confidence intervals constructed from heteroskedasticity-robust standard errors. The dark gray
line shows the mean of the ten-year U.S. government bond yield over the past two years.
Panel A of Figure 2 shows the estimates for life insurers. As the figure illustrates, in the
normal rate period estimates of γ are very close to zero with very tight confidence intervals. As
data from the financial crisis (beginning roughly in July 2007 and continuing through June 2010)
become fully incorporated into the two-year window, the point estimates rise and the confidence
intervals expand dramatically. Finally, as the crisis abates, the confidence intervals become
smaller and the point estimates drop. By 2012, yields on a ten-year U.S. government bond were
historically low, and the estimates of γ from the past two years of data were negative and
statistically different from zero. By the end of the sample period the point estimate of γ was
about -1, indicating that a one percentage point increase in ten-year U.S. government bond
returns was associated with a one percentage point decrease in the stock market value of life
insurance firms. Using the July 2015 yield on a ten-year U.S. government bond of 2.32%, our
results imply that a one percentage point decrease in the yield of the ten-year bond is associated
with an 8.8% drop in the stock market value of life insurers.
13

Panel B of Figure 2 shows that U.S. non-life insurance firms displayed a somewhat
similar degree of interest rate sensitivity to the life insurance firms in the period prior to the
financial crisis, but were much less interest rate sensitive in the period following the financial
crisis. The point estimates of γ in the post-crisis period are small in magnitude and statistically
indistinguishable from zero for most of the period after the crisis.
To complete our difference-in-differences estimates, we compare the changes at life
insurers to the changes at non-life insurers by pooling the life and non-life samples used to
estimate Panels A and B and adding interaction terms to the specification shown in Equation (1):
Ri, t = α + β1 Rm, t + β2 Rm, t × Life sharei,t + γ1 R10, t + γ2 R10, t × Life sharei,t + εi ,t ,

(2)

where Life sharei,t is the share of the premiums at firm i that are from life insurance products.
Panel C of Figure 2 is from an estimation of (2). The figure plots γ2, the coefficient on the
interaction between the government bond return factor and the share of premiums from life
insurance. In essence, Panel C shows the difference between panels A and B in that it shows
how interest rate sensitivity for a pure life insurance firm changed relative to a pure non-life
insurance firm. The figure clearly shows that during the low-rate period in the U.S., life insurers
became more interest rate sensitive than non-life insurers.
Figure 3 shows a similar set of plots to those shown in Figure 2, but for U.K. insurance
firms. Again the samples are split into life insurers (Panel A) and non-life insurers (Panel B).
We estimate the regressions in the same manner that we do for the U.S. sample, except that we
use the weekly returns on the FTSE100 and the ten-year U.K. government bond as explanatory
variables rather than the S&P 500 and ten-year U.S. government bond returns. While the
number of firms in both the life and non-life insurance samples is much smaller for the U.K. than
for U.S., which contributes to the larger confidence intervals, the estimates of γ in both the preand post-crisis periods are almost always statistically indistinguishable from zero for the life
insurance sample (Panel A). The same is largely true for the non-life insurance sample (Panel
B), except for a short period during 2013. Furthermore, the difference-in-differences estimate
shown in Panel C is statistically indistinguishable from zero, indicating that any changes in
interest rate sensitivity over time were due to factors that affected both life and non-life insurers
similarly.
Comparing the results for the U.S. and the U.K., we find support for our main hypothesis.
Running through the pieces of our triple difference hypothesis: In the U.S., the change in γ for
14

life insurers from the normal rate period to the low-rate period is significantly more negative
than the change for non-life insurers. However, in the U.K., there is no significant change in γ
for life insurers from the normal rate period to the low-rate period and the change relative to nonlife insurers is, if anything, positive. We argue that this evidence is consistent with guarantees
and policyholder options making U.S. life insurers more sensitive to interest rates in the current
low rate period as compared with the normal rate period. We are agnostic as to extent to which
this is due to imperfect hedging of pre-existing liabilities versus incomplete hedging of
differences in the ability of life insurers to profitably sell new policies when interest rates are
low.
We do not explicitly consider differences in the incentives for life insurance firms to
hedge across countries. Of course, life insurers in the U.S. understand their potential exposure
from a large interest rate decrease. We would expect this to give them a greater incentive than
U.K. life insurers to hedge against interest rate decreases. Nonetheless, we find that the residual
exposure to interest rates in the low-rate period is larger in absolute value for U.S. firms than for
U.K. firms even after any aggressive hedging by U.S. life insurers.

5. Interest Rate Risk in Continental Europe
In this section we turn to continental Europe. We show results that are consistent with our
findings for the U.S. and the U.K. using a sample of European insurers and describe how our
top-down measure of interest rate sensitivity compares to a bottom-up measure which is uniquely
available for Europe.
5.1 Baseline analysis of Europe
Extending our analysis to continental Europe is complicated by several factors. The first
of which is that, as in the U.K., there are relatively few large insurers. The second factor that
complicates our analysis is that the insurance market in Europe is more integrated than in the
U.S. or the U.K. A firm based in one country may sell the majority of its products in other
countries and thus be exposed to the guarantees and options that are prevalent in the countries
where they sell policies rather than the country in which they are headquartered. Finally, for a
number of countries there is not a clear consensus regarding to the prevalence of products that
contain both guarantees and options. Given these constraints, we create a panel including all

15

publicly-traded insurers based in Austria, France, Germany, Italy, Spain, and Switzerland. 9 We
then group these firms based on their exposure to German and U.S. life insurance customers,
since there is a consensus that German insurance products contain long-lived guarantees to
policyholders that make their exposure to interest rate risk from life insurance liabilities similar
to that of U.S. insurers.
The continental European sample is constructed in a similar manner to our U.S. and U.K.
samples. We select insurance firms that are included in the SNL Financial dataset and that have
stock price data extending back in time to at least two years before the financial crisis. Again,
for each firm, we calculate the share of life and health insurance premiums, net of reinsurance.
Since life insurance markets in continental Europe are more integrated than those in the U.S. and
the U.K., we construct country-specific measures of interest rate risk exposure by calculating the
share of life insurance premiums that each company receives from each of the countries in our
continental European sample (Table 3). 10 Our premium-based measure is likely to reflect the
exposure that a given firm has to the types of life insurance products that are sold in a given
country. Our maintained hypothesis is that the extent of guarantees and of policyholder
optionality is related more to the common products typically sold in the country where the
policyholder lives than to those sold in the country where a firm has its headquarters.
We then split our sample by exposure to Germany and the U.S. and by whether a firm is
predominantly a life insurer. Using data from annual reports, we calculate the share of life
insurance premiums from either Germany or the U.S. 11 Firms that earned more than 25% of
their life insurance premiums from Germany and the U.S are categorized as high German
exposure firms, and those that earned less are categorized as low German exposure firms. 12

9

We focus on this set of countries because the sample is deepest in these countries and there is a good mix of life
and non-life insurance companies in these countries.
10
We calculated the share of life insurance premiums that each company earned from each country in our sample
using each company’s 2014 annual report (see Table 3).
11
We lump the U.S. and Germany together since they have similar products. However, only AXA and Zurich,
Insurance Group, Ltd. (at 21% and 6%, respectively) earn more than 5% of life premiums from the U.S. For this
reason, we refer to this measure as ‘German exposure’.
12
We were unable to find information with that the split of life insurance premiums by country of origin in annual
reports for Nürnberger Beteiligungs-AG. We assume that it earns the same share of life premiums from Germany
and the U.S. (98%) as Wüstenrot & Württembergische AG which is the German firm that most resembles
Nürnberger Beteiligungs-AG in terms of the share of premiums earned from life insurance and market
capitalization. Our results are robust to assuming that Nürnberger Beteiligungs-AG earns 0%, 50%, or 100% of its
life premiums from Germany and the U.S.
16

Splitting the sample this way classifies 7 firms as having high German exposure and 18 firms as
having low German exposure.
Panels A and B of Figure 4 show the results of estimating the same specifications as were
presented for the U.S. and U.K. samples in Figure 2 Panel C and Figure 3 Panel C, respectively,
except that in Figure 4 the samples used are the high German exposure companies (Panel A) and
the low German exposure companies (Panel B). When estimating Equation (2) for the
continental European sample, we use German government bond returns to avoid picking up the
effects of sovereign credit risk that might influence interest rates in some of the European
countries. We use the return on the ten-year German government bond as the bond return factor
(R10, t) and the return on the German stock market as measured by the DAX as the market return
factor (Rm, t) for all of the countries in our continental European sample.
Panel C of Figure 4 adds another dimension of differencing. We compare the changes at
life insurers to the changes at non-life insurers in the high and low German exposure companies
by pooling the high and low German exposure sample used to estimate Panels A and B and
adding additional interaction terms to the specification shown in Equation (2):
Ri, t = α + β1 Rm, t + β2 Rm, t × Life sharei,t + β3 Rm, t × Germani,t + β4 Rm, t × Life sharei,t × Germani,t +
γ1 R10, t + γ2 R10, t × Life sharei,t + γ3 R10, t × Germani,t + γ4 R10, t × Life sharei,t × Germani,t + εi ,t ,

(3)

where Life sharei,t is (as previously defined) the share of the premiums at firm i that are from life
insurance products, and Germani,t is an indicator variable which is equal to 1 if the share of life
insurance product premiums from Germany and the U.S. is greater than 25% at firm i, and 0
otherwise. Panel C of Figure 4 plots γ4 from estimates (3), where γ4 is the coefficient on the
interaction between the government bond return factor and the share of premiums from life
insurance and the high German exposure indicator. This coefficient measures the effect of life
insurance exposure to bond returns over and above the effect of non-life insurance exposure for
firms more exposed to Germany relative to those less exposed to Germany. We interpret this
coefficient as measuring how interest rate sensitivity for a pure life insurance firm highly
exposed to German products changed relative to a pure life insurance firm with low exposure to
German products. In other words, it captures the difference between Panels A and B in Figure 4.
While the results are somewhat noisy, the figure clearly shows that during the low-rate period,
continental European life insurers with higher German exposure became more interest rate
sensitive than continental European life insures with lower German exposure. Due to the
17

complications of small sample sizes and a noisy measure of the extent of guarantees and of
policyholder optionality, we are not surprised by the noisiness shown in Figure 4 Panel C.
However, we are reassured by the fact that the point estimates change from positive to negative
from the normal-rate to the low-rate period. We view this as a robustness check to our main
results which compare the U.S. and U.K.
4.2 Comparison to a Bottom-up Measure of Interest Rate Risk
Finally, we consider how our top-down measures of the change in interest rate
sensitivities align with a bottom-up measure that simulates the durations of the specific assets
and liabilities that insurance companies hold. Bottom-up measures exist for a set of European
insurance companies which participated in EIOPA stress tests (see EIOPA, 2014) and the results
are publicly available at the country-level.
In order to measure the change in interest rate risk from the normal-rate to the low-rate
period at a country level, we run country-specific, value-weighted panel regressions using
samples of life and non-life insurer stock returns. Again, we split the sample based on whether
50% or more of premiums come from life and health insurance. We form the country specific
weights by multiplying the market capitalization of each company by the share of life insurance
premiums that the company earns from the specific country that we are considering. 13 We
estimate life insurance and non-life insurance regressions for each country. In order to
summarize the difference-in-differences measure of the change in interest rate risk in each
country with a single coefficient, we estimate a model using returns data from the normal-rate
and the low-rate periods (excluding the financial crisis period), and include an interaction term
between an indicator for the low rate period and the return on the ten-year government bond.
Specifically, we estimate:
Ri, t = α + β0Rm, t + β1Lt*Rm, t + γ0R10, t + γ1Lt*Rm, t + εi t ,

(4)

where Ri, t , Rm, t , R10, t ,ε i, t are defined as before and Lt is an indicator variable which is equal to 1
in the low-rate period and 0 in the normal-rate period.
The coefficient γ1 in equation (4) is a country-specific measure of the change in interest
rate sensitivity between the normal and the low interest rate period for life and non-life insurers.
We compare this top-down measure to the bottom-up measures reported by country from the
EIOPA 2014 stress test scenario that investigated the impact of a ‘low for long’ interest rate
13

Based on 2014 premiums converted to a common currency using the exchange rate at the end of the year.
18

scenario (see Table 5). Importantly, for the sake of comparability, EIOPA conducted their stress
tests at the undertaking-level, meaning that the country-specific duration mismatches that they
report in the low for long scenario reflect the participating business-units operating in a particular
country and thus insurance products that are sold in that country (rather than firms that are
headquartered in the country).
For the five countries in both our continental European sample and the EIOPA sample,
we find a correlation of -0.40 between our top-down interest rate risk measure and EIOPA’s
duration mismatch measure. 14 A negative correlation indicates that countries with larger
increases in interest rate sensitivity (more negative coefficients) according to the top down
analysis were deemed to have liabilities of a longer duration than their assets in the bottom up
EIOPA stress tests. This suggests that the top-down approach and EIOPA’s bottom-up approach
of measuring interest rate risk are aligned. We do not report the correlation between the EIOPA
duration mismatch numbers and our interest rate risk measures for the non-life sample due to the
fact that the coefficients on our interest rate risk measure are small in magnitude and mostly
statistically indistinguishable from zero as we would expect for the non-life insurers.

6. Conclusions
We use a two factor model of life insurer stock returns to measure interest rate risk at
U.S. and U.K. insurers. We find that interest rate risk among U.S. life insurers has increased in
the recent period of decreasing and low interest rates. In the U.K., in contrast, life insurer
interest rate risk has been low in this period and roughly similar to the period prior to the
financial crisis when long-term interest rates were in their usual historical ranges as. We
attribute the difference in interest rate risk between the U.S. and the U.K. to the heavier use of
guarantees and policyholder options among U.S. life insurers relative to their U.K. counterparts.

14

Switzerland did not participate in the EIOPA stress test.
19

References
Ang, Andrew, Jun Liu, and Krista Schwarz (2010). ‘Using Stock or Portfolios in Test of
Factor Models’. Unpublished manuscript.
Berends, Kyal and Thomas King (2015). ‘Derivatives and Collateral at U.S. Life Insurers’.
Economic Perspectives, 39/1st Quarter.
Berends, Kyal, Robert McMenamin, Thanases Plestis and Richard J. Rosen (2013).
‘Sensitivity of Life Insurance Firms to Interest Rate Changes’. Economic Perspectives, 37/2nd
Quarter.
Brewer, Elijah, III, James M. Carson, Elyas Elyasiani, Iqbal Mansur, and William L. Scott
(2007). ‘Interest rate risk and equity values of life insurance companies: A GARCH–M model’.
Journal of Risk and Insurance, 74/2: 401–423.
Brewer, Elijah, III, Thomas H. Mondschean, and Philip E. Strahan (1993). `Why the life
insurance industry did not face an “S&L-type” crisis’. Economic Perspectives, 17/5: 12–24.
Carson, James M., Elyas Elyasiani, and Iqbal Mansur (2008). ‘Market risk, interest rate risk,
and interdependencies in insurer stock returns: A System-GARCH model’. Journal of Risk and
Insurance, 75/4: 873–891.
EIOPA (2014). ‘EIOPA Insurance stress test 2014’. Technical report.
Fama, Eugene F., and Kenneth R. French (1992). ‘The Cross-Section of Expected Stock
Returns’. The Journal of Finance, 47/2: 427–465.
Fama, Eugene F., and Kenneth R. French (1993). ‘Common risk factors in the returns on
stocks and bonds’. Journal of Financial Economics, 33/1: 3–56.
Flannery, Mark J., and Christopher M. James (1984). ‘The effect of interest rate changes on
the common stock returns of financial institutions’. Journal of Finance, 39/4: 1141–1153.
Geneva Association (2012). ‘Surrenders in the Life Industry and Their Impact on Liquidity’.
Technical report.
Moody’s (2015). ‘Low Interest Rates are Credit Negative for Insurers Globally, but Risks Vary
by Country’. Moody’s Investors Service, Global Insurance Themes, 26 March. Technical report.
Oliver Wyman (2014). ‘The Future of the U.K. Life Industry. Time to Invest in Mass Market
Retirement’. Technical report.

20

Figure 1: 10-year Constant Maturity Government Bond Yields

"'C-.t
Qi

>=

"'C

c:
0

CO N

.....
c:
Q)

E

c:

a>o
6
(!)

2000

2005

2010
Year
U.S. 10-year
U.K. 10-year
German 10-year

21

2015

Figure 2: Estimates of Interest Rate Sensitivity for U.S. Insurers
Panel A. Life Insurers

Panel B. Non-life Insurers

Panel C. All Insurers (Difference)

22

Figure 3: Estimates of Interest Rate Sensitivity for U.K. Insurers
Panel A. Life Insurers

Panel B. Non-life Insurers

Panel C. All Insurers (Difference)

23

Figure 4: Estimates of Interest Rate Sensitivity for Continental European Insurers
Panel A. High German Exposure (Difference)

Panel B. Low German Exposure (Difference)

Panel C. All Insurers (Difference in Differences)

24

Table 1: Insurer Sample Statistics
Insurer Type

Life Insurers
U.S.

U.K.

Non-life Insurers
Europe

U.S.

U.K.

Europe

Size - Total Assets (millions of $)

189

209

141

152

8

24

Financial Leverage - Assets (net of
separate accounts) to Equity Ratio

9.6

13.6

13.6

3.7

4.5

6.7

Profitability - Net Income before
Taxes to Equity Ratio

6%

21%

12%

14%

28%

14%

Number of Companies

21

6

12

57

4

13

Note: This table shows sample report the sample mean of size, financial leverage, and profitability as of the end of
2014 for the six samples analyzed in this chapter. The number of insurers in each sample is reported in the last row.

25

Table 2: U.S. Insurer Sample

Company Name

Premium Income from
Life and Health
Insurance

Observations

Market
Capitalization ,
year-end 2014
(millions of $)

Aetna Inc.

4%

661

31,070

Affirmative Insurance Holdings, Inc.

0%

540

20

Aflac Incorporated

98%

661

27,029

Alleghany Corporation

0%

661

7,441

Allstate Corporation
American Equity Investment Life Holding
Company

7%

661

29,365

99%

567

2,220

American Financial Group, Inc.

2%

661

5,326

American Independence Corp.

43%

661

83

American National Insurance Company

23%

661

3,070

Assurance America Corporation

0%

661

14

Atlantic American Corporation

63%

661

83

Baldwin & Lyons, Inc.

0%

661

386

CNA Financial Corporation

5%

661

10,451

CNO Financial Group, Inc.

93%

579

3,501

Centene Corporation

0%

661

6,150

Chubb Corporation

0%

661

24,050

Cincinnati Financial Corporation

4%

661

8,485

Citizens, Inc.

96%

661

381

Donegal Group Inc.

0%

661

432

EMC Insurance Group Inc.

0%

661

481

Erie Indemnity Company

2%

661

4,746

FBL Financial Group, Inc.

56%

661

1,434

Federated National Holding Company

0%

661

329

First Acceptance Corporation
GAINSCO, INC.
Genworth Financial, Inc.
HCC Insurance Holdings, Inc.

0%
0%
56%
35%

661
661
544
661

105
50
4,222
5,166

Hallmark Financial Services, Inc.
Hanover Insurance Group, Inc.
Hartford Financial Services Group, Inc.
Health Net, Inc.
Horace Mann Educators Corporation
Independence Holding Company

0%
0%
22%
0%
15%
78%

661
661
661
661
661
661

232
3,131
17,694
4,179
1,358
242

Infinity Property and Casualty Corporation
Investors Heritage Capital Corporation
Investors Title Company

0%
78%
0%

605
661
661

887
24
148

26

Kansas City Life Insurance Company

75%

661

520

Kemper Corporation
Kingstone Companies, Inc.
Lincoln National Corporation
Loews Corporation
MBIA Inc.
MGIC Investment Corporation

28%
0%
33%
5%
0%
0%

661
661
661
661
661
661

1,893
60
14,795
15,671
1,831
3,155

Manulife Financial Corporation
Markel Corporation
Mercury General Corporation
MetLife, Inc.
Molina Healthcare, Inc.
National Interstate Corporation
National Security Group, Inc.

100%
0%
0%
86%
0%
0%
10%

671
661
661
661
588
513
661

35,739
9,534
3,124
61,226
2,662
590
34

National Western Life Insurance Company
Navigators Group, Inc.
Old Republic International Corporation
Phoenix Companies, Inc.
Principal Financial Group, Inc.
ProAssurance Corporation

10%
0%
1%
69%
90%
0%

661
661
661
661
661
661

979
1,047
3,818
393
15,265
2,553

Progressive Corporation
Prudential Financial, Inc.
RLI Corp.
Radian Group Inc.
Reinsurance Group of America, Incorporated
Safety Insurance Group, Inc.

0%
95%
0%
0%
95%
0%

661
661
661
661
661
617

15,865
41,144
2,129
3,194
6,026
961

Security National Financial Corporation
Selective Insurance Group, Inc.
StanCorp Financial Group, Inc.
State Auto Financial Corporation
Stewart Information Services Corporation
Torchmark Corporation

98%
0%
94%
0%
0%
100%

661
661
661
661
661
661

71
1,538
2,940
909
889
6,930

Travelers Companies, Inc.
Triad Guaranty Inc.
UTG, Inc.
Unico American Corporation
United Fire Group, Inc.
Universal American Corp.

0%
0%
73%
0%
7%
3%

661
661
661
661
661
661

34,105
2
53
61
744
777

Universal Insurance Holdings, Inc.
Unum Group
W. R. Berkley Corporation
WellCare Health Plans, Inc.

0%
96%
0%
0%

661
661
661
541

697
8,801
6,497
3,604

27

Table 3: U.K. Insurer Sample

Company Name

Premium Income from Life and
Health Insurance Products

Observations

Market
Capitalization,
year-end 2014
(millions of $)

Admiral Group Plc

0%

538

5,744

Amlin Plc

0%

672

3,738

Aviva Plc

58%

672

22,268

Chesnara Plc

100%

556

669

Legal & General Group Plc

96%

672

22,917

Old Mutual Plc

76%

672

14,573

Personal Group Holdings Plc

0%

672

220

Prudential Plc

99%

672

59,491

RSA Insurance Group Plc

0%

672

6,879

100%

672

6,549

St. James's Place Plc

28

Table 4: European Insurer Sample

Premium
Income
from Life
and Health
Insurance
Products

Country

Company Name

Austria

UNIQA Insurance Group AG

52%

Austria

Vienna Insurance Group AG

France

AXA

France

Share of
Life and
Health
Insurance
Premium
Income
from
Germany
and U.S.

Observations

Market
Capitalization,
year-end 2014
(millions of $)

0%

635

50%

2%

635

5,773

59%

33%

667

56,764

April SA

63%

0%

667

611

France

CNP Assurances SA

90%

0%

667

12,231

France

Euler Hermes Group

0%

0%

667

4,560

France

SCOR SE

0%

0%

667

5,676

Germany
Germany

34%
0%

64%
0%

659
659

75,883
10,996

Germany
Germany
Germany

Allianz Group
Hannover Rück SE
Münchener RückversicherungsGesellschaft
Nürnberger Beteiligungs-AG
Wüstenrot & Württembergische AG

26%
80%
61%

60%
98%
98%

659
659
659

33,972
999
2,030

Italy

Assicurazioni Generali SpA

69%

28%

651

32,181

Italy

99%

4%

651

4,742

Italy

Mediolanum SpA
Società Cattolica di Assicurazione Società Cooperativa

64%

0%

655

1,207

Italy

Unipol Gruppo Finanziario SpA

49%

0%

651

3,563

Italy

UnipolSai Assicurazioni SpA

47%

0%

651

7,066

Spain

Grupo Catalana Occidente SA

26%

0%

653

3,427

Spain

MAPFRE SA

24%

0%

653

10,486

Switzerland

ACE Limited

20%

0%

661

37,756

Switzerland

Bâloise Holding AG

53%

14%

654

6,070

Switzerland

Helvetia Holding AG

61%

7%

654

4,729

Switzerland

Swiss Life Holding Limited

97%

9%

654

7,625

Switzerland
Switzerland

Vaudoise Assurances Holding SA
Zurich Insurance Group Ltd.

34%
23%

0%
29%

654
654

1,331
46,772

29

2,915

Table 5: Comparison of Interest-Rate Factor to EIOPA Results for the Continental
European Sample
Coefficient on bond factor (γ)
Country

Life insurers

Non-life insurers

EIOPA
duration
mismatch,
years

Austria

-1.00***

0.35

11.33

France

-0.60***

-0.35

5.58

Germany

-0.68***

-0.28

11.32

Italy

-0.84***

-0.25

1.16

Spain

-0.59**

-0.47**

0.89

-0.39

-0.20

--

Switzerland
Correlation with EIOPA duration
mismatch

-0.40

Note: This table shows point estimates from 12 separate panel regressions. Two regressions are estimated for each
country. One regression is for the life insurance sample and one is for the non-life insurance sample. In each
regression the dependent variable is the weekly stock return of the insurance companies in our continental European
sample. Each regression is weighted. The weights are formed by multiplying the market capitalization of each
company (expressed in a common currency) by the share of life insurance premiums that the firm earned from the
country which the regression is for. The explanatory variables consist of the same two factors contained in our main
specifications, the return on the stock market and the return on the ten-year government bond (as noted in the text
we use the German stock and government bond return for the continental European sample). We have also added an
indicator variable for the low-rate period and an interaction term between the return on the 10 year government bond
and an indicator variable for the low-rate period. We can interpret the coefficient on this variable as the change in
interest rate sensitivity of insurance company stock returns from the normal-rate to the low-rate period. The sample
includes only observations from the normal-rate and low-rate periods. For comparison, duration mismatch
measured in years from the low yield module A of the EIOPA 2014 stress tests are also shown. The mismatch
figure captures the number of years by which the simulated duration of liabilities exceeds the simulated duration of
assets. No EIOPA data are available for Switzerland. The correlation between the mismatch numbers and the life
insurer interest rate sensitivity change coefficients is shown below the coefficients. A negative correlation indicates
that countries with larger increases in interest rate sensitivity (more negative coefficients) were deemed to have
liabilities of a longer duration than their assets.

30

Working Paper Series
A series of research studies on regional economic issues relating to the Seventh Federal
Reserve District, and on financial and economic topics.
The Urban Density Premium across Establishments
R. Jason Faberman and Matthew Freedman

WP-13-01

Why Do Borrowers Make Mortgage Refinancing Mistakes?
Sumit Agarwal, Richard J. Rosen, and Vincent Yao

WP-13-02

Bank Panics, Government Guarantees, and the Long-Run Size of the Financial Sector:
Evidence from Free-Banking America
Benjamin Chabot and Charles C. Moul

WP-13-03

Fiscal Consequences of Paying Interest on Reserves
Marco Bassetto and Todd Messer

WP-13-04

Properties of the Vacancy Statistic in the Discrete Circle Covering Problem
Gadi Barlevy and H. N. Nagaraja

WP-13-05

Credit Crunches and Credit Allocation in a Model of Entrepreneurship
Marco Bassetto, Marco Cagetti, and Mariacristina De Nardi

WP-13-06

Financial Incentives and Educational Investment:
The Impact of Performance-Based Scholarships on Student Time Use
Lisa Barrow and Cecilia Elena Rouse

WP-13-07

The Global Welfare Impact of China: Trade Integration and Technological Change
Julian di Giovanni, Andrei A. Levchenko, and Jing Zhang

WP-13-08

Structural Change in an Open Economy
Timothy Uy, Kei-Mu Yi, and Jing Zhang

WP-13-09

The Global Labor Market Impact of Emerging Giants: a Quantitative Assessment
Andrei A. Levchenko and Jing Zhang

WP-13-10

Size-Dependent Regulations, Firm Size Distribution, and Reallocation
François Gourio and Nicolas Roys

WP-13-11

Modeling the Evolution of Expectations and Uncertainty in General Equilibrium
Francesco Bianchi and Leonardo Melosi

WP-13-12

Rushing into the American Dream? House Prices, the Timing of Homeownership,
and the Adjustment of Consumer Credit
Sumit Agarwal, Luojia Hu, and Xing Huang

WP-13-13

1

Working Paper Series (continued)
The Earned Income Tax Credit and Food Consumption Patterns
Leslie McGranahan and Diane W. Schanzenbach

WP-13-14

Agglomeration in the European automobile supplier industry
Thomas Klier and Dan McMillen

WP-13-15

Human Capital and Long-Run Labor Income Risk
Luca Benzoni and Olena Chyruk

WP-13-16

The Effects of the Saving and Banking Glut on the U.S. Economy
Alejandro Justiniano, Giorgio E. Primiceri, and Andrea Tambalotti

WP-13-17

A Portfolio-Balance Approach to the Nominal Term Structure
Thomas B. King

WP-13-18

Gross Migration, Housing and Urban Population Dynamics
Morris A. Davis, Jonas D.M. Fisher, and Marcelo Veracierto

WP-13-19

Very Simple Markov-Perfect Industry Dynamics
Jaap H. Abbring, Jeffrey R. Campbell, Jan Tilly, and Nan Yang

WP-13-20

Bubbles and Leverage: A Simple and Unified Approach
Robert Barsky and Theodore Bogusz

WP-13-21

The scarcity value of Treasury collateral:
Repo market effects of security-specific supply and demand factors
Stefania D'Amico, Roger Fan, and Yuriy Kitsul
Gambling for Dollars: Strategic Hedge Fund Manager Investment
Dan Bernhardt and Ed Nosal
Cash-in-the-Market Pricing in a Model with Money and
Over-the-Counter Financial Markets
Fabrizio Mattesini and Ed Nosal

WP-13-22

WP-13-23

WP-13-24

An Interview with Neil Wallace
David Altig and Ed Nosal

WP-13-25

Firm Dynamics and the Minimum Wage: A Putty-Clay Approach
Daniel Aaronson, Eric French, and Isaac Sorkin

WP-13-26

Policy Intervention in Debt Renegotiation:
Evidence from the Home Affordable Modification Program
Sumit Agarwal, Gene Amromin, Itzhak Ben-David, Souphala Chomsisengphet,
Tomasz Piskorski, and Amit Seru

WP-13-27

2

Working Paper Series (continued)
The Effects of the Massachusetts Health Reform on Financial Distress
Bhashkar Mazumder and Sarah Miller

WP-14-01

Can Intangible Capital Explain Cyclical Movements in the Labor Wedge?
François Gourio and Leena Rudanko

WP-14-02

Early Public Banks
William Roberds and François R. Velde

WP-14-03

Mandatory Disclosure and Financial Contagion
Fernando Alvarez and Gadi Barlevy

WP-14-04

The Stock of External Sovereign Debt: Can We Take the Data at ‘Face Value’?
Daniel A. Dias, Christine Richmond, and Mark L. J. Wright

WP-14-05

Interpreting the Pari Passu Clause in Sovereign Bond Contracts:
It’s All Hebrew (and Aramaic) to Me
Mark L. J. Wright

WP-14-06

AIG in Hindsight
Robert McDonald and Anna Paulson

WP-14-07

On the Structural Interpretation of the Smets-Wouters “Risk Premium” Shock
Jonas D.M. Fisher

WP-14-08

Human Capital Risk, Contract Enforcement, and the Macroeconomy
Tom Krebs, Moritz Kuhn, and Mark L. J. Wright

WP-14-09

Adverse Selection, Risk Sharing and Business Cycles
Marcelo Veracierto

WP-14-10

Core and ‘Crust’: Consumer Prices and the Term Structure of Interest Rates
Andrea Ajello, Luca Benzoni, and Olena Chyruk

WP-14-11

The Evolution of Comparative Advantage: Measurement and Implications
Andrei A. Levchenko and Jing Zhang

WP-14-12

Saving Europe?: The Unpleasant Arithmetic of Fiscal Austerity in Integrated Economies
Enrique G. Mendoza, Linda L. Tesar, and Jing Zhang

WP-14-13

Liquidity Traps and Monetary Policy: Managing a Credit Crunch
Francisco Buera and Juan Pablo Nicolini

WP-14-14

Quantitative Easing in Joseph’s Egypt with Keynesian Producers
Jeffrey R. Campbell

WP-14-15

3

Working Paper Series (continued)
Constrained Discretion and Central Bank Transparency
Francesco Bianchi and Leonardo Melosi

WP-14-16

Escaping the Great Recession
Francesco Bianchi and Leonardo Melosi

WP-14-17

More on Middlemen: Equilibrium Entry and Efficiency in Intermediated Markets
Ed Nosal, Yuet-Yee Wong, and Randall Wright

WP-14-18

Preventing Bank Runs
David Andolfatto, Ed Nosal, and Bruno Sultanum

WP-14-19

The Impact of Chicago’s Small High School Initiative
Lisa Barrow, Diane Whitmore Schanzenbach, and Amy Claessens

WP-14-20

Credit Supply and the Housing Boom
Alejandro Justiniano, Giorgio E. Primiceri, and Andrea Tambalotti

WP-14-21

The Effect of Vehicle Fuel Economy Standards on Technology Adoption
Thomas Klier and Joshua Linn

WP-14-22

What Drives Bank Funding Spreads?
Thomas B. King and Kurt F. Lewis

WP-14-23

Inflation Uncertainty and Disagreement in Bond Risk Premia
Stefania D’Amico and Athanasios Orphanides

WP-14-24

Access to Refinancing and Mortgage Interest Rates:
HARPing on the Importance of Competition
Gene Amromin and Caitlin Kearns

WP-14-25

Private Takings
Alessandro Marchesiani and Ed Nosal

WP-14-26

Momentum Trading, Return Chasing, and Predictable Crashes
Benjamin Chabot, Eric Ghysels, and Ravi Jagannathan

WP-14-27

Early Life Environment and Racial Inequality in Education and Earnings
in the United States
Kenneth Y. Chay, Jonathan Guryan, and Bhashkar Mazumder

WP-14-28

Poor (Wo)man’s Bootstrap
Bo E. Honoré and Luojia Hu

WP-15-01

Revisiting the Role of Home Production in Life-Cycle Labor Supply
R. Jason Faberman

WP-15-02

4

Working Paper Series (continued)
Risk Management for Monetary Policy Near the Zero Lower Bound
Charles Evans, Jonas Fisher, François Gourio, and Spencer Krane
Estimating the Intergenerational Elasticity and Rank Association in the US:
Overcoming the Current Limitations of Tax Data
Bhashkar Mazumder

WP-15-03

WP-15-04

External and Public Debt Crises
Cristina Arellano, Andrew Atkeson, and Mark Wright

WP-15-05

The Value and Risk of Human Capital
Luca Benzoni and Olena Chyruk

WP-15-06

Simpler Bootstrap Estimation of the Asymptotic Variance of U-statistic Based Estimators
Bo E. Honoré and Luojia Hu

WP-15-07

Bad Investments and Missed Opportunities?
Postwar Capital Flows to Asia and Latin America
Lee E. Ohanian, Paulina Restrepo-Echavarria, and Mark L. J. Wright

WP-15-08

Backtesting Systemic Risk Measures During Historical Bank Runs
Christian Brownlees, Ben Chabot, Eric Ghysels, and Christopher Kurz

WP-15-09

What Does Anticipated Monetary Policy Do?
Stefania D’Amico and Thomas B. King

WP-15-10

Firm Entry and Macroeconomic Dynamics: A State-level Analysis
François Gourio, Todd Messer, and Michael Siemer

WP-16-01

Measuring Interest Rate Risk in the Life Insurance Sector: the U.S. and the U.K.
Daniel Hartley, Anna Paulson, and Richard J. Rosen

WP-16-02

5